How to search?
advanced search

Search results

Filters

  • Journals
  • Authors
  • Keywords
  • Date
  • Type

Search results

Number of results: 668
items per page: 25 50 75
Sort by:

Semiquantum authentication of users resistant to multisession attacks

Piotr Zawadzki
Bulletin of the Polish Academy of Sciences Technical Sciences | 2021 | 69 | 4 | e137729 | DOI: 10.24425/bpasts.2021.137729
Keywords quantum cryptography quantum identity authentication semi-quantum communication
Download PDF Download RIS Download Bibtex

Abstract

User authentication is an essential element of any communication system. The paper investigates the vulnerability of the recently published first semiquantum identity authentication protocol (Quantum Information Processing 18: 197, 2019) to the introduced herein multisession attacks. The impersonation of the legitimate parties by a proper combination of phishing techniques is demonstrated. The improved version that closes the identified loophole is also introduced
Go to article

Bibliography

  1.  M.M. Wilde, Quantum Information Theory. Cambridge University Press, 2013, doi: 10.1017/CBO9781139525343.
  2.  S. Wiesner, “Conjugate coding,” SIGACT News, vol. 15, no. 1, pp. 78–88, 1983, doi: 10.1145/1008908.1008920.
  3.  P. Benioff, “The computer as a physical system: A microscopic quantum mechanical Hamiltonian model of computers as represented by Turing machines,” J. Stat. Phys., vol. 22, no. 5, pp. 563–591, 1980, doi: 10.1007/BF01011339.
  4.  C.H. Bennett and G. Brassard, “Quantum cryptography: Public key distribution and coin tossing,” in Proceedings of International Conference on Computers, Systems and Signal Processing, Bangalore, India, 1984, pp. 175–179.
  5.  C.H. Bennett and G. Brassard, “Quantum cryptography: Public key distribution and coin tossing,” Theor. Comput. Sci., vol. 560, pp. 7–11, 2014, doi: 10.1016/j.tcs.2014.05.025.
  6.  P.W. Shor, “Polynomial-time algorithms for prime factorization and discrete logarithms on a quantum computer,” SIAM J. Comput., vol. 26, no. 5, pp. 1484–1509, 1997, doi: 10.1137/S0097539795293172.
  7.  A. Shenoy-Hejamadi, A. Pathak, and S. Radhakrishna, “Quantum cryptography: Key distribution and beyond,” Quanta, vol. 6, no. 1, pp. 1–47, 2017, doi: 10.12743/quanta.v6i1.57.
  8.  F. Xu, X. Ma, Q. Zhang, H.-K. Lo, and J.-W. Pan, “Secure quantum key distribution with realistic devices,” Rev. Mod. Phys., vol. 92, p. 025002, 2020, doi: 10.1103/RevModPhys.92.025002.
  9.  D. Pan, K. Li, D. Ruan, S.X. Ng, and L. Hanzo, “Singlephoton- memory two-step quantum secure direct communication relying on Einstein-Podolsky-Rosen pairs,” IEEE Access, vol. 8, pp. 121 146–121 161, 2020, doi: 10.1109/ACCESS.2020.3006136.
  10.  P. Zawadzki, “Advances in quantum secure direct communication,” IET Quant. Comm., vol. 2, no. 2, pp. 54–62, 2021, doi: 10.1049/ qtc2.12009.
  11.  A. Pljonkin and P.K. Singh, “The review of the commercial quantum key distribution system,” in 2018 Fifth International Conference on Parallel, Distributed and Grid Computing (PDGC), 2018, pp. 795–799, doi: 10.1109/PDGC.2018.8745822.
  12.  R. Qi, Z. Sun, Z. Lin, P. Niu, W. Hao, L. Song, Q. Huang, J. Gao, L. Yin, and G. Long, “Implementation and security analysis of practical quantum secure direct communication,” vol. 8, p. 22, 2019, doi: 10.1038/s41377-019-0132-3.
  13.  X. Li and D. Zhang, “Quantum authentication protocol using entangled states,” in Proceedings of the 5th WSEAS International Conference on Applied Computer Science, Hangzhou, China, 2006, pp. 1004–1009. [Online]. Available: https://www.researchgate.net/ publication/242080451_Quantum_authentication_protocol_using_entangled_states.
  14.  G. Zeng and W. Zhang, “Identity verification in quantum key distribution,” Phys. Rev. A, vol. 61, p. 022303, 2000, doi: 10.1103/ PhysRevA.61.022303.
  15.  Y. Kanamori, S.-M. Yoo, D.A. Gregory, and F.T. Sheldon, “On quantum authentication protocols,” in GLOBECOM ’05. IEEE Global Telecommunications Conference, 2005., vol. 3, 2005, pp. 1650–1654, doi: 10.1109/GLOCOM.2005.1577930.
  16.  P. Zawadzki, “Quantum identity authentication without entanglement,” Quantum Inf. Process., vol. 18, no. 1, p. 7, 2019, doi: 10.1007/ s11128-018-2124-2.
  17.  M. Boyer, D. Kenigsberg, and T. Mor, “Quantum key distribution with classical Bob,” Phys. Rev. Lett., vol. 99, p. 140501, 2007, doi: 10.1103/PhysRevLett.99.140501.
  18.  M. Boyer, R. Gelles, D. Kenigsberg, and T. Mor, “Semiquantum key distribution,” Phys. Rev. A, vol. 79, no. 3, p. 032341, 2009, doi: 10.1103/PhysRevA.79.032341.
  19.  W.O. Krawec, “Security of a semi-quantum protocol where reflections contribute to the secret key,” Quantum Inf. Process., vol. 15, no. 5, pp. 2067–2090, 2016, doi: 10.1007/s11128-016-1266-3.
  20.  Z.-R. Liu and T. Hwang, “Mediated semi-quantum key distribution without invoking quantum measurement,” Ann. Phys., vol. 530, no. 4, p. 1700206, 2018, doi: 10.1002/andp.201700206.
  21.  C.-W. Tsai and C.-W. Yang, “Cryptanalysis and improvement of the semi-quantum key distribution robust against combined collective noise,” Int. J. Theor. Phys., vol. 58, no. 7, pp. 2244–2250, 2019, doi: 10.1007/s10773-019-04116-5.
  22.  W.O. Krawec, “Security proof of a semi-quantum key distribution protocol,” in 2015 IEEE International Symposium on Information Theory (ISIT), 2015, pp. 686–690, doi: 10.1109/ISIT.2015.7282542.
  23.  Y.-P. Luo and T. Hwang, “Authenticated semi-quantum direct communication protocols using Bell states,” Quantum Inf. Process., vol. 15, no. 2, pp. 947–958, 2016, doi: 10.1007/s11128-015-1182-y.
  24.  J. Gu, P.-h. Lin, and T. Hwang, “Double C-NOT attack and counterattack on ‘Three-step semi-quantum secure direct communication protocol’,” Quantum Inf. Process., vol. 17, no. 7, p. 182, 2018, doi: 10.1007/s11128-018-1953-3.
  25.  M.-H. Zhang, H.-F. Li, Z.-Q. Xia, X.-Y. Feng, and J.-Y. Peng, “Semiquantum secure direct communication using EPR pairs,” Quantum Inf. Process., vol. 16, no. 5, p. 117, 2017, doi: 10.1007/s11128-017-1573-3.
  26.  L.-L. Yan, Y.-H. Sun, Y. Chang, S.-B. Zhang, G.-G. Wan, and Z.-W. Sheng, “Semi-quantum protocol for deterministic secure quantum communication using Bell states,” Quantum Inf. Process., vol. 17, no. 11, p. 315, 2018, doi: 10.1007/s11128-018-2086-4.
  27.  C. Xie, L. Li, and D. Qiu, “A novel semi-quantum secret sharing scheme of specific bits,” Int. J. Theor. Phys., vol. 54, no. 10, pp. 3819– 3824, 2015, doi: 10.1007/s10773-015-2622-2.
  28.  A. Yin and F. Fu, “Eavesdropping on semi-quantum secret sharing scheme of specific bits,” Int. J. Theor. Phys., vol. 55, no. 9, pp. 4027– 4035, 2016, doi: 10.1007/s10773-016-3031-x.
  29.  K.-F. Yu, J. Gu, T. Hwang, and P. Gope, “Multi-party semi-quantum key distribution-convertible multi-party semi- quantum secret sharing,” Quantum Inf. Process., vol. 16, no. 8, p. 194, 2017, doi: 10.1007/s11128-017-1631-x.
  30.  X. Gao, S. Zhang, and Y. Chang, “Cryptanalysis and improvement of the semi-quantum secret sharing protocol,” Int. J. Theor. Phys., vol. 56, no. 8, pp. 2512–2520, 2017, doi: 10.1007/s10773-017-3404-9.
  31.  Z. Li, Q. Li, C. Liu, Y. Peng, W. H. Chan, and L. Li, “Limited resource semiquantum secret sharing,” Quantum Inf. Process., vol. 17, no. 10, p. 285, 2018, doi: 10.1007/s11128-018-2058-8.
  32.  K. Sutradhar and H. Om, “Efficient quantum secret sharing without a trusted player,” Quantum Inf. Process., vol. 19, no. 2, p. 73, 2020, doi: 10.1007/s11128-019-2571-4.
  33.  H. Iqbal and W.O. Krawec, “Semi-quantum cryptography,” Quantum Inf. Process., vol. 19, no. 3, p. 97, 2020, doi: 10.1007/s11128-020- 2595-9.
  34.  N.-R. Zhou, K.-N. Zhu, W. Bi, and L.-H. Gong, “Semi-quantum identification,” Quantum Inf. Process., vol. 18, no. 6, p. 197, 2019, doi: 10.1007/s11128-019-2308-4.
  35.  K. Moriarty, B. Kaliski, and A. Rusch, “Pkcs #5: Password-based cryptography specification version 2.1,” Internet Requests for Comments, RFC Editor, RFC 8018, January 2017. [Online]. Available: https://www.rfc-editor.org/rfc/rfc8018.html.
  36.  A. Biryukov, D. Dinu, D. Khovratovich, and S. Josefsson, “The memory-hard Argon2 password hash and proof-of-work function,” Working Draft, IETF Secretariat, Internet-Draft draft-irtf-cfrg-argon2-12, 2020. [Online]. Available: https://tools.ietf.org/id/draft-irtf-cfrg-argon2-03. html.
  37.  P.-H. Lin, T. Hwang, and C.-W. Tsai, “Double CNOT attack on ‘Quantum key distribution with limited classical Bob’,” Int. J. Quantum Inf., vol. 17, no. 02, p. 1975001, 2019, doi: 10.1142/S0219749919750017.
  38.  D. Moody, L. Chen, S. Jordan, Y.-K. Liu, D. Smith, R. Perlner, and R. Peralta, “Nist report on post-quantum cryptography,” National Institute of Standards and Technology, U.S. Department of Commerce, Tech. Rep., 2016, doi: 10.6028/NIST.IR.8105.
  39.  P. Wang, S. Tian, Z. Sun, and N. Xie, “Quantum algorithms for hash preimage attacks,” Quantum Eng., vol. 2, no. 2, p. e36, 2020, doi: 10.1002/que2.36.
Go to article

Authors and Affiliations

Piotr Zawadzki
1
ORCID: ORCID
  1. Department of Telecommunications and Teleinformatics, Silesian University of Technology, ul. Akademicka 2A, 44-100 Gliwice, Poland

Cavitation erosion of electrostatic spray polyester coatings with different surface finish

Mirosław Szala Aleksander Świetlicki Weronika Sofińska-Chmiel
Bulletin of the Polish Academy of Sciences Technical Sciences | 2021 | 69 | 4 | e137519 | DOI: 10.24425/bpasts.2021.137519
Keywords polyester powder coatings cavitation erosion profilometry spectroscopy wear mechanism AW-6060 aluminium alloy
Download PDF Download RIS Download Bibtex

Abstract

Polyester coatings are among the most commonly used types of powder paints and present a wide range of applications. Apart from its decorative values, polyester coating successfully prevents the substrate from environmental deterioration. This work investigates the cavitation erosion (CE) resistance of three commercial polyester coatings electrostatic spray onto AW-6060 aluminium alloy substrate. Effect of coatings repainting (single- and double-layer deposits) and effect of surface finish (matt, silk gloss and structural) on resistance to cavitation were comparatively studied. The following research methods were used: CE testing using ASTM G32 procedure, 3D profilometry evaluation, light optical microscopy, scanning electron microscopy (SEM), optical profilometry and FTIR spectroscopy. Electrostatic spray coatings present higher CE resistance than aluminium alloy. The matt finish double-layer (M2) and single-layer silk gloss finish (S1) are the most resistant to CE. The structural paint showed the lowest resistance to cavitation wear which derives from the rougher surface finish. The CE mechanism of polyester coatings relies on the material brittle-ductile behaviour, cracks formation, lateral net-cracking growth and removal of chunk coating material and craters’ growth. Repainting does not harm the properties of the coatings. Therefore, it can be utilised to regenerate or smother the polyester coating finish along with improvement of their CE resistance.
Go to article

Bibliography

  1.  A. Kausar, “Review of fundamentals and applications of polyester nanocomposites filled with carbonaceous nanofillers,” J. Plast. Film Sheeting, vol. 35, no. 1, pp. 22–44, Jan. 2019, doi: 10.1177/8756087918783827.
  2.  A. Krzyzak, E. Kosicka, and R. Szczepaniak, “Research into the Effect of Grain and the Content of Alundum on Tribological Properties and Selected Mechanical Properties of Polymer Composites,” Materials, vol. 13, no. 24, Art. no. 5735, Jan. 2020, doi: 10.3390/ma13245735.
  3.  A. Kausar, “High performance epoxy/polyester-based nanocomposite coatings for multipurpose applications: A review,” J. Plast. Film Sheeting, vol. 36, no. 4, pp. 391–408, Oct. 2020, doi: 10.1177/8756087920910481.
  4.  M. Winnicki, T. Piwowarczyk, and A. Małachowska, “General description of cold sprayed coatings formation and of their properties,” Bull. Pol. Acad. Sci. Tech. Sci., vol. 66, no. 3, pp. 301–310, Jun. 2018.
  5.  L. Łatka, L. Pawłowski, M. Winnicki, P. Sokołowski, A. Małachowska, and S. Kozerski, “Review of Functionally Graded Thermal Sprayed Coatings,” Appl. Sci., vol. 10, no. 15, Art. no. 5153, Jan. 2020, doi: 10.3390/app10155153.
  6.  R. Kosydar et al., “Boron nitride/titanium nitride laminar lubricating coating deposited by pulsed laser ablation on polymer surface,” Bull. Pol. Acad. Sci. Tech. Sci., vol. 56, no. 3, pp. 217–221, 2008.
  7.  T. Burakowski and T. Wierzchon, Surface Engineering of Metals: Principles, Equipment, Technologies. Boca Raton, Fla: CRC Press, 1998.
  8.  T. Hejwowski, Nowoczesne powłoki nakładane cieplnie odporne na zużycie ścierne i erozyjne (Modern wear and erosion resitant thermally deposited coatings). Lublin, Poland: Politechnika Lubelska (Lublin University of Technology), 2013. [Online]. Available: http://bc.pollub. pl/dlibra/docmetadata?id=4059.
  9.  Z.W. Wicks. Jr, F.N. Jones, S.P. Pappas, and D.A. Wicks, Organic Coatings: Science and Technology. John Wiley & Sons, 2007.
  10.  S. Biggs, C.A. Lukey, G.M. Spinks, and S.-T. Yau, “An atomic force microscopy study of weathering of polyester/melamine paint surfaces,” Prog. Org. Coat., vol. 42, no. 1, pp. 49–58, Jun. 2001, doi: 10.1016/S0300-9440(01)00147-3.
  11.  M. Oleksy et al., “Kompozycje modyfikowanych farb proszkowych. Cz. 1. Hybrydowe kompozycje poliestrowych farb proszkowych,” Polimery, vol. 63, no. 11– 12, pp. 762‒771, 2018, doi: 10.14314/polimery.2018.11.4.
  12.  M. Fernández-Álvarez, F. Velasco, and A. Bautista, “Effect on wear resistance of nanoparticles addition to a powder polyester coating through ball milling,” J. Coat. Technol. Res., vol. 15, no. 4, pp. 771–779, Jul. 2018, doi: 10.1007/s11998-018-0106-z.
  13.  M. Zouari, M. Kharrat, and M. Dammak, “Wear and friction analysis of polyester coatings with solid lubricant,” Surf. Coat. Technol., vol. 204, no. 16, pp. 2593–2599, May 2010, doi: 10.1016/j.surfcoat.2010.02.001.
  14.  I. Stojanović, V. Šimunović, V. Alar, and F. Kapor, “Experimental Evaluation of Polyester and Epoxy–Polyester Powder Coatings in Aggressive Media,” Coatings, vol. 8, no. 3, Art. no. 98, Mar. 2018, doi: 10.3390/coatings8030098.
  15.  K.V.S.N. Raju and D.K. Chattopadhyay, “Polyester coatings for corrosion protection,” in High-Performance Organic Coatings, A.S. Khanna, Ed. Woodhead Publishing, 2008, pp. 165–200. doi: 10.1533/9781845694739.2.165.
  16.  M. Szala and E. Kot, “Influence of repainting on the mechanical properties, surface topography and microstructure of polyester powder coatings,” Adv. Sci. Technol. Res. J., vol. 11, no. 2, pp. 159–165, Jun. 2017, doi: 10.12913/22998624/69680.
  17.  M. Walczak, D. Pieniak, and M. Zwierzchowski, “The tribological characteristics of SiC particle reinforced aluminium composites,” Arch. Civ. Mech. Eng., vol. 15, no. 1, pp. 116–123, Jan. 2015, doi: 10.1016/j.acme.2014.05.003.
  18.  M. Szala, L. Łatka, M.Walczak, and M.Winnicki, “Comparative Study on the Cavitation Erosion and Sliding Wear of Cold-Sprayed Al/ Al2O3 and Cu/Al2O3 Coatings, and Stainless Steel, Aluminium Alloy, Copper and Brass,” Metals, vol. 10, no. 7, Art. no. 7, Jul. 2020, doi: 10.3390/met10070856.
  19.  V. Caccese, K.H. Light, and K.A. Berube, “Cavitation erosion resistance of various material systems,” Ships Offshore Struct., vol. 1, no. 4, pp. 309–322, Apr. 2006, doi: 10.1533/saos.2006.0136.
  20.  T. Deplancke, O. Lame, J.-Y. Cavaille, M. Fivel, M. Riondet, and J.-P. Franc, “Outstanding cavitation erosion resistance of Ultra High Molecular Weight Polyethylene (UHMWPE) coatings,” Wear, vol. 328–329, pp. 301–308, Apr. 2015, doi: 10.1016/j.wear.2015.01.077.
  21.  N. Qiu, L. Wang, S. Wu, and D.S. Likhachev, “Research on cavitation erosion and wear resistance performance of coatings,” Eng. Fail. Anal., vol. 55, pp. 208–223, Sep. 2015, doi: 10.1016/j.engfailanal.2015.06.003.
  22.  S. Chi, J. Park, and M. Shon, “Study on cavitation erosion resistance and surface topologies of various coating materials used in shipbuilding industry,” J. Ind. Eng. Chem., vol. 26, pp. 384–389, Jun. 2015, doi: 10.1016/j.jiec.2014.12.013.
  23.  G.L. García et al., “Cavitation resistance of epoxybased multilayer coatings: Surface damage and crack growth kinetics during the incubation stage,” Wear, vol. 316, no. 1–2, pp. 124–132, Aug. 2014, doi: 10.1016/j.wear.2014.04.007.
  24.  M. Hibi, K. Inaba, K. Takahashi, K. Kishimoto, and K. Hayabusa, “Effect of Tensile Stress on Cavitation Erosion and Damage of Polymer,” J. Phys. Conf. Ser., vol. 656, no. 1, p. 012049, Nov. 2015, doi: 10.1088/1742-6596/656/1/012049.
  25.  G. Taillon, S. Saito, K. Miyagawa, and C. Kawakita, “Cavitation erosion resistance of high-strength fiber reinforced composite material,” IOP Conf. Ser. Earth Environ. Sci., vol. 240, no. 6, p. 062056, Mar. 2019, doi: 10.1088/1755-1315/240/6/062056.
  26.  N. Sheppard, “The Historical Development of Experimental Techniques in Vibrational Spectroscopy,” in Handbook of Vibrational Spectroscopy, American Cancer Society, 2006. doi: 10.1002/0470027320.s0101.
  27.  R.M. Silverstein et al., Spectrometric Identification of Organic Compounds, 8th Edition, 8th edition. Wiley, 2014.
  28.  W. Macek et al., “Profile and Areal Surface Parameters for Fatigue Fracture Characterisation,” Materials, vol. 13, no. 17, Art. no. 3691, 2020, doi: 10.3390/ma13173691.
  29.  “ISO 4287:1997. Geometrical Product Specifications (GPS) – Surface texture: Profile method – Terms, definitions and surface texture parameters,” International Organization for Standardization, Geneva, Switzerland, Norma, 1997.
  30.  A. Skoczylas, “Influence of Centrifugal Shot Peening Parameters on the Impact Force and Surface Roughness of EN-AW2024 Aluminum Alloy Elements,” Adv. Sci. Technol. Res. J., vol. 15, no. 1, pp. 71–78, Mar. 2021, doi: 10.12913/22998624/130511.
  31.  “ASTM G32-10: Standard Test Method for Cavitation Erosion Using Vibratory Apparatus,” ASTM International: West Conshohocken, Philadelphia, PA, USA, 2010.
  32.  M. Szala, M. Walczak, L. Łatka, K. Gancarczyk, and D. Özkan, “Cavitation Erosion and Sliding Wear of MCrAlY and NiCrMo Coatings Deposited by HVOF Thermal Spraying,” Adv. Mater. Sci., vol. 20, no. 2, pp. 26–38, Jun. 2020, doi: 10.2478/adms-2020-0008.
  33.  J. Steller, A. Krella, J. Koronowicz, and W. Janicki, “Towards quantitative assessment of material resistance to cavitation erosion,” Wear, vol. 258, no. 1, pp. 604–613, Jan. 2005, doi: 10.1016/j.wear.2004.02.015.
  34.  J. Steller, “International Cavitation Erosion Test and quantitative assessment of material resistance to cavitation,” Wear, vol. 233–235, pp. 51–64, Dec. 1999, doi: 10.1016/S0043-1648(99)00195-7.
  35.  B. Dybowski, M. Szala, T. J. Hejwowski, and A. Kiełbus, “Microstructural phenomena occurring during early stages of cavitation erosion of Al-Si aluminium casting alloys,” Solid State Phenom., vol. 227, pp. 255–258, 2015, doi: 10.4028/www.scientific.net/SSP.227.255.
  36.  J. Zhao, Z. Jiang, J. Zhu, J. Zhang, and Y. Li, “Investigation on Ultrasonic Cavitation Erosion Behaviors of Al and Al-5Ti Alloys in the DistilledWater,” Metals, vol. 10, no. 12, Art. no. 1631, Dec. 2020, doi: 10.3390/met10121631.
  37.  J. Lin, Z. Wang, J. Cheng, M. Kang, X. Fu, and S. Hong, “Effect of Initial Surface Roughness on Cavitation Erosion Resistance of Arc- Sprayed Fe-Based Amorphous/Nanocrystalline Coatings,” Coatings, vol. 7, no. 11, Art. no. 2000, Nov. 2017, doi: 10.3390/coatings7110200.
  38.  M. Szala, L. Łatka, M. Awtoniuk, M. Winnicki, and M. Michalak, “Neural Modelling of APS Thermal Spray Process Parameters for Optimizing the Hardness, Porosity and Cavitation Erosion Resistance of Al2O3‒13 wt% TiO2 Coatings,” Processes, vol. 8, no. 12, Art. no. 1544, Dec. 2020, doi: 10.3390/pr8121544.
  39.  J.C. Lindon, Encyclopedia of Spectroscopy and Spectrometry – 3rd Edition. 2010. [Online]. Available: https://www.elsevier.com/books/ encyclopedia-of-spectro scopy-and-spectrometry/lindon/978-0-12-803224-4 (Accessed: Feb. 24, 2021).
  40.  J.I. Haleem, “A Review of: Handbook of Near-Infrared Analysis,” Instrum. Sci. Technol., vol. 22, no. 3, pp. 283–285, Aug. 1994, doi: 10.1080/10739149408000456.
  41. Infrared Spectroscopy: Fundamentals and Applications. John Wiley & Sons, Ltd, 2004, doi: 10.1002/0470011149.ch3.
Go to article

Authors and Affiliations

Mirosław Szala
1
ORCID: ORCID
Aleksander Świetlicki
2
Weronika Sofińska-Chmiel
3
  1. Department of Materials Engineering, Faculty of Mechanical Engineering, Lublin University of Technology, ul. Nadbystrzycka 36, 20-618 Lublin, Poland
  2. Students Research Group of Materials Technology, Department of Materials Engineering, Lublin University of Technology, ul. Nadbystrzycka 36, 20-618 Lublin, Poland
  3. Analytical Laboratory, Institute of Chemical Sciences, Faculty of Chemistry, Maria Curie-Sklodowska University, pl. Maria Curie-Sklodowska 3, 20-031 Lublin, Poland

Accurate identification on individual similar communication emitters by using HVG-NTE feature

Ke Li Wei Ge Xiaoya Yang Zhengrong Xu
Bulletin of the Polish Academy of Sciences Technical Sciences | 2021 | 69 | 2 | e136741 | DOI: 10.24425/bpasts.2021.136741
Keywords communication emitter identification feature extraction HVG NTE
Download PDF Download RIS Download Bibtex

Abstract

Individual identification of similar communication emitters in the complex electromagnetic environment has great research value and significance in both military and civilian fields. In this paper, a feature extraction method called HVG-NTE is proposed based on the idea of system nonlinearity. The shape of the degree distribution, based on the extraction of HVG degree distribution, is quantified with NTE to improve the anti-noise performance. Then XGBoost is used to build a classifier for communication emitter identification. Our method achieves better recognition performance than the state-of-the-art technology of the transient signal data set of radio stations with the same plant, batch, and model, and is suitable for a small sample size.
Go to article

Bibliography

  1.  J. Dudczyk, “Radar emission sources identification based on hierarchical agglomerative clustering for large data sets”, J. Sens. 2016, 1879327 (2016).
  2.  G. Manish, G. Hareesh, and M. Arvind, “Electronic Warfare: Issues and Challenges for Emitter Classification”, Def. Sci. J. 201161(3), 228‒234 (2011).
  3.  J. Dudczyk and A. Kawalec, “Specific emitter identification based on graphical representation of the distribution of radar signal parameters”, Bull. Pol. Acad. Sci. Tech. Sci. 63(2), 391‒396 (2015).
  4.  Q. Xu, R. Zheng, W. Saad, and Z. Han, “Device Fingerprinting in Wireless Networks: Challenges and Opportunities”, IEEE Commun. Surv. Tutor. 18(1), 94‒104 (2016).
  5.  P.C. Adam and G.L. Dennis, “Identification of Wireless Devices of Users Who Actively Fake Their RF Fingerprints With Artificial Data Distortion”, IEEE Trans. Wirel. Commun. 14(11), 5889‒5899 (2015).
  6.  N. Zhou, L. Luo, G. Sheng, and X. Jiang, “High Accuracy Insulation Fault Diagnosis Method of Power Equipment Based on Power Maximum Likelihood Estimation”, IEEE Trans. Power Deliv. 34(4), 1291‒1299 (2019).
  7.  S. Guo, R.E. White, and M. Low, “A comparison study of radar emitter identification based on signal transients”, IEEE Radar Conference, Oklahoma City, 2018, pp. 286‒291.
  8.  Q. Wu, C. Feres, D. Kuzmenko, D. Zhi, Z. Yu, and X. Liu, “Deep learning based RF fingerprinting for device identification and wireless security”, Electron. Lett. 54(24), 1405‒1407 (2018).
  9.  A. Kawalec, R. Owczarek, and J. Dudczyk, “Karhunen-Loeve transformation in radar signal features processing”, International Conference on Microwaves, Krakow, 2006.
  10.  B. Danev and S. Capkun, “Transient-based identification of wireless sensor nodes”, Information Processing in Sensor Networks, San Francisco, 2009, pp. 25‒36.
  11.  R.W. Klein, M.A. Temple, M.J. Mendenhall, and D.R. Reising, “Sensitivity Analysis of Burst Detection and RF Fingerprinting Classification Performance”, International Conference on Communications, Dresden, 2009, pp. 641‒645.
  12.  C. Bertoncini, K. Rudd, B. Nousain, and M. Hinders, “Wavelet Fingerprinting of Radio-Frequency Identification (RFID) Tags”, I IEEE Trans. Ind. Electron. 59(12), 4843‒4850 (2012).
  13.  Z. Shi, X. Lin, C. Zhao, and M. Shi, “Multifractal slope feature based wireless devices identification”, International Conference on Computer Science and Education, Cambridge, 2015, pp. 590‒595.
  14.  C.K. Dubendorfer, B.W. Ramsey, and M.A. Temple, “ZigBee Device Verification for Securing Industrial Control and Building Automation Systems”, International Conference on Critical Infrastructure Protection ,Washington DC, 2013, pp. 47‒62.
  15.  D.R. Reising and M.A. Temple, “WiMAX mobile subscriber verification using Gabor-based RF-DNA fingerprints”, International Conference on Communications, Ottawa, 2012, pp. 1005‒1010.
  16.  Y. Li, Y. Zhao, L. Wu, and J. Zhang, “Specific emitter identification using geometric features of frequency drift curve”, Bull. Pol. Acad. Sci. Tech. Sci. 66, 99‒108 (2018).
  17.  Y. Yuan, Z. Huang, H. Wu, and X. Wang, “Specific emitter identification based on Hilbert-Huang transform-based time-frequency-energy distribution features”, IET Commun. 8(13), 2404‒2412 (2014).
  18.  T.L. Carroll, “A nonlinear dynamics method for signal identification”, Chaos Interdiscip. J. Nonlinear Sci. 17(2), 023109 (2007).
  19.  D. Sun, Y. Li, Y. Xu, and J. Hu, “A Novel Method for Specific Emitter Identification Based on Singular Spectrum Analysis”, Wireless Communications & Networking Conference, San Francisco, 2017, pp. 1‒6.
  20.  Y. Jia, S. Zhu, and G. Lu, “Specific Emitter Identification Based on the Natural Measure”, Entropy 19(3), 117 (2017).
  21.  L. Lacasa, B. Luque, J. Luque, and J.C. Nuno, “The visibility graph: A new method for estimating the Hurst exponent of fractional Brownian motion”, Europhys. Lett. 86(3), 30001‒30005 (2009).
  22.  M. Ahmadlou and H. Adeli, “Visibility graph similarity: A new measure of generalized synchronization in coupled dynamic systems”, Physica D 241(4), 326‒332 (2012).
  23.  S. Zhu and L. Gan, “Specific emitter identification based on horizontal visibility graph”, IEEE International Conference Computer and Communications, Chengdu, 2017, pp. 1328‒1332.
  24.  B. Luque, L. Lacasa, F. Ballesteros, and J. Luque, “Horizontal visibility graphs: Exact results for random time series”, Phys. Rev. E. 80(4), 046103 (2009).
  25.  W. Jiang, B. Wei, J. Zhan, C. Xie, and D. Zhou, “A visibility graph power averaging aggregation operator: A methodology based on network analysis”, Comput. Ind. Eng. 101, 260‒268 (2016).
  26.  M. Wajs, P. Kurzynski, and D. Kaszlikowski, “Information-theoretic Bell inequalities based on Tsallis entropy”, Phys. Rev. A. 91(1), 012114 (2015).
  27.  J. Liang, Z. Huang, and Z. Li, “Method of Empirical Mode Decomposition in Specific Emitter Identification”, Wirel. Pers. Commun. 96(2), 2447‒2461, (2017).
  28.  A.M. Ali, E. Uzundurukan, and A. Kara, “Improvements on transient signal detection for RF fingerprinting”, Signal Processing and Communications Applications Conference (SIU), Antalya, 2017, pp. 1‒4.
  29.  Y. Yuan, Z. Huang, H. Wu, and X. Wang, “Specific emitter identification based on Hilbert-Huang transform-based time-frequency-energy distribution features”, IET Commun. 8(13), 2404‒2412 (2014).
  30.  D.R. Kong and H.B. Xie, “Assessment of Time Series Complexity Using Improved Approximate Entropy”, Chin. Phys. Lett. 28(9), 90502‒90505 (2011).
  31.  T. Chen and C. Guestrin, “XGBoost: A Scalable Tree Boosting System”, Knowledge Discovery and Data Mining, San Francisco, 2016, pp. 785‒794.
  32.  G. Huang, Y. Yuan, X. Wang, and Z. Huang, “Specific Emitter Identification Based on Nonlinear Dynamical Characteristics”, Can. J. Electr. Comp. Eng.-Rev. Can. Genie Electr. Inform. 39(1), 34‒41 (2016).
  33.  D. Sun, Y. Li, Y. Xu, and J. Hu, “A Novel Method for Specific Emitter Identification Based on Singular Spectrum Analysis”, Wireless Communications and Networking Conference, San Francisco, 2017, pp. 1‒6.
Go to article

Authors and Affiliations

Ke Li
1 2 3
ORCID: ORCID
Wei Ge
1 2
ORCID: ORCID
Xiaoya Yang
1 2
Zhengrong Xu
1
  1. School of Information and Computer, Anhui Agricultural University, Hefei, Anhui, 230036, China
  2. Anhui Provincial Engineering Laboratory for Beidou Precision Agriculture Information, Anhui Agricultural University, Hefei, Anhui, 230036, China
  3. Key Laboratory of Specialty Fiber Optics and Optical Access Networks, Shanghai University, Shanghai, 200072, China

Retraction notice Machining of microholes in Ti-6Al-4V by hybrid micro-electrical discharge machining to improve process parameters and flushing properties

Bulletin of the Polish Academy of Sciences Technical Sciences | 2021 | 69 | 4 | e00ret1
Download PDF Download RIS Download Bibtex

Numerical investigation of vortex wake patterns of laminar flow around two side-by-side cylinders

Van Luc Nguyen Duy Knanh Ho
Archive of Mechanical Engineering | 2022 | vol. 69 | No 3 | 541-565 | DOI: 10.24425/ame.2022.141517
Keywords viscous fluid vortex shedding vortex wake pattern vortex-in-cell method two side-by-side cylinders
Download PDF Download RIS Download Bibtex

Abstract

The laminar flow around two side-by-side circular cylinders was numerically investigated using a vortex-in-cell method combined with a continuous-forcing immersed boundary method. The Reynolds number (Re) of the flow was examined in the range from 40 to 200, and the distance between the cylinders varies from 1.2 D to 6 D, where D is the cylinder diameter. Simulation results show that the vortex wake is classified into eight patterns, such as single-bluff-body, meandering-motion, steady, deflected-in-one-direction, flip-flopping, anti-phase-synchronization, in-phase-synchronization, and phase-difference-synchronization, significantly depending on the Re, the cylinder distance, and the initial external disturbance effects. The anti-phase-synchronization, in-phase-synchronization, and phase-difference-synchronization vortex patterns can be switched at a low Re after a long time evolution of the flow. In particular, the single-bluff-body and flip-flopping vortex patterns excite the oscillation amplitude of the drag and lift coefficients exerted on the cylinders.
Go to article

Bibliography

[1] S. Ishigai, E. Nishikawa, K. Nishimura, and K. Cho. Experimental study on structure of gas flow in tube banks with tube axes normal to flow: Part 1, Karman vortex flow from two tubes at various spacings. Bulletin of JSME, 15(86):949–956, 1972. doi: 10.1299/jsme1958.15.949.
[2] P.W. Bearman and A.J.Wadcock. The interaction between a pair of circular cylinders normal to a stream. Journal of Fluid Mechanics, 61(3):499–511, 1973. doi: 10.1017/S0022112073000832.
[3] M.M. Zdravkovich. The effects of interference between circular cylinders in cross flow. Journal of Fluids and Structures, 1(2):239–261, 1987. doi: 10.1016/S0889-9746(87)90355-0.
[4] C.H.K. Williamson. Evolution of a single wake behind a pair of bluff bodies. Journal of Fluid Mechanics, 159:1–18, 1985. doi: 10.1017/S002211208500307X.
[5] H.J. Kim and P.A. Durbin. Investigation of the flow between a pair of circular cylinders in the flopping regime. Journal of Fluid Mechanics, 196:431–448, 1988. doi: 10.1017/S0022112088002769.
[6] K.-S. Chang and C.-J.. Song. Interactive vortex shedding from a pair of circular cylinders in a transverse arrangement. International Journal for Numerical Methods in Fluids, 11(3):317–329, 1990. doi: 10.1002/fld.1650110305.
[7] S. Kang. Characteristics of flow over two circular cylinders in a side-by-side arrangement at low Reynolds numbers. Physics of Fluids, 15(9):2486, 2003. doi: 10.1063/1.1596412.
[8] A. Slaouti and P.K. Stansby. Flow around two circular cylinders by the random-vortex method. Journal of Fluids and Structures, 6(6):641–670, 1992. doi: 10.1016/0889-9746(92)90001-J.
[9] J.R. Meneghini, F. Saltara, C.L.R. Siqueira, and J.A. Ferrari Jr. Numerical simulation of flow interference between two circular cylinders in tandem and side-by-side arrangements. Journal of Fluids and Structures, 15(2):327–350, 2001. doi: 10.1006/jfls.2000.0343.
[10] W. Jester and Y. Kallinderis. Numerical study of incompressible flow about fixed cylinder pairs. Journal of Fluids and Structures, 17(4):561–577, 2003. doi: 10.1016/S0889-9746(02)00149-4.
[11] C.K. Birdsall and D. Fuss. Clouds-in-clouds, clouds-in-cells physics for many-body plasma simulation. Journal of Computational Physics, 3(4):494–511, 1969. doi: 10.1016/0021-9991(69)90058-8.
[12] I.P. Christiansen. Numerical simulation of hydrodynamics by the method of point vortices. Journal of Computational Physics,13(3):363–379,1973. doi: 10.1016/0021-9991(73)90042-9.
[13] G.-H. Cottet and P.D. Koumoutsakos. Vortex Methods: Theory and Practice. Cambridge University Press, 2000.
[14] V.L. Nguyen, R.Z. Lavi, and T. Uchiyama. Numerical simulation of flow around two tandem cylinders by vortex in cell method combined with immersed boundary method. Advances and Applications in Fluid Mechanics, 19(4):781–804, 2016. doi: 10.17654/FM019040787.
[15] V.L. Nguyen, T. Takamure, and T. Uchiyama. Deformation of a vortex ring caused by its impingement on a sphere. Physics of Fluids, 31(10):107108, 2019. doi: 10.1063/1.5122260.
[16] V. L. Nguyen, T. Nguyen-Thoi, and V. D. Duong. Characteristics of the flow around four cylinders of various shapes. Ocean Engineering, 238:109690, 2021.
[17] J.J. Monaghan. Extrapolating B splines for interpolation. Journal of Computational Physics, 60(2):253–262, 1985. doi: 10.1016/0021-9991(85)90006-3.
[18] J.H. Walther and P. Koumoutsakos. Three-dimensional vortex methods for particle-laden flows with two-way coupling. Journal of Computational Physics, 167(1):39–71, 2001. doi: 10.1006/jcph.2000.6656.
[19] C.S. Peskin. Flow patterns around heart valves: a numerical method. Journal of Computational Physics, 10(2):252–271, 1972. doi: 10.1016/0021-9991(72)90065-4.
[20] P. Angot, C.-H. Bruneau, and P. Fabrie. A penalization method to take into account obstacles in incompressible viscous flows. Numerische Mathematik, 81:497–520, 1999. doi: 10.1007/s002110050401.
[21] E.A. Fadlun, R. Verzicco, P. Orlandi, and J. Mohd-Yusof. Combined immersed-boundary finitedifference methods for three-dimensional complex flow simulations. Journal of Computational Physics, 191(1):35–60, 2000. doi: 10.1006/jcph.2000.6484.
[22] N.K.-R. Kevlahan and J.-M. Ghidaglia. Computation of turbulent flow past an array of cylinders using a spectral method with Brinkman penalization. European Journal of Mechanics - B/Fluids, 20(3):333–350, 2001. doi: 10.1016/S0997-7546(00)01121-3.
[23] M. Coquerelle and G.-H.Cottet. Avortex level set method for the two-way coupling of an incompressible fluid with colliding rigid bodies. Journal of Computational Physics, 227(21):9121– 9137, 2008. doi: 10.1016/j.jcp.2008.03.041.
[24] F. Noca, D. Shiels, and D. Jeon. A comparison of methods for evaluating time-dependent fluid dynamic forces on bodies, using only velocity fields and their derivatives. Journal of Fluids and Structures, 13(5):551–578, 1999. doi: 10.1006/jfls.1999.0219.
[25] C. Mimeau, F. Gallizio, G.-H. Cottet, and I. Mortazavi. Vortex penalization method for bluff body flows. International Journal for Numerical Methods in Fluids, 79(2):55–83, 2015. doi: 10.1002/fld.4038.
[26] J.-I. Choi, R.C. Oberoi, J.R. Edwards, and J.A. Rosati. An immersed boundary method for complex incompressible flows. Journal of Computational Physics, 224(2):757–784, 2007. doi: 10.1016/j.jcp.2006.10.032.
[27] AB. Harichandan and A. Roy. Numerical investigation of low Reynolds number flow past two and three circular cylinders using unstructured grid CFR scheme. International Journal of Heat and Fluid Flow, 31(2):154–171, 2010. doi: 10.1016/j.ijheatfluidflow.2010.01.007.
[28] M. Braza, P. Chassaing, and H. Ha Minh. Numerical study and physical analysis of the pressure and velocity fields in the near wake of a circular cylinder. Journal of Fluid Mechanics, 165:79– 130, 1986. doi: 10.1017/S0022112086003014.
[29] K. Supradeepan and A. Roy. Characterisation and analysis of flow over two side by side cylinders for different gaps at low Reynolds number: A numerical approach. Physics of Fluids, 26(6):063602, 2014. doi: 10.1063/1.4883484.
[30] V.L. Nguyen, T. Degawa, and T. Uchiyama. Numerical simulation of annular bubble plume by vortex in cell method. International Journal of Numerical Methods for Heat and Fluid Flow, 29(3):1103–1131, 2019. doi: 10.1108/HFF-03-2018-0094.
Go to article

Authors and Affiliations

Van Luc Nguyen
1
ORCID: ORCID
Duy Knanh Ho
1
  1. Institute of Engineering and Technology, Thu Dau Mot University, Binh Duong Province, Vietnam

Inverse kinematics solution for humanoid robot minimizing gravity-related joint torques

Kacper Mikołajczyk Maksymilian Szumowski Łukasz Woliński
Archive of Mechanical Engineering | 2022 | vol. 69 | No 3 | 393-409 | DOI: 10.24425/ame.2022.140423
Keywords humanoid robot redundant kinematics joint torque minimalization
Download PDF Download RIS Download Bibtex

Abstract

A method of solving the inverse kinematics problem for a humanoid robot modeled as a tree-shaped manipulator is presented. Robot trajectory consists of a set of trajectories of the characteristic points (the robot’s center of mass, origins of feet and hands frames) in the discrete time domain. The description of motion in the frame associated with the supporting foot allows one to represent the robot as a composite of several serial open-loop redundant manipulators. Stability during the motion is provided by the trajectory of the robot’s center of mass which ensures that the zero moment point criterion is fulfilled. Inverse kinematics solution is performed offline using the redundancy resolution at the velocity level. The proposed method utilizes robot’s redundancy to fulfill joint position limits and to reduce gravity-related joint torques. The method have been tested in simulations and experiments on a humanoid robot Melson, and results are presented.
Go to article

Bibliography

[1] P. Gupta, V. Tirth, and R.K. Srivastava. Futuristic humanoid robots: An overview. In First International Conference on Industrial and Information Systems, pages 247–254, 2006. doi: 10.1109/ICIIS.2006.365732.
[2] S. Behnke. Humanoid robots – from fiction to reality? KI– Künstliche Intelligenz, 22(4):5–9, 2008.
[3] C.-H. Ting,W.-H Yeo, Y.-J. King, Y.-D. Chuah, J.-V Lee, and W.-B Khaw. Humanoid robot: A review of the architecture, applications and future trend. Research Journal of Applied Sciences, Engineering and Technology, 7:1178–1183, 2014. doi: 10.19026/rjaset.7.402.
[4] R. Mahum, F. Butt, K. Ayyub, S. Islam, M. Nawaz, and D. Abdullah. A review on humanoid robots. International Journal of Advanced and Applied Sciences, 4(2):83–90, 2017. doi: 10.21833/ijaas.2017.02.015.
[5] S. Saeedvand, M. Jafari, H.S. Aghdasi, and J. Baltes. A comprehensive survey on humanoid robot development. The Knowledge Engineering Review, 34:e20, 2019. doi: 10.1017/S0269888919000158.
[6] E. Krotkov, D. Hackett, L. Jackel, M. Perschbacher, J. Pippine, J. Strauss, G. Pratt, and C. Orlowski. The DARPA robotics challenge finals: Results and perspectives. Journal of Field Robotics, 34(2):229–240, 2016. doi: 10.1002/rob.21683.
[7] M. Vukobratovic and B. Borovac. Zero-Moment Point — Thirty Five Years of Its Life. International Journal of Humanoid Robotics, 01(01):157–173, 2004. doi: 10.1142/s0219843604000083.
[8] Ł. Woliński and M. Wojtyra. A novel QP-based kinematic redundancy resolution method with joint constraints satisfaction. IEEE Access, 10:41023–41037, 2022. doi: 10.1109/ACCESS.2022.3167403.
[9] B.W. Satzinger, J.I. Reid, M. Bajracharya, P. Hebert, and K. Byl. More solutions means more problems: Resolving kinematic redundancy in robot locomotion on complex terrain. In 2014 IEEE/RSJ International Conference on Intelligent Robots and Systems, pages 4861–4867. IEEE, 2014. doi: 10.1109/iros.2014.6943253.
[10] J.J. Kuffner and S.M. LaValle. RRT-connect: An efficient approach to single-query path planning. In Proceedings 2000 ICRA. Millennium Conference. IEEE International Conference on Robotics and Automation. Symposia Proceedings (Cat. No.00CH37065). IEEE, 2000. doi: 10.1109/robot.2000.844730.
[11] B. Siciliano and J.J.E. Slotine. A general framework for managing multiple tasks in highly redundant robotic systems. In Fifth International Conference on Advanced Robotics 'Robots in Unstructured Environments, pages 1211–1216, vol. 2, 1991. doi: 10.1109/ICAR.1991.240390.
[12] B. Siciliano, L. Sciavicco, L.Villani, and G. Oriolo. Robotics. Modelling, Planning and Control. Springer-Verlag, Wien, 1 edition, 2009. doi: 10.1007/978-1-84628-642-1.
[13] B. Siciliano and O. Khatib, editors. Springer Handbook of Robotics. Springer Handbooks. Springer, Berlin, 2 edition, 2016. doi: 10.1007/978-3-540-30301-5.
[14] S. Chiaverini. Singularity-robust task-priority redundancy resolution for real-time kinematic control of robot manipulators. IEEE Transactions on Robotics and Automation, 13(3):398–410, 1997. doi: 10.1109/70.585902.
[15] N. Mansard, O. Khatib, and A. Kheddar. A unified approach to integrate unilateral constraints in the stack of tasks. IEEE Transactions on Robotics, 25(3):670–685, 2009. doi: 10.1109/TRO.2009.2020345.
[16] F. Flacco and A. De Luca. A reverse priority approach to multi-task control of redundant robots. In 2014 IEEE/RSJ International Conference on Intelligent Robots and Systems, pages 2421–2427, 2014. doi: 10.1109/IROS.2014.6942891.
[17] A.A. Maciejewski and C.A. Klein. Obstacle avoidance for kinematically redundant manipulators in dynamically varying environments. The International Journal of Robotics Research, 4(3):109–117, 1985. doi: 10.1177/027836498500400308.
[18] A.S. Deo and I.D.Walker. Minimum effort inverse kinematics for redundant manipulators. IEEE Transactions on Robotics and Automation, 13(5):767–775, 1997. doi: 10.1109/70.631238.
[19] G.S. Chyan and S.G. Ponnambalam. Obstacle avoidance control of redundant robots using variants of particle swarm optimization. Robotics and Computer-Integrated Manufacturing, 28(2):147–153, 2011. doi: 10.1016/j.rcim.2011.08.001.
[20] M. Duguleana, F. Grigore Barbuceanu, A. Teirelbar, and G. Mogan. Obstacle avoidance of redundant manipulators using neural networks based reinforcement learning. Robotics and Computer-Integrated Manufacturing, 28(2):132–146, 2011. doi: 0.1016/j.rcim.2011.07.004.
[21] C. Yang, S. Amarjyoti, X. Wang, Z. Li, H. Ma, and C. Y. Su. Visual servoing control of baxter robot arms with obstacle avoidance using kinematic redundancy. In H. Liu, N. Kubota, X. Zhu, R. Dillmann, and D. Zhou, editors, Intelligent Robotics and Applications, pages 568–580. Springer International Publishing, Cham, 2015. doi: 10.1007/978-3-319-22879-2_52.
[22] T. Petric, A. Gams, N. Likar, and L. Žlajpah. Obstacle avoidance with industrial robots. In G. Carbone and F. Gomez-Bravo, editors, Motion and Operation Planning of Robotic Systems: Background and Practical Approaches, pages 113–145. Springer International Publishing, Cham, 2015. doi: 10.1007/978-3-319-14705-5_5.
[23] T. Winiarski, K. Banachowicz, and D. Seredyński. Multi-sensory feedback control in door approaching and opening. In D. Filev, J. Jabłkowski, J. Kacprzyk, M. Krawczak, I. Popchev, L. Rutkowski, V. Sgurev, E. Sotirova, P. Szynkarczyk, and S. Zadrożny, editors, Intelligent Systems’2014, pages 57–70, Cham, 2015. Springer International Publishing. doi: 10.1007/978-3-319-11310-4_6.
[24] M. Tanaka and F. Matsuno. Modeling and control of head raising snake robots by using kinematic redundancy. Journal of Intelligent & Robotic Systems, 75(1):53–69, 2013. doi: 10.1007/s10846-013-9866-y.
[25] C. Ye, S. Ma, B. Li, and Y. Wang. Head-raising motion of snake-like robots. In 2004 IEEE International Conference on Robotics and Biomimetics, pages 595–600, 2004. doi: 10.1109/ROBIO.2004.1521847.
[26] J.-A. Claret, G. Venture, and L. Basañez. Exploiting the robot kinematic redundancy for emotion conveyance to humans as a lower priority task. International Journal of Social Robotics, 9(2):277–292, 2017. doi: 10.1007/s12369-016-0387-2.
[27] K. Mikołajczyk, M. Szumowski, P. Płoński, and P. Żakieta. Solving inverse kinematics of humanoid robot using a redundant tree-shaped manipulator model. In Proceedings of the 2020 4th International Conference on Vision, Image and Signal Processing, ICVISP 2020, NewYork, NY, USA, 2020. Association for Computing Machinery. doi: 10.1145/3448823.3448885.
[28] M. Szumowski, M.S. Żurawska, and T. Zielińska. Preview control applied for humanoid robot motion generation. Archives of Control Sciences, 29(1):111–132, 2019. doi: 10.24425/acs.2019.127526.
[29] M. Szumowski, M.S. Zurawska, and T. Zielinska. Simplified method for humanoid robot gait generation. In T. Uhl, editor, Advances in Mechanism and Machine Science, pages 2269–2278. Springer International Publishing, 2019. doi: 10.1007/978-3-030-20131-9_224.
[30] T. Zielińska, L. Zimin, M. Szumowski, and W. Ge. Motion planning for a humanoid robot with task dependent constraints. In T. Uhl, editor, Advances in Mechanism and Machine Science, pages 1681–1690. Springer International Publishing, Cham, 2019. doi: 10.1007/978-3-030-20131-9_166.
[31] S. Kajita, F. Kanehiro, K. Kaneko, K. Fujiwara, K. Harada, K. Yokoi, and H. Hirukawa. Biped walking pattern generation by using preview control of zero-moment point. In 2003 IEEE International Conference on Robotics and Automation (Cat. No.03CH37422), volume 2, pages 1620–1626. IEEE, 2003. doi: 10.1109/ROBOT.2003.1241826.
[32] S.R. Buss and J.-S. Kim. Selectively damped least squares for inverse kinematics. J ournal of Graphics Tools, 10(3):37–49, 2005. doi: 10.1080/2151237X.2005.10129202.
[33] A. Ben-Israel and T.N.E. Greville. Generalized Inverses, Theory and Applications. Springer- Verlag New York, 2 edition, 2003. doi: 10.1007/b97366.
[34] P. Falco and C. Natale. On the stability of closed-loop inverse kinematics algorithms for redundant robots. IEEE Transactions on Robotics, 27(4):780–784, 2011. doi: 10.1109/TRO.2011.2135210.
[35] A. Colomé and C. Torras. Closed-loop inverse kinematics for redundant robots: Comparative assessment and two enhancements. IEEE/ASME Transactions on Mechatronics, 20(2):944–955, 2015. doi: 10.1109/TMECH.2014.2326304.
[36] D.N. Nenchev. Redundancy resolution through local optimization: A review. Journal of Robotic Systems, 6(6):769–798, 1989. doi: 10.1002/rob.4620060607.
[37] H. Zghal, R.V. Dubey, and J.A. Euler. Efficient gradient projection optimization for manipulators with multiple degrees of redundancy. In Proceedings., IEEE International Conference on Robotics and Automation, pages 1006–1011, vol. 2, 1990. doi: 10.1109/ROBOT.1990.126123.
[38] A. Liégeois. Automatic supervisory control of the configuration and behavior of multibody mechanisms. IEEE Transactions on Systems, Man, and Cybernetics, 7(12):868–871, 1977. doi: 10.1109/TSMC.1977.4309644.
[39] D.-S. Bae and E. Haug. A recursive formulation for constrained mechanical system dynamics: Part I. Open loop systems. Mechanics of Structures and Machines, 15(3):359–382, 1987. doi: 10.1080/08905458708905124.
[40] G. Rodriguez, A. Jain, and K. Kreutz-Delgado. A spatial operator algebra for manipulator modeling and control. The International Journal of Robotics Research, 10(4):371–381, 1991. doi: 10.1177/027836499101000406.
[41] K. Yamane and L. Nakamura. O(N) forward dynamics computation of open kinematic chains based on the principle of virtual work. In Proceedings 2001 ICRA. IEEE International Conference on Robotics and Automation (Cat. No.01CH37164), volume 3, pages 2824–2831, 2001. doi: 10.1109/ROBOT.2001.933050.
[42] Ł. Woliński and P. Malczyk. Dynamic modeling and analysis of a lightweight robotic manipulator in joint space. Archive of Mechanical Engineering, 62(2):279–302, 2015. doi: 10.1515/meceng-2015-0016.
[43] M.W. Spong, S. Hutchinson, and M. Vidyasagar. Robot Modeling and Control. Wiley, 2005.
[44] B. Espiau and R. Boulic. On the Computation and Control of the Mass Center of Articulated Chains. Technical Report RR-3479, INRIA, August 1998.
[45] D.A.Winter. Biomechanics and Motor Control of Human Movement. JohnWiley & Sons, Inc., 2009. doi: 10.1002/9780470549148.
Go to article

Authors and Affiliations

Kacper Mikołajczyk
1
Maksymilian Szumowski
1
Łukasz Woliński
1
ORCID: ORCID
  1. Faculty of Power and Aeronautical Engineering, Warsaw University of Technology, Warsaw, Poland

Free vibration analysis of sandwich beam with porous FGM core in thermal environment using mesh-free approach

Tran Quang Hung Tran Minh Tu Do Minh Duc
Archive of Mechanical Engineering | 2022 | vol. 69 | No 3 | 471-496 | DOI: 10.24425/ame.2022.140422
Keywords thermal vibration mesh-free method sandwich beam porous materials
Download PDF Download RIS Download Bibtex

Abstract

Thermally induced free vibration of sandwich beams with porous functionally graded material core embedded between two isotropic face sheets is investigated in this paper. The core, in which the porosity phase is evenly or unevenly distributed, has mechanical properties varying continuously along with the thickness according to the power-law distribution. Effects of shear deformation on the vibration behavior are taken into account based on both third-order and quasi-3D beam theories. Three typical temperature distributions, which are uniform, linear, and nonlinear temperature rises, are supposed. A mesh-free approach based on point interpolation technique and polynomial basis is utilized to solve the governing equations of motion. Examples for specific cases are given, and their results are compared with predictions available in the literature to validate the approach. Comprehensive studies are carried out to examine the effects of the beam theories, porosity distributions, porosity volume fraction, temperature rises, temperature change, span-to-height ratio, different boundary conditions, layer thickness ratio, volume fraction index on the vibration characteristics of the beam.
Go to article

Bibliography

[1] D.K. Jha, T. Kant, and R.K. Singh. A critical review of recent research on functionally graded plates. Composite Structures, 96:833–849, 2013. doi: 10.1016/j.compstruct.2012.09.001.
[2] A.S. Sayyad and Y.M. Ghugal. Modeling and analysis of functionally graded sandwich beams: a review. Mechanics of Advanced Materials and Structures, 26(21):1776–1795, 2019. doi: 10.1080/15376494.2018.1447178.
[3] A. Paul and D. Das. Non-linear thermal post-buckling analysis of FGM Timoshenko beam under non-uniform temperature rise across thickness. Engineering Science Technology, an International Journal, 19(3):1608–1625, 2016. doi: 10.1016/j.jestch.2016.05.014.
[4] A. Fallah and M.M. Aghdam. Thermo-mechanical buckling and nonlinear free vibration analysis of functionally graded beams on nonlinear elastic foundation. Composites Part B: Engineering, 43 (3):1523–1530, 2012. doi: 10.1016/j.compositesb.2011.08.041.
[5] A.I. Aria and M.I. Friswell. Computational hygro-thermal vibration and buckling analysis of functionally graded sandwich microbeams. Composites Part B: Engineering, 165:785–797, 2019. doi: 10.1016/j.compositesb.2019.02.028.
[6] S.E. Esfahani, Y. Kiani, and M.R. Eslami. Non-linear thermal stability analysis of temperature dependent FGM beams supported on non-linear hardening elastic foundations. International Journal of Mechanical Sciences, 69:10–20, 2013. doi: 10.1016/j.ijmecsci.2013.01.007.
[7] M. Lezgy-Nazargah. Fully coupled thermo-mechanical analysis of bi-directional FGM beams using NURBS isogeometric finite element approach. Aerospace Science and Technology, 45:154–164, 2015. doi: 10.1016/j.ast.2015.05.006.
[8] L.C. Trinh, T.P. Vo, H.-T. Thai, and T.-K. Nguyen. An analytical method for the vibration and buckling of functionally graded beams under mechanical and thermal loads. Composites Part B: Engineering, 100:152–163, 2016. doi: 10.1016/j.compositesb.2016.06.067.
[9] T.-K. Nguyen, B.-D. Nguyen, T.P. Vo, and H.-T. Thai. Hygro-thermal effects on vibration and thermal buckling behaviours of functionally graded beams. Composite Structures, 176:1050–1060, 2017. doi: 10.1016/j.compstruct.2017.06.036.
[10] P. Malekzadeh and S. Monajjemzadeh. Dynamic response of functionally graded beams in a thermal environment under a moving load. Mechanics of Advanced Materials and Structures, 23(3):248– 258, 2016. doi: 10.1080/15376494.2014.949930.
[11] N. Wattanasakulpong, B. Gangadhara Prusty, and D.W. Kelly. Thermal buckling and elastic vibration of third-order shear deformable functionally graded beams. International Journal of Mechanical Sciences, 53(9):734–743, 2011. doi: 10.1016/j.ijmecsci.2011.06.005.
[12] S.C. Pradhan and T. Murmu. Thermo-mechanical vibration of FGM sandwich beam under variable elastic foundations using differential quadrature method. Journal of Sound and Vibration, 321(1- 2):342–362, 2009. doi: 10.1016/j.jsv.2008.09.018.
[13] G.-L. She, F.-G. Yuan, and Y.-R. Ren. Thermal buckling and post-buckling analysis of functionally graded beams based on a general higher-order shear deformation theory. Applied Mathematical Modelling, 47:340–357, 2017. doi: 10.1016/j.apm.2017.03.014.
[14] H.-S. Shen and Z.-X. Wang. Nonlinear analysis of shear deformable FGM beams resting on elastic foundations in thermal environments. International Journal of Mechanical Sciences, 81:195–206, 2014. doi: 10.1016/j.ijmecsci.2014.02.020.
[15] T.T. Tran, N.H. Nguyen, T.V. Do, P.V. Minh, and N.D. Duc. Bending and thermal buckling of unsymmetric functionally graded sandwich beams in high-temperature environment based on a new third-order shear deformation theory. Journal of Sandwich Structures & Materials, 23(3):906–930, 2021. doi: 10.1177/1099636219849268.
[16] A.R. Setoodeh, M. Ghorbanzadeh, and P. Malekzadeh. A two-dimensional free vibration analysis of functionally graded sandwich beams under thermal environment. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 226(12):2860–2873, 2012. doi: 10.1177/0954406212440669.
[17] L. Chu, G. Dui, and Y. Zheng. Thermally induced nonlinear dynamic analysis of temperature-dependent functionally graded flexoelectric nanobeams based on nonlocal simplified strain gradient elasticity theory. European Journal of Mechanics - A/Solids, 82:103999, 2020. doi: 10.1016/j.euromechsol.2020.103999.
[18] Y. Fu, J. Wang, and Y. Mao. Nonlinear analysis of buckling, free vibration and dynamic stability for the piezoelectric functionally graded beams in thermal environment. Applied Mathematical Modelling, 36(9):4324–4340, 2012. doi: 10.1016/j.apm.2011.11.059.
[19] W.-R. Chen, C.-S. Chen, and H. Chang. Thermal buckling analysis of functionally graded Euler-Bernoulli beams with temperature-dependent properties. Journal of Applied and Computational Mechanics, 6(3):457–470, 2020. doi: 10.22055/JACM.2019.30449.1734.
[20] N. Wattanasakulpong and V. Ungbhakorn. Linear and nonlinear vibration analysis of elastically restrained ends FGM beams with porosities. Aerospace Science and Technology, 32(1):111–120, 2014. doi: 10.1016/j.ast.2013.12.002.
[21] N. Wattanasakulpong and A. Chaikittiratana. Flexural vibration of imperfect functionally graded beams based on Timoshenko beam theory: Chebyshev collocation method. Meccanica, 50(5):1331– 1342, 2015. doi: 10.1007/s11012-014-0094-8.
[22] D. Shahsavari, M. Shahsavari, L. Li, and B. Karami. A novel quasi-3D hyperbolic theory for free vibration of FG plates with porosities resting on Winkler/Pasternak/Kerr foundation. Aerospace Science and Technology, 72:134–149, 2018. doi: 0.1016/j.ast.2017.11.004.
[23] Z. Ibnorachid, L. Boutahar, K. EL Bikri, and R. Benamar. Buckling temperature and natural frequencies of thick porous functionally graded beams resting on elastic foundation in a thermal environment. Advances in Acoustics and Vibration, 2019:7986569, 2019. doi: 10.1155/2019/7986569.
[24] Ş.D. Akbaş. Thermal effects on the vibration of functionally graded deep beams with porosity. International Journal of Applied Mechanics, 9(5):1750076, 2017. doi: 10.1142/ S1758825117500764.
[25] H. Babaei, M.R. Eslami, and A.R. Khorshidvand. Thermal buckling and postbuckling responses of geometrically imperfect FG porous beams based on physical neutral plane. Journal of Thermal Stresses, 43(1):109–131, 2020. doi: 10.1080/01495739.2019.1660600.
[26] F. Ebrahimi and A. Jafari. A higher-order thermomechanical vibration analysis of temperature-dependent FGM beams with porosities. Journal of Engineering, 2016:9561504, 2016. doi: 10.1155/2016/9561504.
[27] Y. Liu, S. Su, H. Huang, and Y. Liang. Thermal-mechanical coupling buckling analysis of porous functionally graded sandwich beams based on physical neutral plane. Composites Part B: Engineering, 168:236–242, 2019. doi: 10.1016/j.compositesb.2018.12.063.
[28] S.S. Mirjavadi, A. Matin, N. Shafiei, S. Rabby, and B. Mohasel Afshari. Thermal buckling behavior of two-dimensional imperfect functionally graded microscale-tapered porous beam. Journal of Thermal Stresses, 40(10):1201–1214, 2017. doi: 0.1080/01495739.2017.1332962.
[29] E. Salari, S.A. Sadough Vanini, A.R. Ashoori, and A.H. Akbarzadeh. Nonlinear thermal behavior of shear deformable FG porous nanobeams with geometrical imperfection: Snap-through and postbuckling analysis. International Journal of Mechanical Sciences, 178:105615, 2020. doi: 10.1016/j.ijmecsci.2020.105615.
[30] N. Ziane, S.A. Meftah, G. Ruta, and A. Tounsi. Thermal effects on the instabilities of porous FGM box beams. Engineering Structures, 134:150–158, 2017. doi: 10.1016/j.engstruct. 2016.12.039.
[31] A.I. Aria, T. Rabczuk, and M.I. Friswell. A finite element model for the thermo-elastic analysis of functionally graded porous nanobeams. European Journal of Mechanics - A/Solids, 77:103767, 2019. doi: 10.1016/j.euromechsol.2019.04.002.
[32] G.R. Liu and Y.T. Gu. A point interpolation method for two-dimensional solids. International Journal for Numerical Methods in Engineering, 50(4):937–951, 2001. doi: 10.1002/1097-0207(20010210)50:4937::AID-NME62>3.0.CO;2-X.
[33] Y.T. Gu and G.R. Liu. A local point interpolation method for static and dynamic analysis of thin beams. Computer Methods in Applied Mechanics and Engineering, 190(42):5515–5528, 2001. doi: 10.1016/S0045-7825(01)00180-3.
[34] T.H. Chinh, T.M. Tu, D.M. Duc, and T.Q. Hung. Static flexural analysis of sandwich beam with functionally graded face sheets and porous core via point interpolation meshfree method based on polynomial basic function. Archive of Applied Mechanics, 91:933–947, 2021. doi: 10.1007/s00419-020-01797-x.
[35] J.N. Reddy and C.D. Chin. Thermomechanical analysis of functionally graded cylinders and plates. Journal of Thermal Stresses, 21(6):593–626, 1998. doi: 10.1080/01495739808956165.
[36] H.-S. Shen. Functionally Graded Materials: Nonlinear Analysis of Plates and Shells. CRC Press, 2016. doi: 10.1201/9781420092578.
[37] T.-K. Nguyen, T.P. Vo, B.-D. Nguyen, and J. Lee. An analytical solution for buckling and vibration analysis of functionally graded sandwich beams using a quasi-3D shear deformation theory. Composite Structures, 156:238–252, 2016. doi: 10.1016/j.compstruct.2015.11.074.
[38] M. Şimşek. Fundamental frequency analysis of functionally graded beams by using different higher-order beam theories. Nuclear Engineering and Design, 240(4):697–705, 2010. doi: 10.1016/j.nucengdes.2009.12.013.
[39] J.N. Reddy. Mechanics of Laminated Composite Plates and Shells: Theory and Analysis. 2nd ed. CRC Press, 2003.
[40] G.R. Liu. Meshfree Methods: Moving Beyond the Finite Element Method. 2nd ed. Taylor & Francis, 2009. doi: 10.1201/9781420082104.
[41] G.R. Liu, Y.T. Gu, and K.Y. Dai. Assessment and applications of point interpolation methods for computational mechanics. International Journal for Numerical Methods in Engineering, 59(10):1373– 1397, 2004. doi: 10.1002/nme.925.
[42] T.P. Vo, H.-T. Thai, T.-K. Nguyen, F. Inam, and J. Lee. A quasi-3D theory for vibration and buckling of functionally graded sandwich beams. Composite Structures, 119:1–12, 2015. doi: 10.1016/j.compstruct.2014.08.006.
Go to article

Authors and Affiliations

Tran Quang Hung
1
Tran Minh Tu
2
ORCID: ORCID
Do Minh Duc
1
  1. Faculty of Civil Engineering, The University of Da Nang - University of Science and Technology, Da Nang, Vietnam
  2. Hanoi University of Civil Engineering, Hanoi, Vietnam

Study on the ankle rehabilitation device

Minh Duc Dao Xuan Tuy Tran Dang Phuoc Pham Quoc Anh Ngo Thi Thuy Tram Le
Archive of Mechanical Engineering | 2022 | vol. 69 | No 1 | 147-163 | DOI: 10.24425/ame.2021.139803
Keywords ankle rehabilitation stroke slide mode controller linear actuator
Download PDF Download RIS Download Bibtex

Abstract

This study developed an ankle rehabilitation device for post-stroke patients. First, the research models and dynamic equations of the device are addressed. Second, the Sliding Mode Controller for the ankle rehabilitation device is designed, and the device's response is simulated on the software MATLAB. Third, the ankle rehabilitation device is successfully manufactured from aluminum and uses linear actuators to emulate dorsiflexion and plantarflexion exercises for humans. The advantages of the device are a simple design, low cost, and mounts onto rehabilitative equipment. The device can operate fast through experiments, has a foot drive mechanism overshoot of 0°, and a maximum angle error of 1°. Moreover, the rehabilitation robot can operate consistently and is comfortable for stroke patients to use. Finally, we will fully develop the device and proceed to clinical implementation.
Go to article

Bibliography

[1] E. Osayande, K.P. Ayodele, M.A. Komolafe. Development of a robotic hand orthosis for stroke patient rehabilitation. International Journal of Online and Biomedical Engineering, 16(13):142–149, 2020. doi: 10.3991/ijoe.v16i13.13407.
[2] Z. Yue, X. Zhang, and J. Wang. Hand Rehabilitation robotics on poststroke motor recovery. Behavioural Neurology, 2017:3908135, 2017. doi: 10.1155/2017/3908135.
[3] C. Grefkes and G.R. Fink. Recovery from stroke: current concepts and futures perspectives. Neurological Research and Practice, 2(1):17, 2020. doi: 10.1186/s42466-020-00060-6.
[4] R. Gassert and V. Dietz. Rehabilitation robots for the treatment of sensorimotor deficits: a neurophysiological perspective. Journal of NeuroEngineering and Rehabilitation, 15:46, 2018. doi: 10.1186/s12984-018-0383-x.
[5] S.H. Hayes and S.R. Carroll. Early intervention care in the acute stroke patient. Archives of Physical Medicine and Rehabilitation, 67(5):319–321, 1986.
[6] D.U. Jette, R.L. Warren, and C. Wirtalla. The relation between therapy intensity and outcomes of rehabilitation in skilled nursing facilities. Archives of Physical Medicine and Rehabilitation, 86(3):373–379, 2005. doi: 10.1016/j.apmr.2004.10.018.
[7] Z. Zhou and Q. Wang. Concept and prototype design of a robotic ankle-foot rehabilitation system with passive mechanism for coupling motion. 2019 IEEE 9th Annual International Conference on CYBER Technology in Automation, Control, and Intelligent Systems (CYBER), pages 1002–1005, Suzhou, China, 29 July -2 August, 2019. doi: 10.1109/cyber46603.2019.9066745.
[8] C.M. Racu and I. Doroftei. An overview on ankle rehabilitation devices. Advanced Materials Research, 1036:781–786, 2014. doi: 10.4028/www.scientific.net/amr.1036.781.
[9] A.A. Blank, J.A. French, A.U. Pehlivan, and M.K. O'Malley. Rehabilitation: Current trends in robot-assisted upper-limb stroke rehabilitation: promoting patient engagement in therapy. Current Physical Medicine and Rehabilitation Reports, 2(3):184–195, 2014.
[10] Z. Liao, L. Yao, Z. Lu, and J. Zhang. Screw theory based mathematical modeling and kinematic analysis of a novel ankle rehabilitation robot with a constrained 3-PSP mechanism topology. International Journal of Intelligent Robotics and Applications, 2(3):351–360, 2018. doi: 10.1007/s41315-018-0063-9.
[11] C.C.K. Lin, M.S. Ju, S.M. Chen, and B.W. Pan. A specialized robot for ankle rehabilitation and evaluation. Journal of Medical and Biological Engineering, 28(2):79–86, 2008.
[12] Z. Sun et al. Mechanism Design and ADAMS-MATLAB-Simulation of a Novel Ankle Rehabilitation Robot. 2019 IEEE International Conference on Robotics and Biomimetic (ROBIO), pages 425–432, Dali, China, December, 2019. doi: 10.1109/robio49542.2019.8961829.
[13] Q. Liu, A. Liu, W. Meng, Q. Ai, and S.Q. Xie. Hierarchical compliance control of a soft ankle rehabilitation robot actuated by pneumatic muscles. Frontiers in Neurorobotics, 11:64, 2017. doi: 10.3389/fnbot.2017.00064.
[14] T. Yonezawa, K. Nomura, T. Onodera, S. Ishimura, H. Mizoguchi, and H. Takemura. Evaluation of venous return in lower limb by passive ankle exercise performed by PHARAD. 2015 37th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC), pages 3582–3585, Milan, Italia, 25–29 August, 2015. doi: 10.1109/embc.2015.7319167.
[15] Ye Ding, M. Sivak, B. Weinberg, C. Mavroidis, and M.K. Holden. NUVABAT: Northeastern university virtual ankle and balance trainer. 2010 IEEE Haptics Symposium, pages 509–514, Waltham, Massachusetts, USA, 25–26 March, 2010. doi: 10.1109/haptic.2010.5444608.
[16] D. Ao, R. Song, and J. Gao. Movement performance of human–robot cooperation control based on emg-driven hill-type and proportional models for an ankle power-assist exoskeleton robot. IEEE Transactions on Neural Systems and Rehabilitation Engineering, 25(8):1125–1134, 2017. doi: 10.1109/tnsre.2016.2583464.
[17] Y. Ren, Y.-N. Wu, C.-Y. Yang, T. Xu, R. L. Harvey, and L.-Q. Zhang. Developing a wearable ankle rehabilitation robotic device for in-bed acute stroke rehabilitation. IEEE Transactions on Neural Systems and Rehabilitation Engineering, 25(6):589–596, 2017. doi: 10.1109/tnsre.2016.2584003.
[18] G. Aguirre-Ollinger, J.E. Colgate, M.A. Peshkin, and A. Goswami. Design of an active one-degree-of-freedom lower-limb exoskeleton with inertia compensation. The International Journal of Robotics Research, 30(4):486–499, 2011. doi: 10.1177/0278364910385730.
[19] Z. Zhou, Y. Sun, N. Wang, F. Gao, K. Wei, and Q. Wang. Robot-assisted rehabilitation of ankle plantar flexors spasticity: a 3-month study with proprioceptive neuromuscular facilitation. Frontiers in Neurorobotics, 10:16, 2016. doi: 10.3389/fnbot.2016.00016.
[20] I. Doroftei, C.M. Racu, C. Honceriu, and D. Irimia. One-degree-of freedom ankle rehabilitation platform. IOP Conference Series: Materials Science and Engineering, 591:012076, 2019. doi: 10.1088/1757-899x/591/1/012076.
[21] A. Gmerek and E. Jezierski. Admittance control of a 1-DoF robotic arm actuated by BLDC motor. 2012 17th International Conference on Methods & Models in Automation & Robotics (MMAR), pages 633–638, Miedzyzdroje, Poland, 27–30 August, 2012. doi: 10.1109/mmar.2012.6347811.
[22] Ł. Woliński. Comparison of the adaptive and neural network control for LWR 4+ manipulators: simulation study. Archive of Mechanical Engineering, 67(1):111–121, 2020. doi: 10.24425/ame.2020.131686.
[23] Meera C S, M.K. Gupta, and S. Mohan. Disturbance observer-assisted hybrid control for autonomous manipulation in a robotic backhoe. Archive of Mechanical Engineering, 66(2):153–169, 2019. doi: 10.24425/ame.2019.128442.
[24] O. Jedda, J. Ghabi and A. Douik. Sliding mode control of an inverted pendulum. In: Derbel N., Ghommam J., Zhu Q. (eds), Applications of Sliding Mode Control. Studies in Systems, Decision and Control, chapter 6:105–118, 2016, Springer. doi: 10.1007/978-981-10-2374-3_6.
[25] S. Singh, M.S. Qureshi, and P. Swarnkar. Comparison of conventional PID controller with sliding mode controller for a 2-link robotic manipulator. 2016 International Conference on Electrical Power And Energy System (ICEPES), pages 115–119, Bhopal, India, 14-16 December, 2016. doi: 10.1109/icepes.2016.7915916.
[26] P. Boscariol and D. Richiedei. Trajectory design for energy savings in redundant robotic cells. Robotics, 8(1):15, 2019. doi: 10.3390/robotics8010015.
[27] M. Adolphe, J. Clerval, Z. Kirchof, R. Lacombe-Delpech, and B. Zagrodny. Center of mass of human's body segments, Mechanics and Mechanical Engineering, 21(3):485–497, 2017.
[28] T. Eiammanussakul and V. Sangveraphunsiri. A lower limb rehabilitation robot in sitting position with a review of training activities. Journal of Healthcare Engineering, 2018:927807, 2018. doi: 10.1155/2018/1927807.
[29] A. Roy, H.I. Krebs, C.T. Bever, L.W. Forrester, R.F. Macko, and N. Hogan. Measurement of passive ankle stiffness in subjects with chronic hemiparesis using a novel ankle robot. Journal of Neurophysiology, 105(5):2132–2149, 2011. doi: 10.1152/jn.01014.2010.
[30] F. Gao, Y. Ren, E.J. Roth, R. Harvey, and L.-Q. Zhang. Effects of repeated ankle stretching on calf muscle–tendon and ankle biomechanical properties in stroke survivors. Clinical Biomechanics, 26(5):516–522, 2011. doi: 10.1016/j.clinbiomech.2010.12.003.
[31] G. Bucca, A. Bezzolato, S. Bruni and F. Molteni. A Mechatronic Device for the Rehabilitation of Ankle Motor Function. Journal of Biomechanical Engineering, 131(12):125001, 2009. doi: 10.1115/1.4000083.
[32] J. Zhong, Y. Zhu, C. Zhao, Z. Han, and X. Zhang. Position tracking of a pneumatic-muscle-driven rehabilitation robot by a single neuron tuned pid controller. Complexity, 2020:438391, 2020. doi: 10.1155/2020/1438391.
Go to article

Authors and Affiliations

Minh Duc Dao
1
ORCID: ORCID
Xuan Tuy Tran
2
Dang Phuoc Pham
1
Quoc Anh Ngo
1
Thi Thuy Tram Le
3
  1. Faculty Technology and Engineering, The Pham Van Dong University, Quang Ngai, Vietnam
  2. Faculty Technology of Mechanical Engineering, The University of Danang – University of Science and Technology, Danang, Vietnam
  3. The Faculty Electronic-Electrical, The Quang Nam College, Quang Nam, Vietnam

Applying rapid heating for controlling thermal displacement of CNC lathe

Van-The Than Chi-Chang Wang Thi-Thao Ngo Guan-Liang Guo
Archive of Mechanical Engineering | 2022 | vol. 69 | No 3 | 519-539 | DOI: 10.24425/ame.2022.140420
Keywords rapid heating CNC lathe thermal displacement ball screw temperature control
Download PDF Download RIS Download Bibtex

Abstract

Thermal error always exists in a machine tool and accounts for a large part of the total error in the machine. Thermal displacement in X-axis on a CNC lathe is controlled based on a rapid heating system. Positive Temperature Coefficient (PTC) heating plates are installed on the X-axis of the machine. A control temperature system is constructed for rapid heating which further helps the thermal displacement to quickly reach stability. The system then continuously maintains stable compensation of the thermal error. The presented rapid heating technique is simpler than the compensation of machine thermal errors by interference in the numerical control system. Results show that the steady state of the thermal displacement in the X-axis can be acquired in a shorter time. In addition, almost all thermal errors in constant and varying working conditions could be significantly reduced, by above 80% and 60%, respectively, compared to those without using the rapid heating. Therefore, the proposed method has a high potential for application on the CNC lathe machine for improving its precision.
Go to article

Bibliography

[1] J. Bryan. International status of thermal error research. CIRP Annals, 39(2):645–656, 1990. doi: 10.1016/S0007-8506(07)63001-7.
[2] J. Mayr, J. Jedrzejewski, E. Uhlmann, M. Alkan Donmez, W. Knapp, F. Härtig, et al. Thermal issues in machine tools. CIRP Annals, 61(2):771–791, 2012. doi: 10.1016/j.cirp.2012.05.008.
[3] H. Wang, F. Li, Y. Cai, Y. Liu, and Y. Yang. Experimental and theoretical analysis of ball screw under thermal effect. Tribology International, 152:106503, 2020. doi: 10.1016/j.triboint.2020.106503.
[4] C. Jin, B. Wu, and Y. Hu. Heat generation modeling of ball bearing based on internal load distribution. Tribology International, 45(1):8–15, 2012. doi: 10.1016/j.triboint.2011.08.019.
[5] J. Liu, C. Ma, S. Wang, S. Wang, B. Yang, and H. Shi. Thermal boundary condition optimization of ball screw feed drive system based on response surface analysis. Mechanical Systems and Signal Processing, 121:471–495, 2019. doi: 10.1016/j.ymssp.2018.11.042.
[6] C.-H. Wu and Y.-T. Kung. Thermal analysis for the feed drive system of a CNC machine center. International Journal of Machine Tools and Manufacture, 43(15):1521–1528, 2003. doi: 10.1016/j.ijmachtools.2003.08.008.
[7] H. Shi, C. Ma, J. Yang, L. Zhao, X. Mei, and G. Gong. Investigation into effect of thermal expansion on thermally induced error of ball screw feed drive system of precision machine tools. International Journal of Machine Tools and Manufacture, 97:60–71, 2015. doi: 10.1016/j.ijmachtools.2015.07.003.
[8] W.S. Yun, S.K. Kim, and D.W. Cho. Thermal error analysis for a CNC lathe feed drive system. International Journal of Machine Tools and Manufacture, 39:1087–1101, 1999. doi: 10.1016/S0890-6955(98)00073-X.
[9] H. Shi, B. He, Y. Yue, C. Min, and X. Mei. Cooling effect and temperature regulation of oil cooling system for ball screw feed drive system of precision machine tool. Applied Thermal Engineering, 161:114150, 2019. doi: 10.1016/j.applthermaleng.2019.114150.
[10] Z.Z. Xu, X.J. Liu, H.K. Kim, J.H. Shin, and S.K. Lyu. Thermal error forecast and performance evaluation for an air-cooling ball screw system. International Journal of Machine Tools and Manufacture, 51(7-8):605–611, 2011. doi: 10.1016/j.ijmachtools.2011.04.001.
[11] S.-C. Huang. Analysis of a model to forecast thermal deformation of ball screw feed drive systems. International Journal of Machine Tools and Manufacture, 35,(8):1099–1104, 1995. doi: 10.1016/0890-6955(95)90404-A.
[12] T.-J. Li, J.-H. Yuan, Y.-M. Zhang, and C.-Y. Zhao. Time-varying reliability prediction modeling of positioning accuracy influenced by frictional heat of ball-screw systems for CNC machine tools. Precision Engineering, 64:147–156, 2020. doi: 10.1016/j.precisioneng.2020.04.002.
[13] C. Ma, J. Liu, and S. Wang. Thermal error compensation of linear axis with fixed-fixed installation. International Journal of Mechanical Sciences, 175:105531, 2020. doi: 10.1016/j.ijmecsci.2020.105531.
[14] J. Zapłata and M. Pajor. Piecewise compensation of thermal errors of a ball screw driven CNC axis. Precision Engineering, 60:160–166, 2019. doi: 10.1016/j.precisioneng.2019.07.011.
[15] W. Feng, Z. Li, Q. Gu, and J. Yang. Thermally induced positioning error modelling and compensation based on thermal characteristic analysis. International Journal of Machine Tools and Manufacture, 93:26–36, 2015. doi: 10.1016/j.ijmachtools.2015.03.006.
[16] H. Zhou, P. Hu, H. Tan, J. Chen, and G. Liu. Modelling and compensation of thermal deformation for machine tool based on the real-time data of the CNC system. Procedia Manufacturing, 26:1137–1146, 2018. doi: 10.1016/j.promfg.2018.07.150.
[17] A.A. Kendoush. An approximate solution of the convective heat transfer from an isothermal rotating cylinder. International Journal of Heat and Fluid Flow, 17(4):439–441, 1996. doi: 10.1016/0142-727X(95)00002-8.
[18] T.L. Bergman, F.P. Incropera, D.P. DeWitt, and A.S. Lavine. Fundamentals of Heat and Mass Transfer. 7th edition, John Wiley & Sons, 2011.
[19] Z. Li, K. Fan, J. Yang, and Y. Zhang. Time-varying positioning error modeling and compensation for ball screw systems based on simulation and experimental analysis. The International Journal of Advanced Manufacturing Technology, 73:773–782, 2014. doi: 10.1007/s00170-014-5865-9.
[20] J.G. Yang, Y.Q. Ren, and Z.C. Du. An application of real-time error compensation on an NC twin-spindle lathe. Journal of Materials Processing Technology, 129(1-3):474–479, 2002. doi: 10.1016/S0924-0136(02)00618-0.
Go to article

Authors and Affiliations

Van-The Than
1
ORCID: ORCID
Chi-Chang Wang
2
Thi-Thao Ngo
1
Guan-Liang Guo
2
  1. Faculty of Mechanical Engineering, Hung Yen University of Technology and Education, Khoai Chau District, Hung Yen Province, Vietnam
  2. Department of Mechanical and Computer-Adided Engineering, Feng Chia University, Taichung, Taiwan, R.O.C.

Hybrid robot hand for stably manipulating one group objects

Pho Van Nguyen Phi N. Nguyen Tan Nguyen Thanh Lanh Le
Archive of Mechanical Engineering | 2022 | vol. 69 | No 3 | 375-391 | DOI: 10.24425/ame.2022.140421
Keywords hybrid gripper soft gripper manipulate group objects handle multiple objects hybrid robot hand
Download PDF Download RIS Download Bibtex

Abstract

Autonomous manipulation of group objects requires the gripper/robot hand to achieve high productivity without poor outcomes such as object slippage and damage. This article develops the robot hand capable of achieving effective performance in each trial of grasping the group objects. Our proposed robot hand consists of two symmetrical groups of hybrid fingers having soft pads on the grasping interfaces, which operate as a comb. The grasping ability of this robot hand was theoretically and experimentally validated by handling three groups of objects showcases: tea packs, toothbrushes, and mixing sticks.Additionally, validation resultswere compared with those of another soft robot hand having soft Pneunet fingers. In each trial, the experimental results showed that the proposed robot hand with hybrid fingers achieved more stable grasping states characterized by a higher number of grasped objects than those in the case of the soft robot hand. Also, experimental results were in good agreement with the predictions of the proposed theoretical analysis. Finally, better performances of the hybrid robot hand in handling the group object provide the bases for developing a novel-robotic application in industrial production.
Go to article

Bibliography

[1] D. Rus and M.T. Tolley. Design, fabrication and control of soft robots. Nature, 521:467–475, 2015. doi: 10.1038/nature14543.
[2] S.N. Gorb. Biological attachment devices: exploring nature’s diversity for biomimetics. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 366(1870):1557–1574, 2008. doi: 10.1098/rsta.2007.2172.
[3] S. Kim, M. Spenko, S. Trujillo, B. Heyneman, V. Mattoli, and M.R. Cutkosky. Whole body adhesion: hierarchical, directional and distributed control of adhesive forces for a climbing robot. Proceedings 2007 IEEE International Conference on Robotics and Automation (ICRA), pages 1268–1273, 2007. doi: 10.1109/ROBOT.2007.363159.
[4] E. W. Hawkes, H. Jiang, D. L. Christensen, A. K. Han, and M. R. Cutkosky. Grasping without squeezing: Design and modeling of shear-activated grippers. IEEE Transactions on Robotics, 34(2):303–316, 2018. doi: 10.1109/TRO.2017.2776312.
[5] J. Shintake, S. Rosset, B. Schubert, D. Floreano, and H. Shea. Versatile soft grippers with intrinsic electroadhesion based on multifunctional polymer actuators. Advanced Materials, 28(2):231–238, 2016. doi: 10.1002/adma.201504264.
[6] B. Mazzolai, A. Mondini, F. Tramacere, G. Riccomi, A. Sadeghi, G. Giordano, E. Del Dottore, M. Scaccia, M. Zampato, and S. Carminati. Octopus-inspired soft arm with suction cups for enhanced grasping tasks in confined environments. Advanced Intelligent Systems, 1(6):1900041, 2019. doi: 10.1002/aisy.201900041.
[7] P.V. Nguyen and V.A. Ho. Grasping interface with wet adhesion and patterned morphology: Case of thin shell. IEEE Robotics and Automation Letters, 4(2):792–799, 2019. doi: 10.1109/LRA.2019.2893401.
[8] D.N. Nguyen, N.L. Ho, T.-P. Dao, and C.N. Le. Multi-objective optimization design for a sand crab-inspired compliant microgripper. Microsystem Technologies, 25, 2019. doi: 10.1007/s00542-019-04331-4.
[9] J. Hughes, U. Culha, F. Giardina, F. Guenther, A. Rosendo, and F. Iida. Soft manipulators and grippers: A review. Frontiers in Robotics and AI, 3:69, 2016. doi: 10.3389/frobt.2016.00069.
[10] Phoung H. Le, Thien P. Do, and Du B. Le. A soft pneumatic finger with different patterned profile. International Journal of Mechanical Engineering and Robotics Research, 10(10):577– 582, 2021. doi: 10.18178/ijmerr.10.10.577-582.
[11] T.-P. Dao,N.L. Ho, T.T. Nguyen, H.G. Le, P.T. Thang, H.-T. Pham, H.-T. Do, M.-D. Tran, and T.T. Nguyen. Analysis and optimization of a micro-displacement sensor for compliant microgripper. Microsystem Technologies, 23:5375–5395, 2017. doi: 10.1007/s00542-017-3378-9.
[12] P.V. Nguyen, Q.K. Luu, Y. Takamura, and V.A. Ho. Wet adhesion of micro-patterned interfaces for stable grasping of deformable objects. 2020 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), pages 9213–9219, 2020. doi: 10.1109/IROS45743.2020.9341095.
[13] M. Calisti, M. Giorelli, G. Levy, B. Mazzolai, B. Hochner, C. Laschi, and P. Dario. An octopus-bioinspired solution to movement and manipulation for soft robots. Bioinspiration & Biomimetics, 6(3):036002, 2011. doi: 10.1088/1748-3182/6/3/036002.
[14] K.C. Galloway, K.P. Becker, B. Phillips, J. Kirby, S. Licht, D. Tchernov, R.J. Wood, and D.F. Gruber. Soft robotic grippers for biological sampling on deep reefs. Soft Robotics, 3(1):23–33, 2016. doi: 10.1089/soro.2015.0019.
[15] 2F-85 and 2F-140 Grippers. https://robotiq.com/products/2f85-140-adaptive-robot-gripper.
[16] Forestry Cranes https://marchesigru.com/en/forestry-cranes-2.
[17] H. Hyyti, V.V. Lehtola, and A. Visala. Forestry crane posture estimation with a two-dimensional laser scanner. Journal of Field Robotics, 35(7):1025–1049, 2018. doi: 10.1002/rob.21793.
[18] K.W. Allen. Encyclopedia of Physical Science and Technology – Materials. Elsevier, 2001.
[19] P.V. Nguyen, T.H. Bui, and V.A. Ho. Towards safely grasping group objects by hybrid robot hand. 2021 4th International Conference on Robotics, Control and Automation Engineering (RCAE), pages 389–393, 2021. doi: 10.1109/RCAE53607.2021.9638841.
[20] T.-L. Le, J.-C. Chen, F.-S. Hwu, and H.-B. Nguyen. Numerical study of the migration of a silicone plug inside a capillary tube subjected to an unsteady wall temperature gradient. International Journal of Heat and Mass Transfer, 97:439–449, 2016. doi: 10.1016/j.ijheatmasstransfer.2015.11.098.
[21] P.V. Nguyen and V.A. Ho. Wet adhesion of soft curved interfaces with micro pattern. IEEE Robotics and Automation Letters, 6(3):4273–4280, 2021. doi: 10.1109/LRA.2021.3067277.
[22] J. Gao, W.D. Luedtke, D. Gourdon, M. Ruths, J.N. Israelachvili, and U. Landman. Frictional forces and amontons’ law: From the molecular to the macroscopic scale. The Journal of Physical Chemistry B, 108(11):3410–3425, 2004. doi: 10.1021/jp036362l.
[23] D. Maruthavanan, A. Seibel, and J. Schlattmann. Fluid-structure interaction modelling of a soft pneumatic actuator. Actuators, 10(7):163, 2021. doi: 10.3390/act10070163.
[24] D.X. Phu, V. Mien, P.H.T. Tu, N.P. Nguyen, and S.-B. Choi. A new optimal sliding mode controller with adjustable gains based on Bolza-Meyer criterion for vibration control. Journal of Sound and Vibration, 485:115542, 2020. doi: 10.1016/j.jsv.2020.115542.
Go to article

Authors and Affiliations

Pho Van Nguyen
1 2
ORCID: ORCID
Phi N. Nguyen
2
Tan Nguyen
2
Thanh Lanh Le
2
  1. Japan Advanced Institute of Science and Technology, 1-1 Asahidai, Nomi, Ishikawa, Japan
  2. Department of Technology, Dong Nai Technology University, Bien Hoa 810000, Vietnam

Investigating the effects of alumina nanoparticles on the impact resistance of polycarbonate nano-composites

Ali Alavi Nia Saeed Amirchakhmaghi
Archive of Mechanical Engineering | 2022 | vol. 69 | No 3 | 431-454 | DOI: 10.24425/ame.2022.140419
Keywords nanoparticles alumina ballistic test nano-composite polycarbonates surface treatments
Download PDF Download RIS Download Bibtex

Abstract

In this project, two types of treated and untreated alumina nanoparticles with different weight percentages (wt%) of 0.5, 1 and 3% were mixed with polycarbonate matrix; then, the impact ballistic properties of the nano-composite targets made from them were investigated. Three types of projectile noses -cylindrical, hemispherical, and conical, each with the same mass of 5.88\;gr -- were used in the ballistic tests. The results highlighted that ballistic limit velocities were improved by increasing the percentage of alumina nanoparticles and the treatment process; changing the projectile's nose geometry from conical to blunt nose increases the ballistic limit velocity, and ultimately, by increasing the initial velocity of conical and hemispherical nosed projectiles, the failure mechanism of the targets changed from dishing to petalling; whereas for the cylindrical projectile, the failure mode was always plugging.
Go to article

Bibliography

[1] S. Fu, Y. Wang, and Y. Wang. Tension testing of polycarbonate at high strain rates. Polymer Testing, 28(7):724–729, 2009. doi: 10.1016/j.polymertesting.2009.06.002.
[2] Q.H. Shah and Y.A. Abkar. Effect of distance from the support on the penetration mechanism of clamped circular polycarbonate armor plates. International Journal of Impact Engineering, 35(11):1244–125, 2008. doi: 10.1016/j.ijimpeng.2007.07.012.
[3] Q.H. Shah. Impact resistance of a rectangular polycarbonate armor plate subjected to single and multiple impacts. International Journal of Impact Engineering, 36(9):1128–113, 2009. doi: 10.1016/j.ijimpeng.2008.12.005.
[4] M.R. Edwards and H. Waterfall. Mechanical and ballistic properties of polycarbonate apposite to riot shield applications. Plastic Rubber Composites, 37(1):1–6, 2008. doi: 10.1179/174328908X283177.
[5] I. Livingstone, M. Richards, and R. Clegg. Numerical and experimental investigation of ballistic performance of transparent armour systems. Lightweight Armour Systems Symposium Conference, UK, 10-12 November, 1999.
[6] S.C. Wright, N.A. Fleck, and W.J. Stronge. Ballistic impact of polycarbonate–An experimental investigation. International Journal of Impact Engineering, 13(1):1–20, 1993. doi: 10.1016/0734-743X(93) 90105-G.
[7] M. Rahman, M. Hosur, S. Zainuddin, U. Vaidya, A. Tauhid, A. Kumar, J. Trovillion, and S. Jeelani. Effects of amino-functionalized MWCNTs on ballistic impact performance of E-glass/epoxy composites using a spherical projectile. International Journal of Impact Engineering, 57:108–118, 2013. doi: 10.1016/j.ijimpeng.2013.01.011.
[8] S.G. Kulkarni, X.L. Gao, S.E. Horner, J.Q. Zheng, and N.V. David. Ballistic helmets – Their design, materials, and performance against traumatic brain injury. Composite Structures, 101:313–331, 2013. doi: 10.1016/j.compstruct.2013.02.014.
[9] W. Al-Lafi, J. Jin, and M. Song. Mechanical response of polycarbonate nanocomposites to high velocity impact. European Polymer Journal, 85:354–262, 2016. doi: 10.1016/j.eurpolymj. 2016.10.048.
[10] A. Kurzawa, D. Pyka, and K. Jamroziak. Analysis of ballistic resistance of composites with EN AW-7075 matrix reinforced with Al2O3 particles. Archive of Foundry Engineering, 20(1):73–78, 2020. doi: 10.24425/afe.2020.131286.
[11] P.H.C. Camargo, K.G. Satyanarayana, and F. Wypych. Nanocomposite: synthesis, structure, properties and new application opportunities. Materials Research, 12(1):1–39, 2009. doi: 10.1590/S1516-14392009000100002.
[12] R. Jacob, A.P. Jacob, and D.E. Mainwaring. Mechanism of the dielectric enhancement in polymer–alumina nano-particle composites. Journal of Molecular Structure, 933(1-3):77–85, 2009. doi: 10.1016/j.molstruc.2007.05.041.
[13] X. Zhang and L.C. Simon. In situ polymerization of hybrid polyethylene-alumina nanocomposites. Macromolecular Materials and Engineering, 290(6):573–583, 2005. doi: 10.1002/mame. 200500075.
[14] S. Zhao, L.S. Schadleer, R. Duncan, H. Hillborg, and T. Auletta. Mechanisms leading to improved mechanical performance in nanoscale alumina filled epoxy. Composites Science and Technology, 68(14):2965–2975, 2008. doi: 10.1016/j.compscitech.2008.01.009.
[15] S.C. Zunjarrao and R.P. Singh. Characterization of the fracture behavior of epoxy reinforced with nanometer and micrometer sized aluminum particles. Composites Science and Technology, 66(13):2296–2305, 2006. doi: 10.1016/j.compscitech.2005.12.001.
[16] S. Amirchakhmaghi, A. Alavi Nia, Gh. Azizpour, and H. Bamdadi. The effect of surface treatment of alumina nanoparticles with a silane coupling agent on the mechanical properties of polymer nanocomposites. Mechanics of Composite Materials, 51(3):347– 358, 2015. doi: 10.1007/s11029-015-9506-7.
[17] E.A. Ferriter, A. McCulloh, and W. deRosset. Techniques used to estimate limit velocity in ballistic testing with small sample size. In Proceedings of the 13th Annual U.S. Army Research Laboratory Conference, pages 72–95, USA, 2005.
[18] Bayer MateralScience AG., Polycarbonates Business Unit., (2013). www.plastics.bayer.com/Products/Makrolon/ProductList/201305212210/Makrolon- 2807.aspx.
[19] A. Chandra, L.S. Turng, P. Gopalan, R.M. Rowell, and S. Gong. Study of utilizing thin polymer surface coating on the nanoparticles for melt compounding of polycarbonate/alumina nanocomposites and their optical properties. Composites Science and Technology, 68(3-4):768–776, 2008. doi: 10.1016/j.compscitech.2007.08.027.
[20] Z. Zatorski. Diagnostics of ballistic resistance of multi-layered shields. \textit{Archive of Mechanical Engineering, 54(3):205–218, 2007. doi: 10.24425/ame.2007.131555.
[21] H. Motulsky and A. Christopoulos. Fitting Models to Biological Data Using Linear and Nonlinear Regression, a Particle Guide to Curve Fitting. GraphPad Software Inc., San Diego CA, 2003.
Go to article

Authors and Affiliations

Ali Alavi Nia
1
Saeed Amirchakhmaghi
2
  1. Department of Mechanical Engineering, Bu Ali Sina University, Hamedan, Iran
  2. Department of Mechanical Industrial and Aerospace engineering, Concordia University, Montreal, Canada

Investigation of deformation behaviour of steel, aluminium and copper alloys during hydro-mechanical drawing

Binayak Nahak Anil Kumar Anshul Yadav Jerzy Winczek
Archive of Mechanical Engineering | 2022 | vol. 69 | No 3 | 455-469 | DOI: 10.24425/ame.2022.141516
Keywords hydro-mechanical drawing EN10130 copper C12200 aluminium 8011 deformation
Download PDF Download RIS Download Bibtex

Abstract

The hydro-mechanical drawing combines conventional deep drawing and sheet hydroforming and is widely used in the automotive industry. In this study, we designed and fabricated an indigenous experimental set-up that is low cost, low weight and portable. This study investigated the deformation of sheet metals into hemispherical cup-shaped parts made of different materials, viz., aluminium 8011 alloys, copper C12200 and steel EN10130 alloys. The initial thickness of sheet metal was 0.4 mm, the most common thickness range used in automotive applications. The deformation behaviour in terms of dome height has been measured by varying the pressure of the fluids. Aluminium 8011 alloy sheets showed a maximum dome height of 11.46 mm at a pressure of 1.47 MPa with no rupture. Steel EN10130 sheets had a maximum dome height of 10.89 mm at a pressure of 9.31 MPa. It was concluded that the behaviours of materials are different in the hydro-mechanical drawing process than in mechanical tests. Copper C12200 sheet showed superior formability with a maximum dome height of 18.91 mm at a pressure of 7.06 MPa than other materials without fracture.
Go to article

Bibliography

[1] M.-G. Lee, Y.P. Korkolis, and J.H. Kim. Recent developments in hydroforming technology. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 229(4):572–596, 2015. doi: 10.1177/0954405414548463.
[2] C. Bell, J. Corney, N. Zuelli, and D. Savings. A state of the art review of hydroforming technology. International Journal of Material Forming, 13:789–828, 2020. doi: 10.1007/s12289-019-01507-1.
[3] F.T. Feyissa and D.R. Kumar. Enhancement of drawability of cryorolled AA5083 alloy sheets by hydroforming. Journal of Materials Research and Technology, 8(1):411–423, 2019. doi: 10.1016/j.jmrt.2018.02.012.
[4] L.H. Lang, Z.R. Wang, D.C. Kang, S.J. Yuan, S.H. Zhang, J. Danckert, and K.B. Nielsen. Hydroforming highlights: sheet hydro-forming and tube hydro-forming. Journal of Materials Processing Technology, 151(1-3):165–177, 2004. doi: 10.1016/j.jmatprotec.2004.04.032.
[5] K. Siegert, M. Häussermann, B. Lösch, and R. Rieger. Recent developments in hydroforming technology, Journal of Materials Processing Technology, 98(2):251–258, 2000. doi: 10.1016/S0924-0136 (99)00206-X.
[6] H. Hu, J.-F. Wang, K.-T. Fan, T.-Y. Chen, and S.-Y. Wang. Development of sheet hydroforming for making an automobile fuel tank. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 229(4):654–663, 2015. doi: 10.1177/0954405414554666.
[7] T. Nakagawa, K. Nakamura, and H. Amino. Various applications of hydraulic counter-pressure deep drawing. Journal of Materials Processing Technology, 71(1):160–167, 1997. doi: 10.1016/S0924- 0136(97)00163-5.
[8] H. Amino, K. Nakamura, and T. Nakagawa. Counter-pressure deep drawing and its application in the forming of automobile parts. Journal of Materials Processing Technology, 23(3):243–265, 1990. doi: 10.1016/0924-0136(90)90244-O.
[9] K. Nakamura and T. Nakagawa. Sheet metal forming with hydraulic counter pressure in Japan. CIRP Annals, 36(1):191–194, 1987. doi: 10.1016/S0007-8506(07)62583-9.
[10] S.H. Zhang, Z.R. Wang, Y. Xu, Z.T. Wang, and L.X. Zhou. Recent developments in sheet hydroforming technology. Journal of Materials Processing Technology, 151(1-3):237–241, 2004. doi: 10.1016/j.jmatprotec.2004.04.054.
[11] N. Abedrabbo, M.A. Zampaloni, and F. Pourboghrat. Wrinkling control in aluminum sheet hydroforming. International Journal of Mechanical Sciences, 47(3):333–358, 2005. doi: 10.1016/j.ijmecsci.2005.02.003.
[12] M. Koç and O.N. Cora. Introduction and state of the art of hydroforming. In: M. Koç (editor), Hydroforming for Advanced Manufacturing, pages 1–29, Elsevier, 2008. doi: 10.1533/9781845694418.1.
[13] M. Chen, X. Xiao, H. Guo, and J. Tong. Deformation behavior, microstructure and mechanical properties of pure copper subjected to tube hydro-forming. Materials Science and Engineering: A, 731 (2018) 331–343. doi: 10.1016/j.msea.2018.06.068.
[14] A.A. Emiru, D.K. Sinha, A. Kumar, and A. Yadav. Fabrication and characterization of hybrid aluminium (Al6061) metal matrix composite reinforced with SiC, B 4C and MoS 2 via stir casting. International Journal of Metalcasting, 2022. doi: 10.1007/s40962-022-00800-1.
[15] F. Hasan, R. Jaiswal, A. Kumar, and A. Yadav. Effect of TiC and graphite reinforcement on hardness and wear behaviour of copper alloy B-RG10 composites fabricated through powder metallurgy. JMST Advances, 4:1–11, 2022. doi: 10.1007/s42791-022-00043-5.
[16] K.S.A. Ali, V. Mohanavel, S.A. Vendan, M. Ravichandran, A. Yadav, M. Gucwa, and J. Winczek. Mechanical and microstructural characterization of friction stir welded SiC and B 4C reinforced aluminium alloy AA6061 metal matrix composites. Materials, 14 (11):3110, 2021. doi: 10.3390/ma14113110.
[17] L. Prasad, N. Kumar, A. Yadav, A. Kumar, V. Kumar, and J.~Winczek. In situ formation of ZrB 2 and its influence on wear and mechanical properties of ADC12 alloy mixed matrix composites. Materials, 14(9):2141, 2021. doi: 10.3390/ma14092141.
[18] S. Thiruvarudchelvan and F. Travis. An exploration of the hydraulic-pressure assisted redrawing of cups. Journal of Materials Processing Technology, 72(1):117–123, 1997. doi: 10.1016/S0924-0136 (97)00138-6.
[19] J.B. Kim, D.W. Lee, D.Y. Yang, and C.S. Park. Investigation into hydro-mechanical reverse redrawing assisted by separate radial pressure—process development and theoretical verification. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 211(6):451–462, 1997. doi: 10.1243/0954405971516419.
[20] M. Janbakhsh, M. Riahi, and F. Djavanroodi. A practical approach to analysis of hydro-mechanical deep drawing of superalloy sheet metals using finite element method. International Journal of Advanced Design and Manufacturing Technology, 6(1):1–7, 2013.
[21] E. Karajibani, R. Hashemi, and M. Sedighi. Forming limit diagram of aluminum-copper two-layer sheets: numerical simulations and experimental verifications. The International Journal of Advanced Manufacturing Technology, 90:2713–2722, 2017. doi: 10.1007/s00170-016-9585-1.
[22] S. Yaghoubi and F. Fereshteh-Saniee. An investigation on the effects of the process parameters of hydro-mechanical deep drawing on manufacturing high-quality bimetallic spherical-conical cups. The International Journal of Advanced Manufacturing Technology, 110:1805–1818, 2020. doi: 10.1007/s00170-020-05985-5.
[23] Z.P. Xing, S.B. Kang, and H.W. Kim. Softening behavior of 8011 alloy produced by accumulative roll bonding process. Scripta Materialia, 45(5):597–604, 2001. doi: 10.1016/S1359-6462(01)01069- 7.
[24] A. Hasanbaşoğlu and R. Kaçar. Resistance spot weldability of dissimilar materials (AISI 316L–DIN EN 10130-99 steels). Materials & Design, 28(6):1794–1800, 2007. doi: 10.1016/j.matdes.2006.05.013.
[25] B. Meng and M.W. Fu. Size effect on deformation behavior and ductile fracture in microforming of pure copper sheets considering free surface roughening. Materials & Design, 83:400–412, 2015. doi: 10.1016/j.matdes.2015.06.067.
[26] A.G. Olabi and A. Alaswad. Experimental and finite element investigation of formability and failures in bi-layered tube hydro-forming. Advances in Engineering Software, 42(10):815–820, 2011. doi: 10.1016/j.advengsoft.2011.05.022.
[27] M. Rahimi, P. Fojan, L. Gurevich, and A. Afshari. Aluminium Alloy 8011: Surface characteristics. Applied Mechanics and Materials, 719–720:29–37, 2015. doi: 10.4028/www.scientific.net/AMM.719-720.29.
[28] G. Pantazopoulos. Metallurgical observations on fatigue failure of a bent copper tube. Journal of Failure Analysis and Prevention, 9:270–274,2009. doi: 10.1007/s11668-009-9225-2.
[29] K.A. Annan, R.C. Nkhoma, and S. Ngomane. Resistance spot welding of a thin 0.7 mm EN10130: DC04 material onto a thicker 2.4 mm 817M40 engineering steel. Journal of Southern African Institute of Mining and Metallurgy, 121(10):1–7, 2021. doi: 10.17159/2411-9717/1597/2021.
[30] T. Maki and J. Cheng. Sheet hydroforming and other new potential forming technologies. In: IOP Conference Series: Materials Science and Engineering, 418:012117, 2018. doi: 10.1088/1757- 899X/418/1/012117.
[31] A.K. Sharma and D.K. Rout. Finite element analysis of sheet hydro-mechanical forming of circular cup. Journal of Materials Processing Technology, 209(3):1445–1453, 2009. doi: 10.1016/j.jmatprotec.2008.03.070.
Go to article

Authors and Affiliations

Binayak Nahak
1
ORCID: ORCID
Anil Kumar
2
ORCID: ORCID
Anshul Yadav
2
Jerzy Winczek
3
ORCID: ORCID
  1. Motilal Nehru National Institute of Technology Allahabad, Prayagraj – 211004, India
  2. Kamla Nehru Institute of Technology, Sultanpur – 228118, India
  3. Częstochowa University of Technology, Częstochowa, Poland

Numerical analysis of structure, stability and entropy generation in biogas coflow diffusion flames

R. Nivethana Kumar S. Muthu Kumaran Vasudevan Raghavan
Archive of Mechanical Engineering | 2022 | vol. 69 | No 1 | 99-128 | DOI: 10.24425/ame.2021.139648
Keywords biogas flame stability entropy generation coflow air hydrogen injection preheated reactants
Download PDF Download RIS Download Bibtex

Abstract

Biogas is a gaseous biofuel predominantly composed of methane and carbon-dioxide. Stability of biogas flames strongly depend upon the amount of carbon-dioxide present in biogas, which varies with the source of biomass and reactor. In this paper, a comprehensive study on the stability and flame characteristics of coflow biogas diffusion flames is reported. Numerical simulations are carried out using reactive flow module in OpenFOAM, incorporated with variable thermophysical properties, Fick’s and Soret diffusion, and short chemical kinetics mechanism. Effects of carbon-dioxide content in the biogas, temperatures of the fuel or coflowing air streams (preheated reactant) and hydrogen addition to fuel or air streams are analyzed. Entropy generation in these flames is also predicted. Results show that the flame temperature increases with the degree of preheat of reactants and the flames show better stability with the preheated air stream. Preheating the air contributes to increased flame stability and also to a significant decrease in entropy generation. Hydrogen addition, contributing to the same power rating, is seen to be relatively more effective in increasing the flame stability when added to the fuel stream. Results in terms of flow, temperature, species and entropy fields, are used to describe the stability and flame characteristics.
Go to article

Bibliography

[1] Z. Recebli, S. Selimli, M. Ozkaymak, and O. Gonc. Biogas production from animal manure. Journal of Engineering Science and Technology, 10(6):722–729, 2015.
[2] S. Rasi, A.Veijanen, and J. Rintala. Trace compounds of biogas from different biogas production plants. Energy, 32(8):1375–1380, 2007. doi: 10.1016/j.energy.2006.10.018.
[3] O. Jonsson, E. Polman, J.K. Jensen, R. Ekund, H. Schyl, and S. Ivarsson. Sustainable gas enters the European gas distribution system. In World Gas Conference, Tokyo, Japan, 2003.
[4] I.U. Khan, M.H.D. Othman, H. Hashim, T. Matsuura, A.F. Ismail, M. Rezaei-DashtArzhandi, and I.W. Azelee. Biogas as a renewable energy fuel – a review of biogas upgrading, utilization and storage. Energy Conversion and Management, 150:277–294, 2017. doi: 10.1016/j.enconman.2017.08.035.
[5] H.O.B. Nonaka and F.M. Pereira. Experimental and numerical study of CO 2 content effects on the laminar burning velocity of biogas. Fuel, 182:382–390, 2016. doi: j.fuel.2016.05.098.
[6] M.S. Abdallah, M.S. Mansour, and N.K. Allam. Mapping the stability of free-jet biogas flames under partially premixed combustion. Energy, 220:119749, 2021. doi: 10.1016/j.energy.2020.119749.
[7] L. Zhang, X. Ren, R. Sun, andY.A. Levendis. A numerical and experimental study on the effects of CO 2 on laminar diffusion methane/air flames. Journal of Energy Resources Technology, 142(8):82307, 2020. doi: 10.1115/1.4046228.
[8] T. Leung and I. Wierzba. The effect of hydrogen addition on biogas non-premixed jet flame stability in a co-flowing air stream. International Journal of Hydrogen Energy, 33(14):3856–3862, 2008. doi: 10.1016/j.ijhydene.2008.04.030.
[9] S. Verma, K. Kumar, L.M. Das, and S.C. Kaushik. Effects of hydrogen enrichment strategy on performance and emission features of biodiesel-biogas dual fuel engine using simulation and experimental analyses. Journal of Energy Resources Technology, 143(9):092301, 2021. doi: 10.1115/1.4049179.
[10] H.S. Zhen, C.W. Leung, and C.S. Cheung. Effects of hydrogen addition on the characteristics of a biogas diffusion flame. International Journal of Hydrogen Energy, 38(16):6874–6881, 2013. doi: 10.1016/j.ijhydene.2013.02.046.
[11] H.S. Zhen, C.W. Leung, and C.S. Cheung. A comparison of the heat transfer behaviors of biogas–H 2 diffusion and premixed flames. International Journal of Hydrogen Energy, 39(2):1137–1144, 2014. doi: 10.1016/j.ijhydene.2013.10.100.
[12] H.S. Zhen, Z.L. Wei, Z.B. Chen, M.W. Xiao, L.R. Fu, and Z.H. Huang. An experimental comparative study of the stabilization mechanism of biogas-hydrogen diffusion flame. International Journal of Hydrogen Energy, 44(3):1988–1997, 2019. doi: 10.1016/j.ijhydene.2018.11.171.
[13] M.R.J. Charest, Ö.L. Gülder, and C.P.T. Groth. Numerical and experimental study of soot formation in laminar diffusion flames burning simulated biogas fuels at elevated pressures. Combustion and Flame, 161(10):2678–2691, 2014. doi: 10.1016/j.combustflame.2014.04.012.
[14] Z.L.Wei, C.W. Leung, C.S. Cheung, and Z.H. Huang. Effects of H 2 andCO 2 addition on the heat transfer characteristics of laminar premixed biogas-hydrogen Bunsen flame. International Journal of Heat Mass Transfer, 98:359–366, 2016. doi: 10.1016/j.ijheatmasstransfer.2016.02.064.
[15] A. Mameri and F. Tabet. Numerical investigation of counter-flow diffusion flame of biogas-hydrogen blends: Effects of biogas composition, hydrogen enrichment and scalar dissipation rate on flame structure and emissions. International Journal of Hydrogen Energy, 41 (3):2011–2022, 2016. doi: 10.1016/j.ijhydene.2015.11.035.
[16] X. Li, S. Xie, J. Zhang, T. Li, and X. Wang. Combustion characteristics of non-premixed CH 4/CO 2 jet flames in coflow air at normal and elevated temperatures. Energy, 214:118981, 2021. doi: 10.1016/j.energy.2020.118981.
[17] A.V. Prabhu, A. Avinash, K. Brindhadevi, and A. Pugazhendhi. Performance and emission evaluation of dual fuel CI engine using preheated biogas-air mixture. Science of The Total Environment, 754:142389, 2021. doi: 10.1016/j.scitotenv.2020.142389.
[18] M.H. Moghadasi, R. Riazi, S. Tabejamaat, and A. Mardani. Effects of preheating and CO 2 dilution on Oxy-MILD combustion of natural gas. Journal of Energy Resources Technology, 141(12):12200, 2019. doi: 10.1115/1.4043823.
[19] A. Harish, H.R. Rakesh Ranga, A. Babu, and V. Raghavan. Experimental study of the flame characteristics and stability regimes of biogas – air cross flow non-premixed flames. Fuel, 223:334–343, 2018. doi: 10.1016/j.fuel.2018.03.055.
[20] G. Tsatsaronis, T. Morosuk, D. Koch, and M. Sorgenfrei. Understanding the thermodynamic inefficiencies in combustion processes. Energy, 62:3–11, 2013. doi: 10.1016/j.energy.2013.04.075.
[21] A. Datta. Entropy generation in a confined laminar diffusion flame. Combustion Science and Technology, 159(1):39–56, 2000. doi: 10.1080/00102200008935776.
[22] K.M. Saqr and M.A. Wahid. Entropy generation in turbulent swirl-stabilized flame: Effect of hydrogen enrichment. Applied Mechanics and Materials, 388:280–284, 2013. doi: 10.4028/www.scientific.net/AMM.388.280.
[23] H.R. Arjmandi and E. Amani. A numerical investigation of the entropy generation in and thermodynamic optimization of a combustion chamber. Energy, 81:706–718, 2015. doi: 10.1016/j.energy.2014.12.077.
[24] A.M. Briones, A. Mukhopadhyay, and S.K. Aggarwal. Analysis of entropy generation in hydrogen-enriched methane–air propagating triple flames. International Journal of Hydrogen Energy, 34(2):1074–1083, 2009. doi: 10.1016/j.ijhydene.2008.09.103.
[25] K. Nishida, T. Takagi, and S. Kinoshita. Analysis of entropy generation and exergy loss during combustion. Proceedings of the Combustion Institute, 29(1):869–874, 2002. doi: 10.1016/S1540-7489 (02)80111-0.
[26] W. Wang, Z. Zuo, J. Liu, and W. Yang. Entropy generation analysis of fuel premixed CH 4/H 2/air flames using multistep kinetics. International Journal of Hydrogen Energy, 41(45):20744–20752, 2016. doi: 10.1016/j.ijhydene.2016.08.103.
[27] R.S. Barlow, N.S.A. Smith, J.Y. Chen, and R.W. Bilger. Nitric oxide formation in dilute hydrogen jet flames: isolation of the effects of radiation and turbulence–chemistry sub models. Combustion and Flame, 117(1-2):4–31, 1999. doi: 10.1016/S0010-2180(98)00071-6.
[28] J.O. Hirschfelder, C.F. Curtiss, and R.B. Bird. Molecular Theory of Gases and Liquids. Wiley, New York, 1954.
[29] K.K.Y. Kuo. Principles of Combustion. Wiley, New York, 1986.
[30] C.T. Bowman, R.K. Hanson, D.F. Davidson, W.C. Gardiner, Jr., V. Lissianski, G.P. Smith, D.M. Golden, M. Frenklach, and M. Goldenberg. GRI_Mech 2.11. Available: http://combustion.berkeley.edu/gri-mech/new21/version21/text21.html.
[31] D.N. Pope, V. Raghavan, and G. Gogos. Gas-phase entropy generation during transient methanol droplet combustion. International Journal of Thermal Sciences, 49(7):1288–1302, 2010. doi: 10.1016/j.ijthermalsci.2010.02.012.
[32] A.V. Mokhov, B.A.V Bennett, H.B. Levinsky, and M.D. Smooke. Experimental and computational study of C 2H 2 and CO in a laminar axisymmetric methane-air diffusion flame. Proceedings of the Combustion Institute, 31(1):997–1004, 2007. doi: 10.1016/j.proci.2006.08.094.
[33] J. Lim, J. Gore, and R. Viskanta. A study of the effects of air preheat on the structure of methane/air counterflow diffusion flames. Combustion and Flame, 121(1-2):262–274, 2000. doi: 10.1016/S0010-2180(99)00137-6.
[34] H.S. Zhen, J. Miao, C.W. Leung, C.S. Cheung, and Z.H. Huang. A study on the effects of air preheat on the combustion and heat transfer characteristics of Bunsen flames. Fuel, 184:50–58, 2016. doi: 10.1016/j.fuel.2016.07.007.
[35] C.J. Sung, J.B. Liu, and C.K. Law. Structural response of counterflow diffusion flames to strain rate variations. Combustion and Flame, 102(4):481–492, 1995. doi: 10.1016/0010-2180(95)00041-4.
Go to article

Authors and Affiliations

R. Nivethana Kumar
1
S. Muthu Kumaran
1
Vasudevan Raghavan
1
  1. Department of Mechanical Engineering, Indian Institute of Technology Madras, Chennai – 600036, India

Couple stress fluid past a sphere embedded in a porous medium

Krishna Prasad Madasu Priya Sarkar
Archive of Mechanical Engineering | 2022 | vol. 69 | No 1 | 5-19 | DOI: 10.24425/ame.2021.139314
Keywords sphere couple stress fluid saturated porous medium Brinkman’s equation drag force
Download PDF Download RIS Download Bibtex

Abstract

This paper concerns the analytical investigation of the axisymmetric and steady flow of incompressible couple stress fluid through a rigid sphere embedded in a porous medium. In the porous region, the flow field is governed by Brinkman's equation. Here we consider uniform flow at a distance from the sphere. The boundary conditions applied on the surface of the sphere are the slip condition and zero couple stress. Analytical solution of the problem in the terms of stream function is presented by modified Bessel functions. The drag experienced by an incompressible couple stress fluid on the sphere within the porous medium is calculated. The effects of the slip parameter, the couple stress parameter, and permeability on the drag are represented graphically. Special cases of viscous flow through a sphere are obtained and the results are compared with earlier published results.
Go to article

Bibliography

[1] J. Bear. Dynamics of fluids in porous media. Courier Corporation, 2013.
[2] H.C. Brinkman. A calculation of the viscous force exerted by a flowing fluid on a dense swarm of particles. Flow, Turbulence and Combustion, 1(1):27–34, 1949. doi: 10.1007/bf02120313.
[3] R.H. Davis and H.A. Stone. Flow through beds of porous particles. Chemical Engineering Science, 48(23):3993–4005, 1993. doi: 10.1016/0009-2509(93)80378-4.
[4] B. Barman. Flow of a Newtonian fluid past an impervious sphere embedded in a porous medium. Indian Journal of Pure and Applied Mathematics, 27:1249–1256, 1996.
[5] I. Pop and D.B. Ingham. Flow past a sphere embedded in a porous medium based on the Brinkman model. International Communications in Heat and Mass Transfer, 23(6):865–874, 1996. doi: 10.1016/0735-1933(96)00069-3.
[6] D. Srinivasacharya and J.V. Ramana Murthy. Flow past an axisymmetric body embedded in a saturated porous medium. Comptes Rendus Mécanique, 330(6):417–423, 2002. doi: 10.1016/s1631-0721(02)01478-x.
[7] T. Grosan, A. Postelnicu, and I. Pop. Brinkman flowof a viscous fluid through a spherical porous medium embedded in another porous medium. Transport in Porous Media, 81(1):89–103, 2010. doi: 10.1007/s11242-009-9389-y.
[8] S. Deo and B.R. Gupta. Drag on a porous sphere embedded in another porous medium. Journal of Porous Media, 13(11):1009–1016, 2010. doi: 10.1615/JPorMedia.v13.i11.70.
[9] N.E. Leontev. Flow past a cylinder and a sphere in a porous medium within the framework of the Brinkman equation with the Navier boundary condition. Fluid Dynamics, 49(2):232–237, 2014. doi: 10.1134/S0015462814020112.
[10] S. El-Sapa. Effect of permeability of Brinkman flow on thermophoresis of a particle in a spherical cavity. European Journal of Mechanics-B/Fluids, 79:315–323, 2020. doi: 10.1016/j.euromechflu.2019.09.017.
[11] M.S. Faltas, H.H. Sherief, A.A. Allam, and B.A. Ahmed. Mobilities of a spherical particle straddling the interface of a semi-infinite Brinkman flow. Journal of Fluids Engineering, 143(7):071402, 2021. doi: 10.1115/1.4049931.
[12] M. Krishna Prasad and D. Srinivasacharya. Micropolar fluid flow through a cylinder and a sphere embedded in a porous medium. International Journal of Fluid Mechanics Research, 44(3):229–240, 2017. doi: 10.1615/InterJFluidMechRes.2017015283.
[13] B.R. Jaiswal. A non-Newtonian liquid sphere embedded in a polar fluid saturated porous medium: Stokes flow. Applied Mathematics and Computation, 316:488–503, 2018. doi: 10.1016/j.amc.2017.08.009.
[14] K. Ramalakshmi and P. Shukla. Drag on a fluid sphere embedded in a porous medium with solid core. International Journal of Fluid Mechanics Research, 46(3):219–228, 2019. doi: 10.1615/InterJFluidMechRes.2018025197.
[15] K.P. Madasu and T. Bucha. Influence of mhd on micropolar fluid flow past a sphere implanted in porous media. Indian Journal of Physics, 95(6):1175–1183, 2021. doi: 10.1007/s12648-020-01759-7.
[16] V.K. Stokes. Couple stresses in fluids. In Theories of Fluids with Microstructure, pages 34–80. Springer, 1966. doi: 10.1007/978-3-642-82351-0_4.
[17] V.K. Stokes. Theories of Fluids with Microstructure: An Introduction. Springer Science & Business Media, 2012. doi: 10.1007/978-3-642-82351-0.
[18] D. Pal, N. Rudraiah, and R. Devanathan. A couple stress model of blood flow in the microcirculation. Bulletin of Mathematical Biology, 50(4):329–344, 1988. doi: 10.1007/BF02459703.
[19] N.A. Khan, A. Mahmood, and A. Ara. Approximate solution of couple stress fluid with expanding or contracting porous channel. Engineering Computations, 30(3):399–408, 2013. doi: 10.1108/02644401311314358.
[20] D. Srinivasacharya and K. Kaladhar. Mixed convection flowof couple stress fluid in a non-Darcy porous medium with Soret and Dufour effects. Journal of Applied Science and Engineering, 15(4):415–422, 2012.
[21] M. Devakar, D. Sreenivasu, and B. Shankar. Analytical solutions of couple stress fluid flows with slip boundary conditions. Alexandria Engineering Journal, 53(3):723–730, 2014. doi: 10.1016/j.aej.2014.06.005.
[22] D. Srinivasacharya, N. Srinivasacharyulu, and O. Odelu. Flow of couple stress fluid between two parallel porous plates. International Journal of Applied Mathematics, 41(2).
[23] E.A. Ashmawy. Drag on a slip spherical particle moving in a couple stress fluid. Alexandria Engineering Journal, 55(2):1159–1164, 2016. doi: 10.1016/j.aej.2016.03.032.
[24] P. Aparna, P. Padmaja, N. Pothanna, and J.V. Ramana Murthy. Couple stress fluid flow due to slow steady oscillations of a permeable sphere. Nonlinear Engineering, 9(1):352–360, 2020. doi: 10.1515/nleng-2020-0021.
[25] S.O. Adesanya, S.O. Kareem, J.A. Falade, and S.A. Arekete. Entropy generation analysis for a reactive couple stress fluid flow through a channel saturated with porous material. Energy, 93:1239–1245, 2015. doi: 10.1016/j.energy.2015.09.115.
[26] A.R. Hassan. The entropy generation analysis of a reactive hydromagnetic couple stress fluid flow through a saturated porous channel. Applied Mathematics and Computation, 369:124843, 2020. doi: 10.1016/j.amc.2019.124843.
[27] S.I.Abdelsalam, J.X.Velasco-Hernández, and A.Z. Zaher. Electro-magnetically modulated selfpropulsion of swimming sperms via cervical canal. Biomechanics and Modeling in Mechanobiology, 20(3):861–878, 2021. doi: 10.1007/s10237-020-01407-3.
[28] M.M. Bhatti, S.Z. Alamri, R. Ellahi, and S.I. Abdelsalam. Intra-uterine particle–fluid motion through a compliant asymmetric tapered channel with heat transfer. Journal of Thermal Analysis and Calorimetry, 144(6):2259–2267, 2021. doi: 10.1007/s10973-020-10233-9.
[29] A.R. Hadjesfandiari and G.F. Dargush. Polar continuum mechanics. arXiv preprint arXiv:1009.3252, 2010.
[30] A.R. Hadjesfandiari and G.F. Dargush. Couple stress theory for solids. International Journal of Solids and Structures, 48(18):2496–2510, 2011. doi: 10.1016/j.ijsolstr.2011.05.002.
[31] A.R. Hadjesfandiari, G.F. Dargush, and A. Hajesfandiari. Consistent skew-symmetric couple stress theory for size-dependent creeping flow. Journal of Non-Newtonian Fluid Mechanics, 196:83–94, 2013. doi: 10.1016/j.jnnfm.2012.12.012.
[32] A.R. Hadjesfandiari, A. Hajesfandiari, and G.F. Dargush. Skew-symmetric couple-stress fluid mechanics. Acta Mechanica, 226(3):871–895, 2015. doi: 10.1007/s00707-014-1223-0.
[33] C.L.M.H. Navier. Mémoires de l’Académie Royale des Sciences de l’Institut de France. Royale des Sciences de l’Institut de France, 1823.
[34] I.M. Eldesoky, S.I. Abdelsalam, W.A. El-Askary, A.M. El-Refaey, and M.M. Ahmed. Joint effect of magnetic field and heat transfer on particulate fluid suspension in a catheterized wavy tube. BioNanoScience, 9(3):723–739, 2019. doi: >10.1007/s12668-019-00651-x.
[35] M.M. Bhatti and S.I. Abdelsalam. Thermodynamic entropy of a magnetized ree-eyring particle-fluid motion with irreversibility process: A mathematical paradigm. Journal of Applied Mathmatics nd Mechanics/Zeitschrift fur Angewandte Mathematik und Mechanik, 101(6):e202000186, 2021. doi: 10.1002/zamm.202000186.
[36] S. El-Sapa and N.S. Alsudais. Effect of magnetic field on the motion of two rigid spheres embedded in porous media with slip surfaces. The European Physical Journal E, 44(5):1–11, 2021. doi: 10.1140/epje/s10189-021-00073-2.
[37] K.P. Madasu, M. Kaur, and T. Bucha. Slow motion past a spheroid implanted in a Brinkman medium: Slip condition. International Journal of Applied and Computational Mathematics, 7(4):1–15, 2021. doi: 10.1007/s40819-021-01104-4.
[38] J. Happel and H. Brenner. Low Reynolds Number Hydrodynamics: with Special Applications to Particulate Media. Springer Science & Business Media, 2012.
[39] S. El-Sapa, E.I. Saad, and M.S. Faltas. Axisymmetric motion of two spherical particles in a brinkman medium with slip surfaces. European Journal of Mechanics-B/Fluids, 67:306–313, 2018. doi: 10.1016/j.euromechflu.2017.10.003.
[40] V.K. Stokes. Effects of couple stresses in fluids on the creeping flow past a sphere. The Physics of Fluids, 14(7):1580–1582, 1971. doi: 10.1063/1.1693645.
Go to article

Authors and Affiliations

Krishna Prasad Madasu
1
ORCID: ORCID
Priya Sarkar
1
ORCID: ORCID
  1. Department of Mathematics, National Institute of Technology, Raipur-492010, Chhattisgarh, India

Wear and surface characteristics on tool performance with CVD coating of Al2O3/TiCN inserts during machining of Inconel 718 alloys

Shailesh Rao Agari
Archive of Mechanical Engineering | 2022 | vol. 69 | No 1 | 59-75 | DOI: 10.24425/ame.2021.139647
Keywords chip morphology tool wear surface roughness super alloy - Inconel 717
Download PDF Download RIS Download Bibtex

Abstract

The Inconel 718 alloys, which are primarily temperature resistant, are widely used in aviation, aerospace and nuclear industries. The study on dry cutting processes for this alloy becomes difficult due to its high hardness and low thermal conductivity, wherein, most of the heat transfers due to friction are accumulated over the tool surface. Further, several challenges like increased cutting force, developing high temperature and rapid tool wear are observed during its machining process. To overcome these, the coated tool inserts are used for machining the superalloys. In the present work, the cemented carbide tool is coated with chemical vapor deposition multi-layering Al 2O 3/TiCN under the dry cutting environment. The machining processes are carried out with varying cutting speeds: 65, 81, 95, and 106 m/min, feed rate 0.1 mm/rev, and depth of cut 0.2 mm. The variation in the cutting speeds can attain high temperatures, which may activate built-up-edge development which leads to extensive tool wear. In this context, the detailed chip morphology and its detailed analysis are carried out initially to understand the machining performance. Simultaneously, the surface roughness of the machined surface is studied for a clear understanding of the machining process. The potential tool wear mechanism in terms of abrasion, adhesion, tool chip off, delaminating of coating, flank wear, and crater wear is extensively identified during the processes. From the results, it is observed that the machining process at 81 m/min corresponds to a better machining process in terms of lesser cutting force, lower cutting temperature, better surface finish, and reduced tool wear than the other machining processes.
Go to article

Bibliography

[1] R.M. Arunachalam, M.A. Mannan, and A.C. Spowage. Surface integrity when machining age hardened Inconel 718 with coated carbide cutting tools. International Journal of Machine Tools and Manufacture, 44(14):1481–1491, 2004. doi: 10.1016/j.ijmachtools.2004.05.005.
[2] L. Li, N. He, M.Wang, and Z.G.Wang. High-speed cutting of Inconel 718 with coated carbide and ceramic inserts. Journal of Materials Processing Technology, 129(1–3):127–130, 2002. doi: 10.1016/S0924-0136(02)00590-3.
[3] E.O. Ezugwu. Key improvements in the machining of difficult-to-cut aerospace superalloys. International Journal of Machine Tools and Manufacture, 45(12–13):1353–1367, 2005. doi: 10.1016/j.ijmachtools.2005.02.003.
[4] T. Kitagawa, A. Kubo, and K. Maekawa. Temperature and wear of cutting tools in high-speed machining of Inconel and Ti–6Al–6V–2Sn. Wear, 202(2):142–148, 1997. doi: 10.1016/S0043-1648(96)07255-9.
[5] S. Chinchanikar, S.S. Kore, and P. Hujare. A review on nanofluids in minimum quantity lubrication machining. Journal of Manufacturing Processes, 68(A):56–70, 2021. doi: 10.1016/j.jmapro.2021.05.028.
[6] A.C. Okafor and T.O. Nwoguh. Comparative evaluation of soybean oil–based MQL flow rates and emulsion flood cooling strategy in high-speed face milling of Inconel 718. The International Journal of Advanced Manufacturing Technology, 107(9–10):3779–3793, 2020. doi: 10.1007/s00170-020-05248-3.
[7] J. Kaminski and B. Alvelid. Temperature reduction in the cutting zone in water-jet assisted turning. Journal of Materials Processing Technology, 106(1–3):68–73, 2000. doi: 10.1016/S0924-0136(00)00640-3.
[8] A. Marques, M. Paipa Suarez, W. Falco Sales, and Á. Rocha Machado. Turning of Inconel 718 with whisker-reinforced ceramic tools applying vegetable-based cutting fluid mixed with solid lubricants by MQL. Journal of Materials Processing Technology, 266:530–543, 2019. doi: 10.1016/j.jmatprotec.2018.11.032.
[9] A. Suárez, L.N. López de Lacalle, R. Polvorosa, F. Veiga, and A. Wretland. Effects of highpressure cooling on the wear patterns on turning inserts used on alloy IN718. Materials and Manufacturing Processes, 32(6):678–686, 2017. doi: 10.1080/10426914.2016.1244838.
[10] R. Polvorosa, A. Suárez, L.N. López de Lacalle, I. Cerrillo, A. Wretland, and F. Veiga: Tool wear on nickel alloys with different coolant pressures: Comparison of Alloy 718 andWaspaloy. Journal of Manufacturing Processes, 26:44–56, 2017. doi: 10.1016/j.jmapro.2017.01.012.
[11] A.R.C. Sharman, J.I. Hughes, and K. Ridgway. Surface integrity and tool life when turning Inconel 718 using ultra-high pressure 786 and flood coolant systems. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 222(6):653–664, 2008. doi: 10.1243/09544054JEM936.
[12] W.H. Pereira and S. Delijaicov. Surface integrity of Inconel 718 turned under cryogenic conditions at high cutting speeds. The International Journal of Advanced Manufacturing Technology, 104:2163–2177, 2019. doi: 10.1007/s00170-019-03946-1.
[13] H. González, O. Pereira, L.N. López de Lacalle, A. Calleja, I. Ayesta, and J. Muñoa. Flankmilling of integral blade rotors made in Ti6Al4V using cryo CO2 and minimum quantity lubrication. ASME. Journal of Manufacturing Science and Engineering, 143(9):091011, 2021. doi: 10.1115/1.4050548.
[14] A. Devillez, F. Schneider, S. Dominiak, D. Dudzinski, and D. Larrouquere. Cutting forces and wear in dry machining of Inconel 718 with coated carbide tools. Wear, 262(7–8):931–942, 2007. doi: 10.1016/j.wear.2006.10.009.
[15] N.R. Dhar, M.W. Islam, S. Islam, and M.A.H. Mithu. The influence of minimum quantity of lubrication (MQL) on cutting temperature, chip and dimensional accuracy in turning AISI- 1040 steel. Journal of Materials Processing Technology, 171(1):93–99, 2006. doi: 10.1016/j.jmatprotec.2005.06.047.
[16] D. Dudzinski, A. Devillez, A. Moufki, D. Larrouquère,V. Zerrouki, and J. Vigneau. A review of developments towards dry and high speed machining of Inconel 718 alloy. International Journal of Machine Tools and Manufacture, 44(4):439–456, 2004. doi: 10.1016/S0890-6955(03)00159-7.
[17] I.A. Choudhury and M.A. El-Baradie. Machining nickel base super alloys: Inconel 718. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture. 212(3):195–206, 1998. doi: 10.1243/0954405981515617.
[18] S.K. Thandra and S.K. Choudhury. Effect of cutting parameters on cutting force, surface finish and tool wear in hot machining. International Journal of Machining and Machinability of Materials, 7(3-4):260–273, 2010. doi: 10.1504/IJMMM.2010.033070.
[19] L.N. Lopez de Lacalle, J.A. Sanchez, A. Lamikiz, and A. Celaya. Plasma assisted milling of heatresistant superalloys. ASME Journal of Manufacturing Science and Engineering, 126(2):274– 285, 2016. doi: 10.1115/1.1644548.
[20] M.C. Shaw. Metal Cutting Principles. Clarendon, Oxford, 1984.
[21] E.O. Ezugwu, J. Bonney, and Y. Yamane. An overview of the machinability of aeroengine alloys. Journal of Materials Processing Technology, 134(2):233–253, 2003. doi: 10.1016/S0924-0136(02)01042-7.
[22] A. Jawaid, S. Koksal, and S. Sharif. Wear behavior of PVD and CVD coated carbide tools when face milling Inconel 718. Tribology Transactions, 43(2):325–331, 2000. doi: 10.1080/10402000008982347.
[23] T. Sugihara, H. Tanaka, and T. Enomoto. Development of novel CBN cutting tool for high speed machining of Inconel 718 focusing on coolant behaviors. Procedia Manufacturing, 10:436–442, 2017. doi: 10.1016/j.promfg.2017.07.021.
[24] G.A. Ibrahim, C.H.C. Haron, J.A. Ghani, A.Y.M. Said, and M.Z.A. Yazid. Performance of PVD-coated carbide tools when turning Inconel 718 in dry machining. Advances in Mechanical Engineering, 3:790975, 2011. doi: 10.1155/2011/790975.
[25] Z.P. Hao, Y.H. Fan, J.Q. Lin, and Z.X Yu. Wear characteristics and wear control method of PVD-coated carbide tool in turning Inconel 718. The International Journal of Advanced Manufacturing Technology, 78(5–8):1329–1336, 2015. doi: 10.1007/s00170-014-6752-0.
[26] B. Zhang, M.J. Njora, and Y. Sato. High-speed turning of Inconel 718 by using TiAlN- and (Al, Ti) N-coated carbide tools. The International Journal of Advanced Manufacturing Technology, 96(5–8):2141–2147, 2018. doi: 10.1007/s00170-018-1765-8.
[27] F. Zemzemi, J. Rech, W.B. Salem, A. Dogui, and P. Kapsa. Identification of friction and heat partition model at the tool-chip-workpiece interfaces in dry cutting of an Inconel 718 alloy with CBN and coated carbide tools. Advances in Manufacturing Science and Technology, 38(1):5-22, 2014. doi: 10.2478/amst-2014-0001.
[28] W. Grzesik, J. Małecka, Z. Zalisz, K. Zak, and P. Niesłony. Investigation of friction and wear mechanisms of TiAlV coated carbide against Ti6Al4V Titanium alloy using pin-on-disc tribometer. Archive of Mechanical Engineering, 63(1):114-127, 2016. doi: 10.1515/meceng-2016-0006.
[29] V. Bushlya, F. Lenrick, A. Bjerke, H. Aboulfadl, M. Thuvander; J.-E. Ståhl, and R. M’Saoubi: Tool wear mechanisms of PcBN in machining Inconel 718: Analysis across multiple length scale. CIRP Annals, 70(1):73–78, 2021. doi: 10.1016/j.cirp.2021.04.008.
[30] A.R.F. Oliveira, L.R.R. da Silva, V. Baldin, M.P.C. Fonseca, R.B. Silva, and A.R. Machado: Effect of tool wear on the surface integrity of Inconel 718 in face milling with cemented carbide tools. Wear, 476:203752, 2021. doi: 10.1016/j.wear.2021.203752.
[31] A.K.M.N. Amin, S.A. Sulaiman, and M.D. Arif. Development of mathematical model for chip serration frequency in turning of stainless steel 304 using RSM. Advanced Materials and Process Technology, 217-219:2206–2209, 2012. doi: .
[32] J. Hua, and R. Shivpuri. Prediction of chip morphology and segmentation during the machining of titanium alloys. Journal of Materials Processing Technology, 150(1-2):124–133, 2004. doi: 10.1016/j.jmatprotec.2004.01.028.
[33] K. Lin, W. Wang, R. Jiang and Y. Xiong. Effect of tool nose radius and tool wear on residual stresses distribution while turning in situ TiB2/7050Al metal matrix composites. The International Journal of Advanced Manufacturing Technology, 100:143–151, 2019. doi: 10.1007/s00170-018-2742-y.
[34] K. Mahesh, J.T. Philip, S.N. Joshi and B. Kuriachen. Machinability of Inconel 718: A critical review on the impact of cutting temperatures. Materials and Manufacturing Processes, 36(7):753–791, 2021. doi: 10.1080/10426914.2020.1843671.
[35] V. Sivalingam Y. Zhao, R. Thulasiram, J. Sun, G. Kai, and T. Nagamalai. Machining behaviour, surface integrity and tool wear analysis in environment friendly turning of Inconel 718 alloy. Measurement,174:109028, 2021. doi: 10.1016/j.measurement.2021.109028.
[36] Z. Peng, X. Zhang, and D. Zhang. Performance evaluation of high-speed ultrasonic vibration cutting for improving machinability of Inconel 718 with coated carbide tools. Tribology International, 155:106766, 2021. doi: 10.1016/j.triboint.2020.106766.
[37] D.G. Flom, R. Komanduri, and M. Lee. High-speed machining of metals. Annual Review of Material Science, 14:231–278, 1984. doi: 10.1146/annurev.ms.14.080184.001311.
[38] N.L. Bhirud and R.R. Gawande. Optimization of process parameters during end milling and prediction of work piece temperature rise. Archive of Mechanical Engineering, 64(3):327–346, 2017. doi: 10.1515/meceng-2017-0020.
[39] R.S. Pawade, S.S. Joshi, P.K. Brahmankar, and M. Rahman. An investigation of cutting forces and surface damage in high-speed turning of Inconel 718. J ournal of Materials Processing Technology, 192-193:139–146, 2007. doi: 10.1016/j.jmatprotec.2007.04.049.
[40] A. Shokrani, V. Dhokia, and S.T. Newman. Environmentally conscious machining of difficultto- machine materials with regard to cutting fluids. International Journal of Machine Tools and Manufacture, 57:83–101, 2012. doi: 10.1016/j.ijmachtools.2012.02.002.
[41] Y.S. Liao, H.M. Lin, and J.H. Wang. Behaviors of end milling Inconel 718 superalloy by cemented carbide tools. Journal of Materials Processing Technology, 201(1–3):460–465, 2008. doi: 10.1016/j.jmatprotec.2007.11.176.
[42] R. Komanduri and T.A. Schroeder. On shear instability in machining a nickel-iron base superalloy. Journal of Engineering for Industry, 108(2):93–100. 1986. doi: 10.1115/1.3187056.
[43] R. Rakesh and S. Datta. Machining of Inconel 718 using coated wc tool: effects of cutting speed on chip morphology and mechanisms of tool wear. Arabian Journal for Science and Engineering, 45:797–816, 2020. doi: 10.1007/s13369-019-04171-4.
[44] S. Belhadi, T. Mabrouki, J.F. Rigal, and L. Boulanouar. Experimental and numerical study of chip formation during straight turning of hardened AISI 4340 steel. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 219(7):515– 524, 2005. doi: 10.1243/095440505X32445.
[45] A. Thakur and S. Gangopadhyay. Evaluation of micro-features of chips of Inconel 825 during dry turning with uncoated and chemical vapour deposition multilayer coated tools. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 232(6):979–994, 2018. doi: 10.1177/0954405416661584.
[46] M. Rahman,W.K.H. Seah, and T.T. Teo. The machinability of Inconel 718. Journal of Materials Processing Technology, 63(1–3):199–204, 1997. doi: 10.1016/S0924-0136(96)02624-6.
[47] S.P. Sahoo and S. Datta. Dry machining performance of AA7075-T6 alloy using uncoated carbide and MT-CVD TiCN-Al2O3 coated carbide Inserts. Arabian Journal of Science and Engineering,45:9777–9791, 2020. doi: 10.1007/s13369-020-04947-z.
[48] H.Z. Li, H. Zeng, and X.Q. Chen. An experimental study of tool wear and cutting force variation in the end milling of Inconel 718 with coated carbide inserts. Journal of Materials Processing Technology, 180(1–3):296–304, 2006. doi: 10.1016/j.jmatprotec.2006.07.009.
Go to article

Authors and Affiliations

Shailesh Rao Agari
1
  1. Department of Industrial and Production Engineering, The National Institute of Engineering, Mysuru, Karnataka, India

Optimization of the trolley mechanism acceleration during tower crane steady slewing

Viatcheslav Loveikin Yuriy Romasevych Andriy Loveikin Mykola Korobko
Archive of Mechanical Engineering | 2022 | vol. 69 | No 3 | 411-429 | DOI: 10.24425/ame.2022.140424
Keywords trolley optimization movement criteria crane
Download PDF Download RIS Download Bibtex

Abstract

The article describes optimization of the process of acceleration of the tower crane trolley movement mechanism during the steady mode of the slewing mechanism. A mathematical model of the boom system of the tower crane was used for the optimization of the trolley movement. The model was reduced to a sixth-order linear differential equation with constant coefficients, which represents the relationships between the drive torque and the coordinate of the load and its time derivatives. Non-dimensional complex criterion (objective function), which takes into account the drive torque and its rate of change in time during the transient process, was developed to optimize the mode of the trolley movement mechanism. Based on that, a variational problem was formulated and solved in an analytical form in which root-mean-square (RMS) values of the quantiles were applied. A complex optimal mode of acceleration of the trolley movement mechanism was obtained and compared with the modes optimized based on different criteria. Advantages and disadvantages of the solutions were discussed based on the analysis of the obtained optimal modes of motion. The analysis revealed low- and high-frequency elements oscillations of the trolley movement mechanism during the transient processes. The conditions for their elimination were formulated.
Go to article

Bibliography

[1] Y. Qian and Y. Fang. Switching logic-based nonlinear feedback control of offshore ship-mounted tower cranes: a disturbance observer-based approach. IEEE Transactions on Automation Science and Engineering, 16(3):1125–1136, 2018. doi: 10.1109/TASE.2018.2872621.
[2] M. Zhang, Y. Zhang, B. Ji, C. Ma, and X. Cheng. Modeling and energy-based sway reduction control for tower crane systems with double-pendulum and spherical-pendulum effects. Measurement and Control, 53(1-2):141–150, 2020. doi: 10.1177/0020294019877492.
[3] M. Zhang, Y. Zhang, H. Ouyang, C. Ma, and X. Cheng. Adaptive integral sliding mode control with payload sway reduction for 4-DOF tower crane systems. Nonlinear Dynamics, 99(7):2727–2741, 2020. doi: 10.1007/s11071-020-05471-3.
[4] T. Yang, N. Sun, H. Chen, and Y. Fang. Observer-based nonlinear control for tower cranes suffering from uncertain friction and actuator constraints with experimental verification. IEEE Transactions on Industrial Electronics, 68(7):6192–6204, 2021. doi: 10.1109/TIE.2020.2992972.
[5] J. Peng, J. Huang, and W. Singhose. Payload twisting dynamics and oscillation suppression of tower cranes during slewing motions. Nonlinear Dynamics, 98:1041–1048, 2019. doi: 10.1007/s11071-019-05247-4.
[6] S. Fasih, Z. Mohamed, A. Husain, L. Ramli, A. Abdullahi, and W. Anjum. Payload swing control of a tower crane using a neural network-based input shaper. Measurement and Control, 53(7-8):1171– 1182, 2020. doi: 10.1177/0020294020920895.
[7] D. Kruk and M. Sulowicz. AHRS based anti-sway tower crane controller. 2019 20th International Conference on Research and Education in Mechatronics (REM), 2019. doi: 10.1109/rem.2019.8744117.
[8] R.E. Samin and Z. Mohamed. Comparative assessment of anti-sway control strategy for tower crane system. AIP Conference Proceedings, 1883:020035, 2017. doi: 10.1063/1.5002053.
[9] S.-J. Kimmerle, M. Gerdts, and R. Herzog. Optimal control of an elastic crane-trolley-load system – a case study for optimal control of coupled ODE-PDE systems – (extended version with two appendices). Mathematical and Computer Modelling of Dynamical Systems, 24(2):182–206, 2018. doi: 10.1080/13873954.2017.1405046.
[10] V. Loveikin, Y. Romasevych, I. Kadykalo, and A. Liashko. Optimization of the swinging mode of the boom crane upon a complex integral criterion. Journal of Theoretical and Applied Mechanics, 49(3):285–296, 2019. doi: 10.7546/JTAM.49.19.03.07.
[11] Z. Liu, T. Yang, N. Sun, and Y. Fang. An antiswing trajectory planning method with state constraints for 4-DOF tower cranes: design and experiments. IEEE Access, 7:62142–62151, 2019. doi: 10.1109/ACCESS.2019.2915999.
[12] M. Böck and A. Kugi. Real-time nonlinear model predictive path-following control of a laboratory tower crane. IEEE Transactions on Control System Technology, 22(4):1461–1473, 2014. doi: 10.1109/TCST.2013.2280464.
[13] Š. Ileš, J. Matuško, and F. Kolonić. Sequential distributed predictive control of a 3D tower crane. Control Engineering Practice. 79:22–35, 2018. doi: 10.1016/j.conengprac.2018.07.001.
[14] K.W. Cassel. Variational Methods with Applications in Science and Engineering. Cambridge University Press, 2013. doi: 10.1017/CBO9781139136860.
Go to article

Authors and Affiliations

Viatcheslav Loveikin
1
Yuriy Romasevych
1
ORCID: ORCID
Andriy Loveikin
2
Mykola Korobko
1
ORCID: ORCID
  1. National University of Life and Environmental Sciences of Ukraine, Kyiv, Ukraine
  2. Taras Shevchenko National University of Kyiv, Ukraine

Two-dimensional analogies to the deformation characteristics of a falling droplet and its collision

Abid Hasan Rafi Mohammad Rejaul Haque Dewan Hasan Ahmed
Archive of Mechanical Engineering | 2022 | vol. 69 | No 1 | 21-43 | DOI: 10.24425/ame.2021.139649
Keywords droplet freefall spreading drag force
Download PDF Download RIS Download Bibtex

Abstract

The present study investigates the 2D numerical analogies to the changes of the droplet shapes during the freefall for a wide range of droplet sizes through the stagnation air. The freefall velocity, shape change due to frictional force during free-fall is studied for different considered cases. With the elapse of time, a droplet with a larger initial diameter is changing its original shape more compared to droplets with a smaller diameter. In addition, the spreading of the droplet during the freefall seems more rapid for the larger-diameter droplet. When a droplet with an initial diameter of 15 mm starts to fall with gravitational force, the diameter ratio is decreasing for droplets with higher density and surface tension while droplets having lower density and surface tension show a diameter ratio greater than one. The spreading and splashing of the droplet on a solid surface and liquid storage at the time of impact are much influenced by the freefall memories of the droplet during the freefall from a certain height. These freefall memories are influenced by the fluid properties, drag force, and the freefall height. However, these freefall memories eventually regulate the deformation of the droplet during the freefall.
Go to article

Bibliography

[1] X. Cao, Y. Ye, Q. Tang, E. Chen, Z. Jiang, J. Pan, and T. Guo. Numerical analysis of droplets from multinozzle inkjet printing. The Journal of Physical Chemistry Letters, 11(19):8442–8450, 2020. doi: 10.1021/acs.jpclett.0c02250.
[2] H. Wijshoff. Drop dynamics in the inkjet printing process. Current Opinion in Colloid & Interface Science, 36:20–27, 2018. doi: 10.1016/j.cocis.2017.11.004.
[3] W. Zhou, D. Loney, A.G. Fedorov, F.L. Degertekin, and D.W. Rosen. Shape evolution of droplet impingement dynamics in ink-jet manufacturing. Proceedings for the 2011 International Solid Freeform Fabrication Symposium, pages 309–325, Austin, USA, 2011. doi: 10.26153/tsw/15297.
[4] L. Mouzai and M. Bouhadef. Water drop erosivity: Effects on soil splash. Journal of Hydraulic Research, 41(1):61–68, 2003. doi: 10.1080/00221680309499929.
[5] M. Hajigholizadeh, A.M. Melesse, and H.R. Fuentes. Raindrop-induced erosion and sediment transport modelling in shallow waters: A review. Journal of Soil and Water Science, 1(1):15–25, 2018. doi: 10.36959/624/427.
[6] P.C. Ekern. Raindrop impact as the force initiating soil erosion. Soil Science Society of America Journal, 15(C):7–10, 1951. doi: 10.2136/sssaj1951.036159950015000C0002x.
[7] R. Andrade, O. Skurtys, and F. Osorio. Drop impact behavior on food using spray coating: Fundamentals and applications. Food Research International, 54(1):397–405, 2013. doi: 10.1016/j.foodres.2013.07.042.
[8] M. Toivakka. Numerical investigation of droplet impact spreading in spray coating of paper. Proceedings of the 2003 Spring Advanced Coating Fundamentals Symposium, Atlanta, USA, 2003.
[9] A. Prasad and H. Henein. Droplet cooling in atomization sprays. Journal of Materials Science, 43(17):5930–5941, 2008. doi: 10.1007/s10853-008-2860-2.
[10] W. Jia and H.-H. Qiu. Experimental investigation of droplet dynamics and heat transfer in spray cooling. Experimental Thermal and Fluid Science, 27(7):829–838, 2003. doi: 10.1016/S0894-1777(03)00015-3.
[11] G. Duursma, K. Sefiane, and A. Kennedy. Experimental studies of nanofluid droplets in spray cooling. Heat Transfer Engineering, 30(13):1108–1120, 2009. doi: 10.1080/01457630902922467.
[12] W.-C. Qin, B.-J. Qiu, X.-Y. Xue, C. Chen, Z.-F. Xu, and Q.-Q. Zhou. Droplet deposition and control effect of insecticides sprayed with an unmanned aerial vehicle against plant hoppers. Crop Protection, 85:79–88, 2016. doi: 10.1016/j.cropro.2016.03.018.
[13] S. Chen, Y. Lan, Z. Zhou, F. Ouyang, G. Wang, X. Huang, X. Deng, and S. Cheng. Effect of droplet size parameters on droplet deposition and drift of aerial spraying by using plant protection UAV. Agronomy, 10(2):195, 2020. doi: 10.3390/agronomy10020195.
[14] D.T. Sheppard. Spray Characteristics of Fire Sprinklers. Ph.D. Thesis, Northwestern University, Evanston, USA, June 2002.
[15] H. Liu, C.Wang, I.M. De Cachinho Cordeiro, A.C.Y. Yuen, Q. Chen, Q.N. Chan, S. Kook, and G.H. Yeoh. Critical assessment on operating water droplet sizes for fire sprinkler and water mist systems. Journal of Building Engineering, 28:100999, 2020. doi: 10.1016/j.jobe.2019.100999.
[16] D.C. Blanchard. The behavior of water drops at terminal velocity in air. Eos, Transactions American Geophysical Union, 31(6):836–842, 1950. doi: 10.1029/TR031i006p00836.
[17] H.R. Pruppacher and K.V. Beard. A wind tunnel investigation of the internal circulation and shape of water drops falling at terminal velocity in air. Quarterly Journal of the Royal Meteorological Society, 96(408):247–256, 1970. doi: 10.1002/qj.49709640807.
[18] H.R. Pruppacher and R.L. Pitter. A semi-empirical determination of the shape of cloud and rain drops. Journal of the Atmospheric Sciences, 28(1):86–94, 1971. doi: 10.1175/1520-0469(1971)0280086:ASEDOT>2.0.CO;2.
[19] K.V. Beard and C. Chuang. A new model for the equilibrium shape of raindrops. Journal of the Atmospheric Sciences, 44(11):1509–1524, Jun. 1987. doi: 10.1175/1520-0469(1987)0441509:ANMFTE>2.0.CO;2.
[20] É.Reyssat, F. Chevy, A.L. Biance, L. Petitjean, and D. Quéré. Shape and instability of free-falling liquid globules. Europhysics Letters, 80(3):34005, 2007. doi: 10.1209/0295-5075/80/34005.
[21] R. Clift, J.R. Grace, and M.E. Weber. Bubbles, Drops and Particles. Academic Press, 1978.
[22] S.-C. Yao and V.E. Schrock. Heat and mass transfer from freely falling drops. Journal of Heat Transfer, 98(1):120–126, 1976. doi: 10.1115/1.3450453.
[23] T.J. Horton, T.R. Fritsch, and R.C. Kintner. Experimental determination of circulation velocities inside drops. The Canadian Journal of Chemical Engineering, 43(3):143–146, 1965. doi: 10.1002/cjce.5450430309.
[24] R.H. Magarvey and B.W. Taylor. Free fall breakup of large drops. Journal of Applied Physics, 27(10):1129–1135, 1956. doi: 10.1063/1.1722216.
[25] M.N. Chowdhury, F.Y. Testik, M.C. Hornack, and A.A. Khan. Free fall of water drops in laboratory rainfall simulations. Atmospheric Research, 168:158–168, 2016. doi: 10.1016/j.atmosres.2015.08.024.
[26] M. Abdelouahab and R. Gatignol. Study of falling water drop in stagnant air. European Journal of Mechanics - B/Fluids, 60:82–89, 2016. doi: 10.1016/j.euromechflu.2016.07.007.
[27] J.H. van Boxel. Numerical model for the fall speed of raindrops in a rainfall simulator. I.C.E Special Report, 1998/1, 77–85,
[28] A.K. Kamra and D.V Ahire. Wind-tunnel studies of the shape of charged and uncharged water drops in the absence or presence of an electric field. Atmospheric Research, 23(2):117–134, 1989. doi: 10.1016/0169-8095(89)90003-3.
[29] M. Thurai and V.N. Bringi. Drop axis ratios from a 2D video disdrometer. Journal of Atmospheric and Oceanic Technology, 22(7):966–978, 2005. doi: 10.1175/JTECH1767.1.
[30] C. Josserand and S.T. Thoroddsen. Drop impact on a solid surface. Annual Review of Fluid Mechanics, 48:365–391, 2016. doi: 10.1146/annurev-fluid-122414-034401.
[31] J. Eggers, M.A. Fontelos, C. Josserand, and S. Zaleski. Drop dynamics after impact on a solid wall: Theory and simulations. Physics of Fluids, 22(6):062101, 2010. doi: 10.1063/1.3432498.
[32] S. Chandra and C.T. Avedisian. On the collision of a droplet with a solid surface. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, 432(1884):13–41, 1991. doi: 10.1098/rspa.1991.0002.
[33] O.G. Engel. Waterdrop collisions with solid surfaces. Journal of Research of the National Bureau of Standards, 54(5):281–298, 1955. doi: 10.6028/jres.054.033.
[34] I.V. Roisman, R. Rioboo, and C. Tropea. Normal impact of a liquid drop on a dry surface: model for spreading and receding. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, 458(2022):1411–1430, 2002. doi: 10.1098/rspa.2001.0923.
[35] Y. Renardy, S. Popinet, L. Duchemin, M. Renardy, S. Zaleski, C. Josserand, M.A. Drumright-Carke, D. Richard, C. Clanet, and D. Quéré. Pyramidal and toroidal water drops after impact on a solid surface. Journal of Fluid Mechanics, 484:69–83, 2003. doi: 10.1017/S0022112003004142.
[36] D. Bartolo, F. Bouamrirene, É. Verneuil, A. Buguin, P. Silberzan, and S. Moulinet. Bouncing or sticky droplets: Impalement transitions on superhydrophobic micropatterned surfaces. Europhysics Letters, 74(2):299–305, 2006. doi: 10.1209/epl/i2005-10522-3.
[37] D. Bartolo, C. Josserand, and D. Bonn. Singular jets and bubbles in drop impact. Physical Review Letters, 96:124501, 2006. doi: 10.1103/PhysRevLett.96.124501.
[38] C. Clanet, C. Béguin, D. Richard, and D. Quéré. Maximal deformation of an impacting drop. Journal of Fluid Mechanics, 517:199–208, 2004. doi: 10.1017/S0022112004000904.
[39] L.H.J. Wachters, L. Smulders, J.R. Vermeulen, and H.C. Kleiweg. The heat transfer from a hot wall to impinging mist droplets in the spheroidal state. Chemical Engineering Science, 21(12):1047–1056, 1966. doi: 10.1016/0009-2509(66)85042-X.
[40] C.O. Pedersen. An experimental study of the dynamic behavior and heat transfer characteristics of water droplets impinging upon a heated surface. International Journal of Heat and Mass Transfer, 13(2):369–381, 1970. doi: 10.1016/0017-9310(70)90113-4.
[41] M.A. Styricovich, Y.V. Baryshev, G.V. Tsiklauri and M E. Grigorieva. The mechanism of heat and mass transfer between a water drop and a heated surface. Proceedings of the Sixth International Heat Transfer Conference, Vol. 1, pages 239-243, Toronto, Canada, August 7-11, 1978.
[42] P. Savic and G.T. Boult. The fluid flow associated with the impact of liquid drops with solid surfaces. Proceedings of Heat Transfer Fluid Mechanics Institution, 43-84, 1957.
[43] S.E. Hinkle. Water drop kinetic energy and momentum measurement considerations. Applied Engineering in Agriculture, 5(3):386–391, 1989. doi: 10.13031/2013.26532.
[44] C.D. Stow and R.D. Stainer. The physical products of a splashing water drop. Journal of Meteorological Society of Japan, 55(5):518–532, 1977.
[45] Z. Levin and P.V. Hobbs. Splashing of water drops on solid and wetted surfaces, Hydrodynamics and charge separation. Philosophical Transactions of the Royal Society A Mathematical, Physical and Engineering Sciences, 269(1200):555–585, 1971. doi: 10.1098/rsta.1971.0052.
[46] C.D. Stow, M.G. Hadfield. An experimental investigation of fluid flow resulting from the impact of a water drop with an unyielding dry surface. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, 37(1755):419–441, 1981. doi: 10.1098/rspa.1981.0002.
[47] C. Mundo, M. Sommerfeld, and C. Tropea. Droplet-wall collisions: Experimental studies of the deformation and breakup process. I nternational Journal of Multiphase Flow, 21(2):151–173, 1995. doi: 10.1016/0301-9322(94)00069-V.
[48] M. Bussmann, S. Chandra, and J. Mostaghimi. Modeling the splash of a droplet impacting a solid surface. Physics of Fluids, 12(12):3121–3132, 2000. doi: 10.1063/1.1321258.
[49] L. Xu, W.W. Zhang, and S.R. Nagel. Drop splashing on a dry smooth surface. Physical Review Letters, 94(18):184505, 2005. doi: 10.1103/PhysRevLett.94.184505.
[50] B.T. Helenbrook and C.F. Edwards. Quasi-steady deformation and drag of uncontaminated liquid drops. International Journal of Multiphase Flow, 28(10):1631–1657, 2002. doi: 10.1016/S0301-9322(02)00073-3.
[51] J.Q. Feng. A deformable liquid drop falling through a quiescent gas at terminal velocity. Journal of Fluid Mechanics, 658:438–462, 2010. doi: 10.1017/S0022112010001825.
[52] J.Q. Feng and K.V. Beard. Raindrop shape determined by computing steady axisymmetric solutions for Navier-Stokes equations. Atmospheric Research, 101(1–2):480–491, 2011. doi: 10.1016/j.atmosres.2011.04.012.
[53] J. Han and G. Tryggvason. Secondary breakup of axisymmetric liquid drops. I. Acceleration by a constant body force. Physics of Fluids, 11(12):3650–3667, 1999. doi: 10.1063/1.870229.
[54] J. Han and G. Tryggvason. Secondary breakup of a axisymmetric liquid drops. II. Impulsive acceleration. Physics of Fluids, 13(6):1554–1565, 2001. doi: 10.1063/1.1370389.
[55] P. Khare and V. Yang. Breakup of non-Newtonian liquid droplets. 44th AIAA Fluid Dynamics Conference, Atlanta, USA, 16-20 June 2014. doi: 10.2514/6.2014-2919.
[56] M. Sussman and E.G. Puckett. A Coupled level set and volume-of-fluid method for computing 3D and axisymmetric incompressible two-phase flows. Journal of Computational Physics, 162(2):301–337, 2000. doi: 10.1006/jcph.2000.6537.
[57] R. Scardovelli and S. Zaleski. Direct numerical simulation of free-surface and interfacial flow. Annual Review of Fluid Mechanics, 31:567–603, 1999. doi: 10.1146/annurev.fluid.31.1.567.
[58] S. Shin and D. Juric. Simulation of droplet impact on a solid surface using the level contour reconstruction method. Journal of Mechanical Science and Technology, 23:2434–2443, 2009. doi: 10.1007/s12206-009-0621-z.
[59] M. García Pérez and E. Vakkilainen. A comparison of turbulence models and two and three dimensional meshes for unsteady CFD ash deposition tools. Fuel, 237:806–811, 2019. doi: 10.1016/j.fuel.2018.10.066.
[60] M. Mezhericher, A. Levy, and I. Borde. Modeling of droplet drying in spray chambers using 2D and 3D computational fluid dynamics. Drying Technology, 27(3):359–370, 2009. doi: 10.1080/07373930802682940.
[61] S. Afkhami and M. Bussmann. Height functions for applying contact angles to 2D VOF simulations. International Journal for Numerical Methods in Fluids, 57(4):453-472, 2008. doi: 10.1002/fld.1651.
[62] J. Zheng, J. Wang, Y. Yu, and T. Chen. Hydrodynamics of droplet impingement on a thin horizontal wire. Mathematical Problems in Engineering, 2018:9818494, 2018. doi: 10.1155/2018/9818494.
[63] J. Thalackottore Jose and J.F. Dunne. Numerical simulation of single-droplet dynamics, vaporization, and heat transfer from impingement onto static and vibrating surfaces. Fluids, 5(4):188, 2020. doi: 10.3390/fluids5040188.
[64] H. Liu. Science and Engineering of Droplets: Fundamentals and Applications. Noyes Publications, USA, 1999.
Go to article

Authors and Affiliations

Abid Hasan Rafi
1
ORCID: ORCID
Mohammad Rejaul Haque
1
ORCID: ORCID
Dewan Hasan Ahmed
1
ORCID: ORCID
  1. Department of Mechanical and Production Engineering, Ahsanullah University of Science and Technology, Dhaka, Bangladesh

Hybrid nano improved phase change material for latent thermal energy storage system: Numerical study

Mohamed Lamine Benlekkam Driss Nehari
Archive of Mechanical Engineering | 2022 | vol. 69 | No 1 | 77-98 | DOI: 10.24425/ame.2022.140410
Keywords phase change material (PCM) latent heat storage melting and solidification thermal energy storage hybrid nano-particles LHTESS
Download PDF Download RIS Download Bibtex

Abstract

The phase change materials (PCM) are widely used in several applications, especiallyi n the latent heat thermal energy storage system (LHTESS). Due to the very low thermal conductivity of PCMs. A small mass fraction of hybrid nanoparticles TiO 2–CuO (50%–50%) is dispersed in PCM with five mass concentrations of 0%, 0.25%, 0.5%, 0.75% and 1 mass % to improve its thermal conductivity. This article is focused on thermal performance of the hybrid nano-PCM (HNPCM) used for the LHTESS. A numerical model based on the enthalpy-porosity technique is developed to solve the Navier-Stocks and energy equations. The computations were conducted for the melting and solidification processes of the HNPCM in a shell and tube latent heat storage (LHS). The developed numerical model was validated successfully with experimental data from the literature. The results showed that the dispersed hybrid nanoparticles improved the effective thermal conductivity and density of the HNPCM. Accordingly, when the mass fraction of a HNPCM increases by 0.25%, 0.5%, 0.75% and 1 mass %, the average charging time improves by 12.04 %, 19.9 %, 23.55%, and 27.33 %, respectively. Besides, the stored energy is reduced by 0.83%, 1.67%, 2.83% and 3.88%, respectively. Moreover, the discharging time was shortened by 18.47%, 26.91%, 27.71%, and 30.52%, respectively.
Go to article

Bibliography

[1] L.F. Cabeza, A. Castell, C. Barreneche, A. de Gracia, and A. Fernández. Materials used as PCM in thermal energy storage in buildings: A review. Renewable and Sustainable Energy Reviews, 15(3):1675–1695, 2011. doi: 10.1016/j.rser.2010.11.018.
[2] K. Nedjem, M. Teggar, K.A.R. Ismail, and D. Nehari. Numerical investigation of charging and discharging processes of a shell and tube nano-enhanced latent thermal storage unit. Journal of Thermal Science and Engineering Applications, 12(2):021021, 2020. doi: 10.1115/1.4046062.
[3] K. Hosseinzadeh, M.A. Efrani Moghaddam, A. Asadi, A.R. Mogharrebi, and D.D. Ganji. Effect of internal fins along with hybrid nano-particles on solid process in star shape triplex latent heat thermal energy storage system by numerical simulation. Renewable Energy, 154:497–507, 2020. doi: 10.1016/j.renene.2020.03.054.
[4] M.M. Joybari, S. Seddegh, X. Wang, and F. Haghighat. Experimental investigation of multiple tube heat transfer enhancement in a vertical cylindrical latent heat thermal energy storage system. Renewable Energy,} 140:234–244, 2019. doi: 10.1016/j.renene.2019.03.037.
[5] A.A. Al-Abidi, S. Mat, K. Sopian, M.Y. Sulaiman, and A.T. Mohammad. Internal and external fin heat transfer enhancement technique for latent heat thermal energy storage in triplex tube heat exchangers. Applied Thermal Engineering, 53(1):147–156, 2013. doi: 10.1016/j.applthermaleng.2013.01.011.
[6] X. Yang, Z. Lu, Q. Bai, Q. Zhang, L. Jin, and J. Yan. Thermal performance of a shell-and-tube latent heat thermal energy storage unit: Role of annular fins. Applied Energy, 202:558–570, 2017. doi: 10.1016/j.apenergy.2017.05.007.
[7] C. Zhao, M. Opolot, M. Liu, F. Bruno, S. Mancin, and K. Hooman. Numerical study of melting performance enhancement for PCM in an annular enclosure with internal-external fins and metal foams. International Journal of Heat and Mass Transfer, 150:119348, 2020. doi: 10.1016/j.ijheatmasstransfer.2020.119348.
[8] M. Longeon, A. Soupart, J.-F. Fourmigué, A. Bruch, and P. Marty. Experimental and numerical study of annular PCM storage in the presence of natural convection. Applied Energy, 112:175–184, 2013. doi: 10.1016/j.apenergy.2013.06.007.
[9] S. Seddegh, S.S.M. Tehrani, X. Wang, F. Cao, and R.A. Taylor. Comparison of heat transfer between cylindrical and conical vertical shell-and-tube latent heat thermal energy storage systems. Applied Thermal Engineering, 130:1349–1362, 2018. doi: 10.1016/j.applthermaleng.2017.11.130.
[10] I. Al Siyabi, S. Khanna, T. Mallick, and S. Sundaram. An experimental and numerical study on the effect of inclination angle of phase change materials thermal energy storage system. Journal of Energy Storage, 23:57–68, 2019. doi: 10.1016/j.est.2019.03.010.
[11] S. Sebti, S. Khalilarya, I. Mirzaee, S. Hosseinizadeh, S. Kashani, and M. Abdollahzadeh. A numerical investigation of solidification in horizontal concentric annuli filled with nano-enhanced phase change material (NEPCM). World Applied Sciences Journal, 13(1):9–15, 2011.
[12] N. Dhaidan, J. Khodadadi, T.A. Al-Hattab, and S. Al-Mashat. Experimental and numerical investigation of melting of NePCM inside an annular container under a constant heat flux including the effect of eccentricity. International Journal of Heat and Mass Transfer, 67:455–468, 2013. doi: 10.1016/j.ijheatmasstransfer.2013.08.002.
[13] Q. Ren, F. Meng, and P. Guo. A comparative study of PCM melting process in a heat pipe-assisted LHTES unit enhanced with nanoparticles and metal foams by immersed boundary-lattice Boltzmann method at pore-scale. International Journal of Heat and Mass Transfer, 121:1214–1228, 2018. doi: 10.1016/j.ijheatmasstransfer.2018.01.046.
[14] C. Nie, J. Liu, and S. Deng. Effect of geometric parameter and nanoparticles on PCM melting in a vertical shell-tube system. Applied Thermal Engineering, 184:116290, 2020. doi: 10.1016/j.applthermaleng.2020.116290.
[15] M. Gorzin, M.J. Hosseini, M. Rahimi, and R. Bahrampoury. Nano-enhancement of phase change material in a shell and multi-PCM-tube heat exchanger. Journal of Energy Storage, 22:88–97, 2019. doi: 10.1016/j.est.2018.12.023.
[16] M. Khatibi, R. Nemati-Farouji, A. Taheri, A. Kazemian, T. Ma, and H. Niazmand. Optimization and performance investigation of the solidification behavior of nano-enhanced phase change materials in triplex-tube and shell-and-tube energy storage units. Journal of Energy Storage, 33:102055, 2020. doi: 10.1016/j.est.2020.102055.
[17] P. Manoj Kumar, K. Mylsamy, and P.T. Saravanakumar. Experimental investigations on thermal properties of nano-SiO 2/paraffin phase change material (PCM) for solar thermal energy storage applications. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, 42(19):2420–2433, 2020. doi: 10.1080/15567036.2019.1607942.
[18] P. Manoj Kumar, K. Mylsamy, K. Alagar, and K. Sudhakar. Investigations on an evacuated tube solar water heater using hybrid-nano based organic phase change material. International Journal of Green Energy, 17(13):872–883, 2020. doi: 10.1080/15435075.2020.1809426.
[19] S. Ebadi, S.H. Tasnim, A.A. Aliabadi, and S. Mahmud. Melting of nano-PCM inside a cylindrical thermal energy storage system: Numerical study with experimental verification. Energy Conversion and Management, 166:241–259, 2018. doi: 10.1016/j.enconman.2018.04.016.
[20] J.M. Mahdi and E.C. Nsofor. Solidification enhancement of PCM in a triplex-tube thermal energy storage system with nanoparticles and fins. Applied Energy, 211:975–986, 2018. doi: 10.1016/j.apenergy.2017.11.082.
[21] M.J. Hosseini, A.A. Ranjbar, K. Sedighi, and M. Rahimi. A combined experimental and computational study on the melting behavior of a medium temperature phase change storage material inside shell and tube heat exchanger. International Communications in Heat and Mass Transfer, 39(9):1416–1424, 2012. doi: 10.1016/j.icheatmasstransfer.2012.07.028.
[22] S. Harikrishnan, K. Deepak, and S. Kalaiselvam. Thermal energy storage behavior of composite using hybrid nanomaterials as PCM for solar heating systems. Journal of Thermal Analysis and Calorimetry, 115:1563–1571, 2014. doi: 10.1007/s10973-013-3472-x.
[23] ANSYS. Fluent. (2017), Copyright 2017 SAS IP, Inc.
[24] Z. Khan, Z.A. Khan, and P. Sewell. Heat transfer evaluation of metal oxides based nano-PCMs for latent heat storage system application. International Journal of Heat and Mass Transfer, 144:118619, 2019. doi: 10.1016/j.ijheatmasstransfer.2019.118619.
[25] J.C. Maxwell. Electricity and Magnetism. Clarendon Press, Oxford, 1873.
[26] S. Ghadikolaei, K. Hosseinzadeh, and D.D. Ganji. Investigation on three dimensional squeezing flow of mixture base fluid (ethylene glycol-water) suspended by hybrid nanoparticle (Fe 3O 4-Ag) dependent on shape factor. Journal of Molecular Liquids, 262:376–388, 2018. doi: 10.1016/j.molliq.2018.04.094.
[27] S.S. Ghadikolaei, M. Yassari, H. Sadeghi, K. Hosseinzadeh, and D.D. Ganji. Investigation on thermophysical properties of TiO 2–Cu/H 2O hybrid nanofluid transport dependent on shape factor in MHD stagnation point flow. Powder Technology, 322:428–438, 2017. doi: 10.1016/j.powtec.2017.09.006.
[28] A.D. Brent, V.R. Voller, and K. Reid. Enthalpy-porosity technique for modeling convection-diffusion phase change: application to the melting of a pure metal. Numerical Heat Transfer, 13(3):297–318, 1988. doi: 10.1080/10407788808913615.
[29] S.V. Patankar. Numerical Heat Transfer and Fluid Flow. CRC Press, 1980.
[30] M.L. Benlekkam, D. Nehari, and N. Cheriet. Numerical investigation of latent heat thermal energy storage system. Recueil de Mécanique, 3:229-235, 2018. doi: 10.5281/zenodo.1490505.
[31] M.A. Kibria, M.R. Anisur, M.H. Mahfuz, R. Saidur, and I.H.S.C. Metselaar. Numerical and experimental investigation of heat transfer in a shell and tube thermal energy storage system. International Communications in Heat and Mass Transfer, 53:71–78, 2014. doi: 10.1016/j.icheatmasstransfer.2014.02.023.
[32] M.J. Hosseini, M. Rahimi, and R. Bahrampoury. Experimental and computational evolution of a shell and tube heat exchanger as a PCM thermal storage system. International Communications in Heat and Mass Transfer, 50:128–136, 2014. doi: 10.1016/j.icheatmasstransfer.2013.11.008.
Go to article

Authors and Affiliations

Mohamed Lamine Benlekkam
1 2
ORCID: ORCID
Driss Nehari
3
ORCID: ORCID
  1. Department of Science and Technology, University of Tissemsilt, Tissemsilt, Algeria
  2. Laboratory of Smart Structure, University of Ain Temouchent, Ain Temouchent, Algeria
  3. Laboratory of Hydrology and Applied Environment, University of Ain Temouchent, Algeria

Design and analysis of cementless hip-joint system using functionally graded material

Saeed Asiri
Archive of Mechanical Engineering | 2022 | vol. 69 | No 1 | 129-146 | DOI: 10.24425/ame.2021.139804
Keywords functionally graded material cementless hip-joint system natural frequency harmonic response fatigue analysis finite element analysis modal analysis
Download PDF Download RIS Download Bibtex

Abstract

Functionally Graded Materials (FGM) are extensively employed for hip plant component material due to their certain properties in a specific design to achieve the requirements of the hip-joint system. Nevertheless, if there are similar properties, it doesn’t necessarily indicate that the knee plant is efficiently and effectively working. Therefore, it is important to develop an ideal design of functionally graded material femoral components that can be used for a long period. A new ideal design of femoral prosthesis can be introduced using functionally graded fiber polymer (FGFP) which will reduce the stress shielding and the corresponding stresses present over the interface. Herein, modal analysis of the complete hip plant part is carried out, which is the main factor and to date, very few research studies have been found on it. Moreover, this enhances the life of hip replacement, and the modal, harmonic, and fatigue analysis determines the pre-loading failure phenomena due to the vibrational response of the hip. This study deals with the cementless hip plant applying the finite element analysis (FEA) model in which geometry is studied, and the femoral bone model is based in a 3D scan.
Go to article

Bibliography

[1] S. Gross and E.W. Abel. A finite element analysis of hollow stemmed hip prostheses as a means of reducing stress shielding of the femur. Journal of Biomechanics, 34(8):995–1003, 2001. doi: 10.1016/s0021-9290(01)00072-0.
[2] D. Lin, Q. Li, W. Li, S. Zhou, and M.V. Swain. Design optimization of functionally graded dental implant for bone remodeling. Composites Part B: Engineering, 40(7):668–675, 2009. doi: 10.1016/j.compositesb.2009.04.015.
[3] G. Jin, M. Takeuchi, S. Honda, T. Nishikawa, and H. Awaji. Properties of multilayered mullite/Mo functionally graded materials fabricated by powder metallurgy processing. Materials Chemistry and Physics, 89(2-3):238–243, 2005. doi: 10.1016/j.matchemphys.2004.03.031.
[4] E. Yılmaz, A. Gökçe, F. Findik, H.O. Gulsoy, and O. İyibilgin. Mechanical properties and electrochemical behavior of porous Ti-Nb biomaterials. Journal of the Mechanical Behavior of Biomedical Materials, 87:59–67, 2018. doi: 10.1016/j.jmbbm.2018.07.018.
[5] A.T. Şensoy. M. Çolak, I. Kaymaz, and F. Findik. Optimal material selection for total hip implant: a finite element case study. Arabian Journal for Science and Engineering, 44:10293--10301, 2019. doi: 10.1007/s13369-019-04088-y.
[6] T.A. Enab and N.E. Bondok. Material selection in the design of the tibia tray component of cemented artificial knee using finite element method. Materials and Design, 44:454–460, 2013. doi: 10.1016/j.matdes.2012.08.017.
[7] H. Weinans, R.Huiskes, and H.J. Grootenboer. The behavior of adaptive bone-remodeling simulation models. Journal of Biomechanics, 25(12):1425–1441, 1992. doi: 10.1016/0021-9290(92)90056-7.
[8] J.A. Simões and A.T. Marques. Design of a composite hip femoral prosthesis. Materials & Design, 26(5):391–401, 2005. doi: 10.1016/j.matdes.2004.07.024.
[9] S. Tyagi and S.K. Panigrahi. Transient analysis of ball bearing fault simulation using finite element method. Journal of The Institution of Engineers (India): Series C, 95:309–318, 2014. doi: 10.1007/s40032-014-0129-x.
[10] I.S. Jalham. Computer-aided quality function deployment method for material selection. International Journal of Computer Applications in Technology, 26((4):190–196, 2006. doi: 10.1504/IJCAT.2006.010764.
[11] E. Karana, P. Hekkert, and P. Kandachar. Material considerations in product design: A survey on crucial material aspects used by product designers. Materials & Design, 29(6):1081–1089, 2008. doi: 10.1016/j.matdes.2007.06.002.
[12] M.F. Ashby. Materials Selection in Mechanical Design. Butterworth-Heinemann, Oxford, 1995.
[13] C. Vezzoli and E. Manzini. Environmental complexity and designing activity. In: Design for Environmental Sustainability, pages 215–217. Springer, London, 2008. doi: 10.1007/978-1-84800-163-3_11.
[14] M. Kutz. Handbook of Materials Selection. John Wiley & Sons, New York, 2002.
[15] R.V. Rao and B.K. Patel. A subjective and objective integrated multiple attribute decision making method for material selection. Materials & Design, 31(10):4738–4747, 2010. doi: 10.1016/j.matdes.2010.05.014.
[16] X.F. Zha. A web-based advisory system for process and material selection in concurrent product design for a manufacturing environment. The International Journal of Advanced Manufacturing Technology, 25:233–243, 2005. doi: 10.1007/s00170-003-1838-0.
[17] F. Giudice, G. La Rosa, and A. Risitano. Materials selection in the Life-Cycle Design process: a method to integrate mechanical and environmental performances in optimal choice. Materials & Design, 26(1):9–20, 2005. doi: 10.1016/j.matdes.2004.04.006.
[18] F. Findik and K. Turan. Materials selection for lighter wagon design with a weighted property index method. Materials & Design, 37:470–477, 2012. doi: 10.1016/j.matdes.2012.01.016.
[19] M. İpek, İ.H. Selvi, F. Findik, O. Torkul, and I.H. Cedimoğlu. An expert system based material selection approach to manufacturing. Materials & Design, 47:331–340, 2013. doi: 10.1016/j.matdes.2012.11.060.
[20] J.A. Basurto-Hurtado, G.I. Perez-Soto, R.A. Osornio-Rios, A. Dominguez-Gonzalez, and L.A. Morales-Hernandez. A new approach to modeling the ductile cast iron microstructure for a finite element analysis. Arabian Journal for Science and Engineering, 44:1221–1231, 2019. doi: 10.1007/s13369-018-3465-y.
[21] E. Yılmaz, F. Kabataş, A. Gökçe, and F. Fındık. Production and characterization of a bone-like porous Ti/Ti-hydroxyapatite functionally graded material. Journal of Materials Engineering and Performance, 29:6455--6467, 2020. doi: 10.1007/s11665-020-05165-2.
[22] E. Yılmaz, A. Gökçe, F. Findik, and H.Ö. Gulsoy. Assessment of Ti–16Nb– xZr alloys produced via PIM for implant applications. Journal of Thermal Analysis and Calorimetry, 134:7–14, 2018. doi: 10.1007/s10973-017-6808-0.
[23] H.F. El-Sheikh, B.J. MacDonald, and M.S.J. Hashmi. Material selection in the design of the femoral component of cemented total hip replacement. Journal of Materials Processing Technology, 122(2-3):309–317, 2002. doi: 10.1016/S0924-0136(01)01128-1.
[24] T.S. Rubak, S.W. Svendsen, K. Søballe, and P. Frost. Total hip replacement due to primary osteoarthritis in relation to cumulative occupational exposures and lifestyle factors: a nationwide nested case–control study. Arthritis Care & Research, 66(10):1496–1505. doi: 10.1002/acr.22326.
[25] İ. Çelik and H. Eroğlu. Selection application of material to be used in hip prosthesis production with analytic hierarchy process. Materials Science & Engineering Technology, 48(11):1125–1132, 2017. doi: 10.1002/mawe.201700046.
[26] A. Aherwar, A. Patnaik, M. Bahraminasab, and A. Singh. Preliminary evaluations on development of new materials for hip joint femoral head. Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications, 233(5):885–899, 2019. doi: 10.1177/1464420717714495.
[27] A. Hafezalkotob and A. Hafezalkotob. Comprehensive MULTIMOORA method with target-based attributes and integrated significant coefficients for materials selection in biomedical applications. Materials & Design, 87:949–959, 2015. doi: 10.1016/j.matdes.2015.08.087.
[28] G. Bergmann, G. Deuretzbacher, M. Heller, F. Graichen, A. Rohlmann, J. Strauss, anf G.N. Duda. Hip contact forces and gait patterns from routine activities. Journal of Biomechanics, 34(7):859–871, 2001. doi: 10.1016/s0021-9290(01)00040-9.
[29] A.Z. Şenalp, O. Kayabasi, and H. Kurtaran. Static, dynamic and fatigue behavior of newly designed stem shapes for hip prosthesis using finite element analysis. Materials and Design, 28(5):1577–1583, 2007. doi: 10.1016/j.matdes.2006.02.015.
Go to article

Authors and Affiliations

Saeed Asiri
1
ORCID: ORCID
  1. Mechanical Engineering Department, Engineering College King Abdulaziz University, Jeddah, Saudi Arabia

Simulating human motion using Motion Model Units - example implementation and usage

Adam Kłodowski Ilya Kurinov Grzegorz Orzechowski Aki Mikkola
Archive of Mechanical Engineering | 2022 | vol. 69 | No 3 | 345-373 | DOI: 10.24425/ame.2022.141515
Keywords motion generation example with source code MMU MOSIM human simulation
Download PDF Download RIS Download Bibtex

Abstract

Human motion is required in many simulation models. However, generating such a motion is quite complex and in industrial simulation cases represents an overhead that often cannot be accepted. There are several common file formats that are used nowadays for saving motion data that can be used in gaming engines or 3D editing software. Using such motion sets still requires considerable effort in creating logic for motion playing, blending, and associated object manipulation in the scene. Additionally, every action needs to be described with the motion designed for the target scene environment. This is where the Motion Model Units (MMU) concept was created. Motion Model Units represent a new way of transferring human motion data together with logic and scene manipulation capabilities between motion vendors and simulation platforms. The MMU is a compact software bundle packed in a standardized way, provides machine-readable capabilities and interface description that makes it interchangeable, and is adaptable to the scene. Moreover, it is designed to represent common actions in a task-oriented way, which allows simplifying the scenario creation to a definition of tasks and their timing. The underlying Motion Model Interface (MMI) has become an open standard and is currently usable in MOSIM framework, which provides the implementation of the standard for the Unity gaming engine and works on implementation for the Unreal Engine are under way. This paper presents two implementation examples for the MMU using direct C# programming, and using C# for Unity and MOSIM MMU generator as a helping tool. The key points required to build a working MMU are presented accompanied by an open-source code that is available for download and experimenting.
Go to article

Bibliography

[1] Manufacturing statistics – NACE Rev. 2. https://ec.europa.eu/eurostat/ statistics-explained/index.php? title=Manufacturing_statistics_-_NACE_ Rev._2&oldid=502915. 2021-03-04.
[2] D. Sabadka, V. Molnar, and G. Fedorko. Shortening of life cycle and complexity impact on the automotive industry. TEM Journal, 8(4):1295–1301, 2019. doi: 10.18421/TEM84-27.
[3] J. Ajaefobi and R. Weston. Modelling human systems in support of process engineering. In G. Zülch, H. Jagdev, and P. Stock, editors, Integrating Human Aspects in Production Management. IFIP International Conference for Information Processing, volume 160, pages 3–16, Boston, MA, 2005. Springer US. doi: 10.1007/0-387-23078-5_1.
[4] D. Lämkull, L. Hanson, and R. Örtengren. A comparative study of digital human modelling simulation results and their outcomes in reality: A case study within manual assembly of automobiles. International Journal of Industrial Ergonomics, 39(2):428–441, 2009. doi: 10.1016/j.ergon.2008.10.005.
[5] D. B. Chaffin, C. Nelson, et al. Digital Human Modeling for Vehicle and Workplace Design. Society of Automotive Engineers Warrendale, PA, USA, 2001.
[6] H.O. Demirel and V.G. Duffy. Applications of digital human modeling in industry. In V.G. Duffy, editor, Digital Human Modeling, pages 824–832. Springer, 2007. doi: 10.1007/978-3- 540-73321-8_93.
[7] A. Naumann and M. Rötting. Digital human modeling for design and evaluation of humanmachine systems. MMI Interaktiv, 12:27–35, 2007.
[8] V. Duffy. Handbook of Digital Human Modelling: Research for Applied ergonomics and Human Factors Engineering. CRC Press, 2008. doi: 10.1201/9781420063523.
[9] C.B. Phillips and N.I. Badler. JACK: A toolkit for manipulating articulated figures. In Proceedings of the 1st Annual ACM SIGGRAPH Symposium on User Interface Software, UIST ’88, page 221–229, New York, NY, USA, 1988. doi: 10.1145/62402.62436.
[10] R. Gilbert, R. Carrier, J. Schiettekatte, C. Fortin, B. Dechamplain, H.N. Cheng, A. Savard, C. Benoit, and M. Lachapelle. SAFEWORK: Software to analyse and design workplaces. In G.R. McMillan et al., editors, Applications of Human Performance Models to System Design, pages 389–396. Springer, 1989. doi: 10.1007/978-1-4757-9244-7_28.
[11] K. Abdel-Malek, J. Yang, J. H. Kim, T. Marler, S. Beck, C. Swan, L. Frey-Law, A. Mathai, C. Murphy, S. Rahmatallah, and J. Arora. Development of the virtual-human santostm. In V.G. Duffy, editor, Digital Human Modeling, pages 490–499. Springer, 2007. doi: 10.1007/978-3- 540-73321-8_57.
[12] MSCAdams software. https://www.mscsoftware.com/product/adams. Accessed: 2021- 03-22.
[13] S.L. Delp, F.C. Anderson, A.S. Arnold, P. Loan, A. Habib, C. T. John, E. Guendelman, and D. G. Thelen. OpenSim: open-source software to create and analyze dynamic simulations of movement. IEEE Transactions on Biomedical Engineering, 54(11):1940–1950, 2007. doi: 10.1109/TBME.2007.901024.
[14] P.-B. Wieber, F. Billet, L. Boissieux, and R. Pissard-Gibollet. The humans toolbox, a homogenous framework for motion capture, analysis and simulation. In International Symposium on the 3D Analysis of Human Movement, 2006.
[15] H.-J. Wirsching. Human solutions RAMSIS. In S. Scataglini and G. Paul, editors, DHM and Posturography, pages 49–55.Academic Press, 2019.doi: 10.1016/B978-0-12-816713-7.00004-0.
[16] M. Hovanec, P. Korba, and M. Solc. TECNOMATIX for successful application in the area of simulation manufacturing and ergonomics. In 1 5th International SGEM Geoconference on Informatics, Albena, Bulgaria, 2015.
[17] J. Rasmussen. The AnyBody modeling system. In S. Scataglini and G. Paul, editors, DHM and Posturography, pages 85–96. Academic Press, 2019. doi: 10.1016/B978-0-12-816713- 7.00008-8.
[18] Simcenter Madymo. https://www.plm.automation.siemens.com/global/en/ products/simcenter/madymo.html. Accessed: 2022-04-07.
[19] F. Gaisbauer, P. Agethen, M. Otto, T. Bär, J. Sues, and E. Rukzio. Presenting a modular framework for a holistic simulation of manual assembly tasks. Procedia CIRP, 72:768–773, 2018. doi: 10.1016/j.procir.2018.03.281.
[20] FMI standard. https://fmi-standard.org/. Accessed: 2021-03-22.
[21] Unity. https://unity.com/. Accessed: 2021-03-22.
[22] Unreal engine. https://www.unrealengine.com/en-US/. Accessed: 2021-03-22.
[23] F. Gaisbauer, E. Lampen, P. Agethen, and E. Rukzio. Combining heterogeneous digital human simulations: presenting a novel co-simulation approach for incorporating different character animation technologies. The Visual Computer, 37:717–734, 2020. doi: 10.1007/s00371-020- 01792-x.
[24] MOSIM. https://mosim.eu. Accessed: 2021-03-22.
[25] A. Safonova, J.K. Hodgins, and N.S. Pollard. Synthesizing physically realistic human motion in low-dimensional, behavior-specific spaces. ACM Transactions on Graphics, 23(3):514–521, 2004. doi: 10.1145/1186562.1015754.
[26] K. Rakowski. Learning Apache Thrift. Packt Publishing Ltd, 2015.
[27] M. Sporny, D. Longley, G. Kellogg, M. Lanthaler, and N. Lindström. JSON-LD 1.0. W3C recommendation, 16:41, 2014.
[28] MOSIM download section. https://mosim.eu/download.php. Accessed: 2021-03-22.
[29] K. Pietroszek, P. Pham, S. Rose, L. Tahai, I. Humer, and C. Eckhardt. Real-time avatar animation synthesis from coarse motion input. In Proceedings of the 23rd ACM Symposium on Virtual Reality Software and Technology, Gothenburg, Sweden, 2017. doi: 10.1145/3139131.3141223.
[30] RFC CSV file specification. https://tools.ietf.org/html/rfc4180. Accessed: 2021- 03-29.
Go to article

Authors and Affiliations

Adam Kłodowski
1
Ilya Kurinov
1
Grzegorz Orzechowski
1
Aki Mikkola
1
  1. Department of Mechanical Engineering, LUT University, Lappeenranta, Finland

Air bottoming combined cycle performance analyses by the combined effect of variable parameters

Mohammad N. Khan Dhare Alzafiri
Archive of Mechanical Engineering | 2022 | vol. 69 | No 3 | 497-517 | DOI: 10.24425/ame.2022.140425
Keywords topping cycle air bottoming cycle net power output thermal efficiency total exergy destruction exergetic efficiency
Download PDF Download RIS Download Bibtex

Abstract

To meet the continuous demand for energy of industrial as well as commercial sectors, researchers focus on increasing the power generating capacity of gas turbine power plants. In this regard, the combined cycle is a better solution in terms of environmental aspects and power generation as compared to a simple gas turbine power plant. The present study is the thermodynamic investigation of five possible air bottoming combined cycles in which the topping cycle is a simple gas turbine cycle, regenerative gas turbine cycle, inter-cool gas turbine cycle, reheat gas turbine cycle, and intercool-reheat gas turbine cycle. The effect of pressure ratio of the topping cycle, the turbine inlet temperature of topping cycle, and ambient temperature on net power output, thermal efficiency, total exergy destruction, and exergetic efficiency of the combined cycle have been analyzed. The ratio of the net power output of the combined cycle to that of the topping cycle is maximal in the case when the topping cycle is a simple gas turbine cycle. The ratio of net power output and the total exergy destruction of the combined cycle to those of the topping cycle decrease with pressure ratio for all the combinations under study except for the case when the topping cycle is the regenerative gas turbine cycle.
Go to article

Bibliography

[1] A. Valera-Medina, A. Giles, D. Pugh, S. Morris, M. Pohl, and A. Ortwein. Investigation of combustion of emulated biogas in a gas turbine test rig. Journal of Thermal Science, 27:331–340, 2018. doi: 10.1007/s11630-018-1024-1.
[2] K. Tanaka and I. Ushiyama. Thermodynamic performance analysis of gas turbine power plants with intercooler: 1st report, Theory of intercooling and performance of intercooling type gas turbine. Bulletin of JSME, 13(64):1210–1231, 1970. doi: 10.1299/jsme1958.13.1210.
[3] H.M. Kwon, T.S. Kim, J.L. Sohn, and D.W. Kang. Performance improvement of gas turbine combined cycle power plant by dual cooling of the inlet air and turbine coolant using an absorption chiller. Energy, 163:1050–1061, 2018. doi: 10.1016/j.energy.2018.08.191.
[4] A.T. Baheta and S.I.-U.-H. Gilani. The effect of ambient temperature on a gas turbine performance in part load operation. AIP Conference Proceedings, 1440:889–893, 2012. doi: 10.1063/1.4704300.
[5] F.R. Pance Arrieta and E.E. Silva Lora. Influence of ambient temperature on combined-cycle power-plant performance. Applied Energy, 80(3):261–272, 2005. doi: 10.1016/j.apenergy.2004.04.007.
[6] M. Ameri and P. Ahmadi. The study of ambient temperature effects on exergy losses of a heat recovery steam generator. In: Cen, K., Chi, Y., Wang, F. (eds) Challenges of Power Engineering and Environment. Springer, Berlin, Heidelberg, 2007. doi: 10.1007/978-3-540-76694-0_9.
[7] M.A.A. Alfellag: Parametric investigation of a modified gas turbine power plant. Thermal Science and Engineering Progress, 3:141–149, 2017. doi: 10.1016/j.tsep.2017.07.004.
[8] J.H. Horlock and W.A. Woods. Determination of the optimum performance of gas turbines. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 214:243–255, 2000. doi: 10.1243/0954406001522930.
[9] L. Battisti, R. Fedrizzi, and G. Cerri. Novel technology for gas turbine blade effusion cooling. In: Proceedings of the ASME Turbo Expo 2006: Power for Land, Sea, and Air. Volume 3: Heat Transfer, Parts A and B. pages 491–501. Barcelona, Spain. May 8–11, 2006. doi: 10.1115/GT2006-90516.
[10] F.J. Wang and J.S. Chiou. Integration of steam injection and inlet air cooling for a gas turbine generation system. Energy Conversion and Management, 45(1):15–26, 2004. doi: 10.1016/S0196-8904(03)00125-0.
[11] Z. Wang. 1.23 Energy and air pollution. In I. Dincer (ed.): Comprehensive Energy Systems, pp. 909–949. Elsevier, 2018. doi: 10.1016/B978-0-12-809597-3.00127-9.
[12] Z. Khorshidi, N.H. Florin, M.T. Ho, and D.E. Wiley. Techno-economic evaluation of co-firing biomass gas with natural gas in existing NGCC plants with and without CO$_2$ capture. International Journal of Greenhouse Gas Control, 49:343–363, 2016. doi: 10.1016/j.ijggc.2016.03.007.
[13] K. Mohammadi, M. Saghafifar, and J.G. McGowan. Thermo-economic evaluation of modifications to a gas power plant with an air bottoming combined cycle. Energy Conversion and Management, 172:619–644, 2018. doi: 10.1016/j.enconman.2018.07.038.
[14] S. Mohtaram, J. Lin, W. Chen, and M.A. Nikbakht. Evaluating the effect of ammonia-water dilution pressure and its density on thermodynamic performance of combined cycles by the energy-exergy analysis approach. Mechanika, 23(2):18110, 2017. doi: 10.5755/j01.mech.23.2.18110.
[15] M. Maheshwari and O. Singh. Comparative evaluation of different combined cycle configurations having simple gas turbine, steam turbine and ammonia water turbine. Energy, 168:1217–1236, 2019. doi: 10.1016/j.energy.2018.12.008.
[16] A. Khaliq and S.C. Kaushik. Second-law based thermodynamic analysis of Brayton/Rankine combined power cycle with reheat. Applied Energy, 78(2):179–197, 2004. doi: 10.1016/j.apenergy.2003.08.002.
[17] M. Aliyu, A.B. AlQudaihi, S.A.M. Said, and M.A. Habib. Energy, exergy and parametric analysis of a combined cycle power plant. Thermal Science and Engineering Progress. 15:100450, 2020. doi: 10.1016/j.tsep.2019.100450.
[18] M.N. Khan, T.A. Alkanhal, J. Majdoubi, and I. Tlili. Performance enhancement of regenerative gas turbine: air bottoming combined cycle using bypass valve and heat exchanger—energy and exergy analysis. Journal of Thermal Analysis and Calorimetry. 144:821–834, 2021. doi: 10.1007/s10973-020-09550-w.
[19] F. Rueda Martínez, A. Rueda Martínez, A. Toleda Velazquez, P. Quinto Diez, G. Tolentino Eslava, and J. Abugaber Francis. Evaluation of the gas turbine inlet temperature with relation to the excess air. Energy and Power Engineering, 3(4):517–524, 2011. doi: 10.4236/epe.2011.34063.
[20] A.K. Mohapatra and R. Sanjay. Exergetic evaluation of gas-turbine based combined cycle system with vapor absorption inlet cooling. Applied Thermal Engineering, 136:431–443, 2018. doi: 10.1016/j.applthermaleng.2018.03.023.
[21] A.A. Alsairafi. Effects of ambient conditions on the thermodynamic performance of hybrid nuclear-combined cycle power plant. International Journal of Energy Research, 37(3):211–227, 2013. doi: 10.1002/er.1901.
[22] A.K. Tiwari, M.M. Hasan, and M. Islam. Effect of ambient temperature on the performance of a combined cycle power plant. Transactions of the Canadian Society for Mechanical Engineering, 37(4):1177–1188, 2013. doi: 10.1139/tcsme-2013-0099.
[23] T.K. Ibrahim, M.M. Rahman, and A.N. Abdalla. Gas turbine configuration for improving the performance of combined cycle power plant. Procedia Engineering, 15:4216–4223, 2011. doi: 10.1016/j.proeng.2011.08.791.
[24] M.N. Khan and I. Tlili. New advancement of high performance for a combined cycle power plant: Thermodynamic analysis. Case Studies in Thermal Engineering. 12:166–175, 2018. doi: 10.1016/j.csite.2018.04.001.
[25] S.Y. Ebaid and Q.Z. Al-hamdan. Thermodynamic analysis of different configurations of combined cycle power plants. Mechanical Engineering Research. 5(2):89–113, 2015. doi: 10.5539/mer.v5n2p89.
[26] R. Teflissi and A. Ataei. Effect of temperature and gas flow on the efficiency of an air bottoming cycle. Journal of Renewable and Sustainable Energy, 5(2):021409, 2013. doi: 10.1063/1.4798486.
[27] A.A. Bazmi, G. Zahedi, and H. Hashim. Design of decentralized biopower generation and distribution system for developing countries. Journal of Cleaner Production, 86:209–220, 2015. doi: 10.1016/j.jclepro.2014.08.084.
[28] A.I. Chatzimouratidis and P.A. Pilavachi. Decision support systems for power plants impact on the living standard. Energy Conversion and Management, 64:182–198, 2012. doi: 10.1016/j.enconman.2012.05.006.
[29] T.K. Ibrahim, F. Basrawi, O.I. Awad, A.N. Abdullah, G. Najafi, R. Mamat, and F.Y. Hagos. Thermal performance of gas turbine power plant based on exergy analysis. Applied Thermal Engineering, 115:977–985, 2017. doi: 10.1016/j.applthermaleng.2017.01.032.
[30] M. Ghazikhani, I. Khazaee, and E. Abdekhodaie. Exergy analysis of gas turbine with air bottoming cycle. Energy, 72:599–607, 2014. doi: 10.1016/j.energy.2014.05.085.
[31] M.N. Khan, I. Tlili, and W.A. Khan. thermodynamic optimization of new combined gas/steam power cycles with HRSG and heat exchanger. Arabian Journal for Science and Engineering, 42:4547–4558, 2017. doi: 10.1007/s13369-017-2549-4.
[32] N. Abdelhafidi, İ.H. Yılmaz, and N.E.I. Bachari. An innovative dynamic model for an integrated solar combined cycle power plant under off-design conditions. Energy Conversion and Management, 220:113066, 2020. doi: 10.1016/j.enconman.2020.113066.
[33] T.K. Ibrahim, M.K. Mohammed, O.I. Awad, M.M. Rahman, G. Najafi, F. Basrawi, A.N. Abd Alla, and R. Mamat. The optimum performance of the combined cycle power plant: A comprehensive review. Renewable and Sustainable Energy Reviews, 79:459–474, 2017. doi: 10.1016/j.rser.2017.05.060.
[34] M.N. Khan. Energy and exergy analyses of regenerative gas turbine air-bottoming combined cycle: optimum performance. Arabian Journal for Science and Engineering, 45:5895–5905, 2020. doi: 10.1007/s13369-020-04600-9.
[35] A.M. Alklaibi, M.N. Khan, and W.A. Khan. Thermodynamic analysis of gas turbine with air bottoming cycle. Energy, 107:603–611, 2016. doi: 10.1016/j.energy.2016.04.055.
[36] M. Ghazikhani, M. Passandideh-Fard, and M. Mousavi. Two new high-performance cycles for gas turbine with air bottoming. Energy, 36(1):294–304, 2011. doi: 10.1016/j.energy.2010.10.040.
[37] M.N. Khan and I. Tlili. Innovative thermodynamic parametric investigation of gas and steam bottoming cycles with heat exchanger and heat recovery steam generator: Energy and exergy analysis. Energy Reports, 4:497–506, 2018. doi: 10.1016/j.egyr.2018.07.007.
[38] M.N. Khan and I. Tlili. Performance enhancement of a combined cycle using heat exchanger bypass control: A thermodynamic investigation. Journal of Cleaner Production, 192:443–452, 2018. doi: 10.1016/j.jclepro.2018.04.272.
[39] M. Korobitsyn. Industrial applications of the air bottoming cycle. Energy Conversion and Management, 43(9-12):1311–1322, 2002. doi: 10.1016/S0196-8904(02)00017-1.
[40] T.K. Ibrahim and M.M. Rahman. optimum performance improvements of the combined cycle based on an intercooler–reheated gas turbine. Journal of Energy Resources Technology, 137(6):061601, 2015. doi: 10.1115/1.4030447.
Go to article

Authors and Affiliations

Mohammad N. Khan
1
ORCID: ORCID
Dhare Alzafiri
1
ORCID: ORCID
  1. Department of Mechanical Engineering, College of Engineering, Majmaah University, Al-Majmaah, Saudi Arabia

Application of mixed-nanoparticle coating as a novel simple method in generating speckle pattern to study small fields of view by digital image correlation

Milad Zolfipour Aghdam Naser Soltani Hadi Nobakhti
Archive of Mechanical Engineering | 2022 | vol. 69 | No 1 | 45-58 | DOI: 10.24425/ame.2021.139313
Keywords digital image correlation speckle pattern nanoparticle coating
Download PDF Download RIS Download Bibtex

Abstract

Digital image correlation (DIC) is a powerful full-field displacement measurement technique that has been used in various studies. The first step in the DIC is to create a random speckle pattern, where the spraying method is usually employed. However, creating an optimal pattern and modification in the spraying method is not convenient. Furthermore, the size of speckles which is not so small in spraying method, limits the minimum size of the field of study. In the present research, a convenient novel technique was introduced and investigated to generate a practical kind of speckle pattern with small speckles for evaluating smaller fields of view using nanoparticles. The pattern was created by spreading a mixture of different black and white nanoparticles. To this end, the black graphene oxide particles were mixed with white nanoparticles of titanium oxide, zirconium oxide and silicon to obtain three mixtures. Displacement tests show that the mixture of graphene and titanium provides the best DIC performance. More granularly, graphene and titanium were mixed at three different ratios to find the optimal combination. Subsequently, the accuracy of the new patterning method was analyzed via tensile testing and the results were compared against those of conventional method with various subset sizes.
Go to article

Bibliography

[1] M. Abshirini, N. Soltani, and P. Marashizadeh. On the mode I fracture analysis of cracked Brazilian disc using a digital image correlation method. Optics and Lasers in Engineering, 78:99–105, 2016. doi: 10.1016/j.optlaseng.2015.10.006.
[2] M. Sahlabadi and N. Soltani. Experimental and numerical investigations of mixed-mode ductile fracture in high-density polyethylene. Archive of Applied Mechanics, 88(6):933–942, 2018. doi: 10.1007/s00419-018-1350-5.
[3] M.R.Y. Dehnavi, I. Eshraghi, and N. Soltani. Investigation of fracture parameters of edge Vnotches in a polymer material using digital image correlation. Polymer Testing, 32(4):778–784, 2013. doi: 10.1016/j.polymertesting.2013.03.012.
[4] N.S. Ha, V.T. Le, and S.G. Goo. Investigation of fracture properties of a piezoelectric stack actuator using the digital image correlation technique. International Journal of Fatigue, 101(1):106–111, 2017. doi: 10.1016/j.ijfatigue.2017.02.020.
[5] B. Pan. Digital image correlation for surface deformation measurement: historical developments, recent advances and future goals. Measurement Science and Technology, 29(8):082001, 2018. doi: 10.1088/1361-6501/aac55b.
[6] Y.L. Dong and B. Pan. A review of speckle pattern fabrication and assessment for digital image correlation. Experimental Mechanics, 57(8):1161–1181, 2017. doi: 10.1007/s11340-017-0283-1.
[7] N.S. Ha, T.L. Jin, N.S. Goo, and H.C. Park. Anisotropy and non-homogeneity of an Allomyrina Dichotoma beetle hind wing membrane. Bioinspiration and Biomimetics, 6(4):046003, 2011. doi: 10.1088/1748-3182/6/4/046003.
[8] T. Jin,N.S. Ha,V.T. Le,N.S. Goo, and H.C. Jeon. Thermal buckling measurement of a laminated composite plate under a uniform temperature distribution using the digital image correlation method. Composite Structures, 123:420–429, 2015. doi: 10.1016/j.compstruct.2014.12.025.
[9] T.L. Jin,N.S. Ha, andN.S. Goo.Astudy of the thermal buckling behavior of a circular aluminum plate using the digital image correlation technique and finite element analysis. Thin-Walled Structures, 77:187–197, 2014. doi: 10.1016/j.tws.2013.10.012.
[10] N.S. Ha, V.T. Le, and N.S. Goo. Thermal strain measurement of austin stainless steel (SS304) during a heating-cooling process. International Journal of Aeronautical and Space Sciences, 18(2):206-214, 2017. doi: 10.5139/ijass.2017.18.2.206.
[11] N.S. Ha, H.M. Vang, andN.S. Goo. Modal analysis using digital image correlation technique: an application to artificial wing mimicking beetle’s hind wing. Experimental Mechanics, 55:989– 998, 2015. doi: 10.1007/s11340-015-9987-2.
[12] T. Sadowski and M. Knec. Application of DIC techniques for monitoring of deformation process of spr hybrid joints. Archives of Metallurgy and Materials, 58(1):119–125, 2013. doi: 10.2478/v10172-012-0161-x.
[13] W.H. Peters and W.F. Ranson. Digital imaging techniques in experimental stress analysis. Optical Engineering, 21(3):427–431, 1982. doi: 10.1117/12.7972925.
[14] W.H. Peters, W.F. Ranson, M.A. Sutton, T.C. Chu, and J. Anderson. Application of digital correlation methods to rigid body mechanics. Optical Engineering, 22(6):738–742, 1983. doi: 10.1117/12.7973231.
[15] M.A. Sutton, W.J. Wolters, W.H. Peters, W.F. Ranson, and S.R. McNeill. Determination of displacements using an improved digital correlation method. Image and Vision Computing, 1(3)133–139, 1983. doi: 10.1016/0262-8856(83)90064-1.
[16] T.C. Chu, W.F. Ranson, and M.A. Sutton. Applications of digital-image-correlation techniques to experimental mechanics. Experimental Mechanics, 25(3):232–244, 1985. doi: 10.1007/BF02325092.
[17] J.S. Lyons, J. Liu, and M.A. Sutton. High-temperature deformation measurements using digitalimage correlation. Experimental Mechanics, 36(1):64–70, 1996. doi: 10.1007/BF02328699.
[18] T.A. Berfield, J.K. Patel, R.G. Shimmin, P.V. Braun, J. Lambros, and N.R. Sottos. Micro- and nanoscale deformation measurement of surface and internal planes via digital image correlation. Experimental Mechanics, 47(1):51–62, 2007. doi: 10.1007/s11340-006-0531-2.
[19] Y. Dong, H. Kakisawa, and Y. Kagawa. Development of microscale pattern for digital image correlation up to 1400°C. Optics and Lasers in Engineering, 68:7–15, 2015. doi: 10.1016/j.optlaseng.2014.12.003.
[20] T. Niendorf, C. Burs, D. Canadinc, and H.J. Maier. Early detection of crack initiation sites in TiAl alloys during low-cycle fatigue at high temperatures utilizing digital image correlation. International Journal of Materials Research, 100(4):603–608, 2009. doi: 10.3139/146.110064.
[21] M.A. Sutton, X. Ke, S.M. Lessner, M. Goldbach, M. Yost, F. Zhao, and H.W. Schreier. Strain field measurements on mouse carotid arteries using microscopic three-dimensional digital image correlation. Journal of Biomedical Materials Research Part A, 84A(1):178–190, 2007. doi: 10.1002/jbm.a.31268.
[22] A.D. Kammers and S. Daly. Self-assembled nanoparticle surface patterning for improved digital image correlation in a scanning electron microscope. Experimental Mechanics, 53(8):1333–1341, 2013. doi: 10.1007/s11340-013-9734-5.
[23] K.N. Jonnalagadda, I. Chasiotis, S. Yagnamurthy, J. Lambros, J. Pulskamp, R. Polcawich, and M Dubey. Experimental investigation of strain rate dependence of nanocrystalline Pt films. Experimental Mechanics, 50(1):25–35, 2010. doi: 10.1007/s11340-008-9212-7.
[24] W.A. Scrivens, Y. Luo, M.A. Sutton, S.A. Collette, M.L. Myrick, P. Miney, P.E. Colavita, A.P. Reynolds, and X. Li. Development of patterns for digital image correlation measurements at reduced length scales. Experimental Mechanics, 47(1):63–77, 2007. doi: 10.1007/s11340-006-5869-y.
[25] N. Li, M.A. Sutton, X. Li, and H.W. Schreier. Full-field thermal deformation measurements in a scanning electron microscope by 2D digital image correlation. Experimental Mechanics, 48(5):635–646, 2008. doi: 10.1007/s11340-007-9107-z.
[26] F. Di Gioacchino and J.Q. da Fonseca. Plastic strain mapping with sub-micron resolution using digital image correlation. Experimental Mechanics, 53(5):743–754, 2013. doi: 10.1007/s11340-012-9685-2.
[27] P. Reu. All about speckles: contrast. Experimental Techniques, 39(1):1–2, 2015. doi: 10.1111/ext.12126.
[28] P. Reu. All about speckles: speckle density. Experimental Techniques, 39(3):1–2, 2015. doi: 10.1111/ext.12161.
[29] P. Reu. All about speckles: aliasing. Experimental Techniques, 38(5):1–3, 2014. doi: 10.1111/ext.12111.
[30] P. Reu. All about speckles: speckle size measurement. Experimental Techniques, 38(6):1–2, 2014. doi: 10.1111/ext.12110.
[31] B. Pan, H. Xie, Z. Wang, K. Qian, and Z. Wang. Study on subset size selection in digital image correlation for speckle patterns. Optics Express, 16(10):7037–7048, 2008. doi:
10.1364/OE.16.007037.
[32] B.Wang and B. Pan. Random errors in digital image correlation due to matched or overmatched shape functions. Experimental Mechanics, 55(9):1717–1727, 2015. doi: 10.1007/s11340-015- 0080-7.
[33] B. Pan, K. Qian, H. Xie, and A. Asundi. Two-dimensional digital image correlation for inplane displacement and strain measurement: a review. Measurement Science and Technology, 20(6):062001, 2009. doi: 10.1088/0957-0233/20/6/062001.
[34] H. Haddadi and S. Belhabib. Use of rigid-body motion for the investigation and estimation of the measurement errors related to digital image correlation technique. Optics and Lasers in Engineering, 46(2):185–196, 2007. doi: 10.1016/j.optlaseng.2007.05.008.
Go to article

Authors and Affiliations

Milad Zolfipour Aghdam
1
ORCID: ORCID
Naser Soltani
1
Hadi Nobakhti
1
  1. School of Mechanical Engineering, Collegeof Engineering, University of Tehran, Iran

Study on modeling and production inaccuracies for artillery firing

Mostafa Khalil
Archive of Mechanical Engineering | 2022 | vol. 69 | No 1 | 165-183 | DOI: 10.24425/ame.2021.139802
Keywords artillery firing table modified point mass meteorological messages Coriolis effect genetic algorithm GA
Download PDF Download RIS Download Bibtex

Abstract

Production and assessment of artillery firing tables (FT) are the key tasks in solving ballistic problems through both standard and non-standard firing conditions. According to the literature, two different standard firing table formats were developed by the former-Soviet and the United States armies. This study proposes the main difference between these FT formats, as the standard meteorological conditions. An accuracy assessment has been proposed to justify different sources of errors through modeling and production of such tables, including applied meteorological message, aiming angles round-off, linear superposition principle, and Earth approximation. A~case study has been proposed for the 155M107 projectile to demonstrate the impact of the Coriolis effect as well as other ballistic and atmospheric non-standard conditions. As a part of the construction of artillery FT, a fitting process has to be made between available firing data and simulations. Therefore, a parametric study is implemented to study the number of test elevations per charge needed through the fitting process and its corresponding production error. Hence, based on the number of test elevations available, the genetic algorithm (GA) has been utilized to obtain the test elevations order needed with minimum FT production error. The results show a good agreement with the data stated in the literature.
Go to article

Bibliography

[1] J.A. Matts and D.H. McCoy. A graphical firing table model and a comparison of the accuracy of three utilization schemes. Report No. BRL-MR-2035, Army Ballistic Research Lab., Aberdeen Proving Ground, MD, U.S., April 1970.
[2] H.L. Reed Jr. Firing table computations on the ENIAC. In Proceeding of the 1952 ACM national meeting (Pittsburgh), pages 103-106, Pennsylvania, USA, 2 May, 1952. doi: 10.1145/609784.609796.
[3] E.R. Dickinson. The production of firing tables for cannon artillery. Report No. BRL-R-1371, Army Ballistic Research Lab., Aberdeen Proving Ground, MD, U.S., November 1967.
[4] S. Gorn and N.L. Juncosa. On the computational procedures for firing and bombing tables. Report No. BRL-R-889, Army Ballistic Research Lab., Aberdeen Proving Ground, MD, U.S., November 1954.
[5] C. Niekerk, and W. Rossouw. A proposed format for firing tables of a series of carrier projectiles possessing ballistic similarity with a HE projectile. In Proceeding of the 20th International Symposium on Ballistics, pages 187–194, Orlando, USA, 23–27 September, 2002.
[6] S.A. Ortac, U. Durak, U. Kutluay, K. Kucuk, and M.C. Candan. NABK based next generation ballistic table toolkit. In Proceeding of the 23rd International Symposium on Ballistics, pages 765–774, Tarragona, Spain, 16–20 April, 2007.
[7] A.J. Sowa. NATO shareable software developing into true suite supporting national operational fire control systems. In Proceeding of the 24th International Symposium on Ballistics, pages 126–133, Louisiana, USA, 22–26 September, 2008.
[8] Z. Leciejewski, T. Zawada, P. Kowalczuk, J. Szymonik, and P. Czyronis. Selected ballistic aspects of fire control system designed to anti-aircraft gun. In Proceeding of the 28th International Symposium on Ballistics, pages 655–665, Atlanta, USA, 22–26 September, 2014.
[9] NATO. The Modified Point Mass and five Degrees of Freedom Trajectory Models. Standard No. STANAG-4355, NATO Standardization Agency, Belgium, April 2009.
[10] M. Khalil, X. Rui, Q. Zha, H. Yu, and H. Hendy. Projectile impact point prediction based on self-propelled artillery dynamics and doppler radar measurements. Advances in Mechanical Engineering, 2013:53913, 2013. doi: 10.1155/2013/153913.
[11] L. Baranowski. Feasibility analysis of the modified point mass trajectory model for the need of ground artillery fire control systems. Journal of Theoretical and Applied Mechanics, 51(3):511–522, 2013.
[12] M. Khalil, X. Rui, and H. Hendy. Discrete time transfer matrix method for projectile trajectory prediction. Journal of Aerospace Engineering, 28(2):04014057, 2015. doi: 10.1061/(ASCE)AS.1943- 5525.0000381.
[13] L. Baranowski. Effect of the mathematical model and integration step on the accuracy of the results of computation of artillery projectile flight parameters. Bulletin of the Polish Academy of Sciences: Technical Sciences, 61(2):475–484, 2013. doi: 10.2478/bpasts-2013-0047.
[14] A. Szklarski, R. Głębocki, and M. Jacewicz. Impact point prediction guidance parametric study for 155 mm rocket assisted artillery projectile with lateral thrusters. Archive of Mechanical Engineering, 67(1):31–56, 2020. doi: 10.24425/ame.2020.131682.
[15] M. Aldoegre. Comparison Between Trajectory Models for Firing Table Application. MSc. Thesis, North-West University, Potchefstroom, South Africa, 2019.
[16] C. Donneaud, R. Cayzac and P. Champigny. Recent developments on aeroballistics of yawing and spinning projectiles: Part II: free flight tests. In Proceeding of the 20th International Symposium on Ballistics, pages 655–665, Orlando, USA, 23–27 September, 2002.
[17] A. Dupuis, C. Berner, and V. Fleck. Aerodynamic characteristics of a long-range spinning artillery shell: Part 1: from aeroballistic range free-flight tests. In Proceeding of the 21st International Symposium on Ballistics, Adelaide, Australia, 19–23 April, 2004.
[18] T. Brown, T. Harkins, M. Don, R. Hall, J. Garner, and B. Davis. Development and demonstration of a new capability for aerodynamic characterization of medium caliber projectiles. In Proceedings of the 28th International Symposium on Ballistics, pages 655–665, Atlanta, USA, 22–26 September, 2014.
[19] W. Zhou. An improved hybrid extended kalman filter based drag coefficient estimation for projectiles. In Proceedings of the 30th International Symposium on Ballistics, pages 80–91, California, USA, 11–15 September, 2017.
[20] M. Albisser, S. Dobre, C. Decrocq, F. Saada, B. Martinez, and P. Gnemmi. Aerodynamic characterization of a new concept of long range projectiles from free flight data. In Proceeding of the 30th International Symposium on Ballistics, pages 256–267, California, USA, 11–15 September, 2017.
[21] A. Ishchenko, V. Burkin, V. Faraponov, L. Korolkov, E. Maslov, A. Diachkovskiy, A. Chupashev, and A. Zykova. Determination of extra trajectory parameters of projectile layout motion. Journal of Physics: Conference Series, 919:012010, 2017, 1-5. doi: 10.1088/1742-6596/919/1/012010.
[22] G. Surdu, I. Vedinaş, G. Slămnoiu, and Ş. Pamfil. Projectile’s drag coefficient evaluation for small finite differences of his geometrical dimensions using analytical methods. In: International Conference of Scientific Paper (AFASES 2015), Brasov, Romania, 28–30 May, 2015.
[23] R.L. McCoy. Modern Exterior Ballistics: The Launch and Flight Dynamics of Symmetric Projectiles, 2nd ed., Schiffer Publishing, 2009.
[24] R. H. Whyte. SPIN-73 an Updated Version of the SPINNER Computer Program. Report No. TR-4588, Armament Systems Dept., VT, U.S., November 1973.
[25] W. Yingbin. The application of ballistic filtering theory in the production of firing tables. Journal of Ballistics, 7(1):65–70, 1995. (in Chinese)
[26] W. Liang, B. Jiang, and Y. Sa. The application of simple regression method in producing the curve of accommodation coefficient in test for firing table. Journal of of Shanxi Datong University (Natural Science Edition), 26(1):23–25, 2010. (in Chinese)
[27] C. Xinjun. A study of fitting method for making ground artillery firing tables. Journal of Ballistics, 9(2):76–79, 1997. (in Chinese)
[28] W.-Q. Huang. A series of base functions for global analytical approach to firing table. Applied Mathematics and Mechanics, 2(5):575–579, 1981. doi: 10.1007/bf01895460.
[29] N.P. Roberts. Ballistic analysis of firing table data for 155mm, M825 smoke projectile. Report No. BRL-MR-3865, Army Ballistic Research Lab., Aberdeen Proving Ground, MD, U.S., September 1990.
[30] S. Wu, Q. Kang, L. Fu, and X. Jinxiang. A study on comparing test and its application on the firing table design. Journal of Ballistics, 15(4):22–26, 2003. (in Chinese)
[31] S. Floroff and B. Salatino. 120-MM Ammunition Feasibility Assessment for Light Artillery. Report No. ARFSD TR 99002, U.S Army Armament Reseach, Development and Engineering Center, NJ, USA, March 2000.
[32] D.L. Johnson, B.C. Roberts, and W.W. Vaughan. Reference and standard atmosphere models. In Proceedings of the 10th Conference on Aviation, Range and Aerospace Meteorology, Boston, USA, 13–16 May, 2002.
[33] V. Cech and J. Jevicky. Improved theory of generalized meteo-ballistic weighting factor functions and their use. Defence Technology, 12(3):242–254, 2016. doi: 10.1016/j.dt.2016.01.009.
[34] V. Cech and J. Jevicky. Improved theory of projectile trajectory reference heights as characteristics of meteo-ballistic sensitivity functions. Defence Technology, 13(3):177–187, 2017. doi: 10.1016/j.dt.2017.04.001.
[35] G.E. Wood. Test Design Plan (TDP) for the Production Qualification Testing (PQT) of the 81mm M984/M983 High Explosive (HE) Cartridges. Report No. AD-A257 403, U.S Army Materiel Systems Analysis Activity, Aberdeen Proving Ground, MD, U.S., October 1992.
[36] W. Haifeng, W. Pengxin, W. Long, and D. Lijie. Discussion on the revision of artillery standard firing conditions of our army. Journal of Projectiles, Rockets, Missiles and Guidance, 37(4):153–156, 2017. (in Chinese)
[37] FT-122-2A18: Firing Tables for Cannon, 122mm Howitzer, 2A18. Former Soviet Union, 1968.
[38] S. Karel and B. Martin. Conversions of METB3 meteorological messages into the METEO11 format. In Proceedings of the 2017 International Conference on Military Technologies (ICMT), pages 278-284, Brno, Czech Republic, 31 May - 2 Jun, 2017. doi: 10.1109/MILTECHS.2017.7988770.
[39] FT-155-AM-2: Firing Tables for Cannon, 155mm Howitzer, M185. US Department of the Army, 1983.
[40] Manual of the ICAO Standard Atmosphere: Extended to 80 Kilometres. International Civil Aviation Organization, 1993.
[41] K. Šilinger, L. Potužák, and J. Šotnar. Conversion of the METCM into the METEO-11. In Proceedings of the 13th International Conference on Instrumentation, Measurement, Circuits And Systems (IMCAS '14), pages 212–218, Istanbul, Turkey, 15–17 December, 2014.
[42] Š. Karel, I. Jan, and P. Ladislav. Composition of the METEO11 meteorological message according to abstract of a measured meteorological data. In Proceedings of the 2017 International Conference on Military Technologies (ICMT), pages 194–199, Brno, Czech Republic, 31 May - 2 Jun, 2017. doi: 10.1109/MILTECHS.2017.7988755.
[43] NATO. Adoption of Standard Ballistic Meteorological Message. Standard No. STANAG 4061, NATO Standardization Agency, Belgium, October 2000.
[44] B. Karpov and L. Schmidt. The Aerodynamic Properties of the 155-mm Shell M101 from Free flight Range Tests of Full Scale and 1/12 Scale Models. Report No. BRL-MR-1582, Army Ballistic Research Lab., Aberdeen Proving Ground, MD, U.S., June 1964.
[45] M. Khalil, H. Abdalla, and O. Kamal. Dispersion analysis for spinning artillery projectile. In Proceeding of the 13th International Conference on Aerospace Sciences and Aviation Technology, pages 1-12, Cairo, Egypt, 26–28 May, 2009. doi: 10.21608/asat.2009.23740.
Go to article

Authors and Affiliations

Mostafa Khalil
1
ORCID: ORCID
  1. Aerospace Engineering Department, Military Technical College, Cairo, Egypt

Measurement and evaluation of delamination factors and thrust force generation during drilling of multiwall carbon nanotube (MWCNT) modified polymer laminates

Kuldeep Kumar Rajesh Kumar Verma
Archive of Mechanical Engineering | 2022 | vol. 69 | No 2 | 269-300 | DOI: 10.24425/ame.2022.140417
Keywords drilling glass fiber MWCNT delamination thrust
Download PDF Download RIS Download Bibtex

Abstract

In recent years, manufacturing industries have demanded high-performance materials for structural components development due to their reduced weight, improved strength, corrosion, and moisture resistance. The outstanding performance of polymer nano-composites substitutes the use of conventional composites materials. This study is concerned with the machining of MWCNT and glass fiber-modified epoxy composites prepared by a cost-effective hand layup procedure. The investigations were carried out to estimate the generation of the thrust force (Th) and delamination factors at entry (DF entry) and exit (DF exit) side during the drilling of fiber composites. The effect of varying constraints on the machining indices was explored for obtaining an adequate quality of hole created in the epoxy nano-composites. The outcome shows that the feed rate (F) is the most critical factor influencing delamination at both entry and exit side, and the second one is the thrust force followed by wt. % of MWCNT. The statistical study shows that optimal combination of S (1650 Level-2), F (165 Level-2), and 2 wt. % of MWCNT (Level-2) can be used to minimize DF entry, DF exit, and Th. The drilling-induced damages were studied by means of a high-resolution microscopy test. The results reveal that the supplement of MWCNT substantially increases the machining efficiency of the developed nano-composites.
Go to article

Bibliography

[1] J. Du, H. Zhang, Y. Geng, W. Ming, W. He, J. Ma, Y. Cao, X. Li, and K. Liu. A review on machining of carbon fiber reinforced ceramic matrix composites. Ceramics International, 45(15):18155–18166, 2019. doi: 10.1016/j.ceramint.2019.06.112.
[2] N.R.M. Akmam, M. Mullah, and M.Z. Zakaria. Study on tool wear mechanism during milling of JFRP composite. International Journal of Science and Engineering Investigations, 9(98):20–26, 2020.
[3] D. Geng, Y. Liu, Z. Shao, Z. Lu, J. Cai, X. Li, X. Jiang, and D. Zhang. Delamination formation, evaluation and suppression during drilling of composite laminates: A review. Composite Structures, 216:168–186, 2019. doi: 10.1016/j.compstruct.2019.02.099.
[4] G. Rajaraman, S.K. Agasti, and M.P. Jenarthanan. Investigation on effect of process parameters on delamination during drilling of kenaf-banana fiber reinforced in epoxy hybrid composite using Taguchi method. Polymer Composites, 41(3):994–1002, 2020. doi: 10.1002/pc.25431.
[5] M. Ramesh and A. Gopinath. Measurement and analysis of thrust force in drilling sisal-glass fiber reinforced polymer composites. IOP Conference Series: Materials Science and Enginierring, 197:012056, 2017. doi: 0.1088/1757-899X/197/1/012056.
[6] U.H. Babu, N.V. Sai, and R.K. Sahu. Artificial intelligence system approach for optimization of drilling parameters of glass-carbon fiber/polymer composites. Silicon, 13:2943–2957, 2021. doi: 10.1007/s12633-020-00637-5.
[7] W. Li, A. Dichiara, and J. Bai. Carbon nanotube-graphene nanoplatelet hybrids as high-performance multifunctional reinforcements in epoxy composites. Composites Science and Technology, 74:221–227, 2013. doi: 10.1016/j.compscitech.2012.11.015.
[8] S.G. Ghalme, Y. Bhalerao, and K. Phapale. Analysis of factors affecting delamination in drilling GFRP composite. Journal of Computational and Applied Research in Mechanical Engineering, 10(2):281–289, 2021. doi: 10.22061/jcarme.2019.4397.1530.
[9] S. Manteghi, A. Sarwar, Z. Fawaz, R. Zdero, and H. Bougherara. Mechanical characterization of the static and fatigue compressive properties of a new glass/flax/epoxy composite material using digital image correlation, thermographic stress analysis, and conventional mechanical testing. Materials Science and Engineering: C, 99:940–950, 2019. doi: 10.1016/j.msec.2019.02.041.
[10] J. Samuel, A. Dikshit, R.E. DeVor, S.G. Kapoor, and K.J. Hsia. Effect of carbon nanotube (CNT) loading on the thermomechanical properties and the machinability of CNT-reinforced polymer composites. Journal of Manufacturing Science and Engineering, 131(3):031008, 2009. doi: 10.1115/1.3123337.
[11] A. Babu Arumugam, V. Rajamohan, N. Bandaru, E.P. Sudhagar, and S.G. Kumbhar. Vibration analysis of a carbon nanotube reinforced uniform and tapered composite beams. Archives of Acoustics, 44(2):309–320. doi: .
[12] X. Wang, Q. Zheng, S. Dong, A. Ashour, and B. Han. Interfacial characteristics of nano-engineered concrete composites. Construction and Building Matererials, 259:119803, 2020. doi: 10.1016/j.conbuildmat.2020.119803.
[13] A.K. Chakraborty, T. Plyhm, M. Barbezat, A. Necola, and G.P. Terrasi. Carbon nanotube (CNT)-epoxy nanocomposites: A systematic investigation of CNT dispersion. Journal of Nanoparticle Research, 13:6493–6506, 2011. doi: 10.1007/s11051-011-0552-3.
[14] D.K. Rathore, R.K. Prusty, D.S. Kumar, and B.C. Ray. Mechanical performance of CNT-filled glass fiber/epoxy composite in in-situ elevated temperature environments emphasizing the role of CNT content. Composites Part A: Applied Science and Manufacturing, 84:364–376, 2016. doi: 10.1016/j.compositesa.2016.02.020.
[15] L. Sun, Y. Zhao, Y. Duan , and Z. Zhang. Interlaminar shear property of modified glass fiber-reinforced polymer with different MWCNTs. Chinese Journal of Aeronautics, 21(4):361–369, 2008. doi: 10.1016/S1000-9361(08)60047-3.
[16] A. Esmaeili, C. Sbarufatti, andA.M.S. Hamouda. Investigation of mechanical properties of MWCNTs doped epoxy nanocomposites in tensile, fracture and impact tests. Materials Science Forum, 990:239–243, 2020. doi: 10.4028/www.scientific.net/msf.990.239.
[17] A. Tabatabaeian and A.R. Ghasemi. The impact of MWCNT modification on the structural performance of polymeric composite profiles. Polymer Bulletin, 77:6563–6576, 2020. doi: 10.1007/s00289-019-03088-0.
[18] A. Gaurav and K.K. Singh. Effect of pristine MWCNTs on the fatigue life of GFRP laminates-an experimental and statistical evaluation. Composites Part B: Engineering, 172:83–96, 2019. doi: 10.1016/j.compositesb.2019.05.069.
[19] B. Shivamurthy, S. Anandhan, K.U. Bhat, and B.H.S. Thimmappa. Structure-property relationship of glass fabric/MWCNT/epoxy multi-layered laminates. Composites Communications, 22:100460, 2020. doi: 10.1016/j.coco.2020.100460.
[20] A. Uysal. Evaluation of drilling parameters on surface roughness and burr when drilling carbon black reinforced high-density polyethylene. Journal of Composite Materials, 52(20):2719–2727, 2018. doi: 10.1177/0021998317752505.
[21] F. Susac and F. Stan. Experimental investigation, modeling and optimization of circularity, cylindricity and surface roughness in drilling of PMMA using ANN and ANOVA. Materiale Plastice, 57(1):57–68, 2020. doi: 10.37358/MP.20.1.5312.
[22] P. Czarnocki and T. Zagrajek. Growth stability analysis of embedded delaminations with the use of FE node relocation procedure and effective resistance curve concept. Archive of Mechanical Engineering, 67(4):415–433, 2020. doi: 10.24425/ame.2020.131702.
[23] L. Liu, C. Qi, F. Wu, X. Zhang, and X. Zhu. Analysis of thrust force and delamination in drilling GFRP composites with candle stick drills. The International Journal of Advanced Manufacturing Technology, 95:2585–2600, 2018. doi: 10.1007/s00170-017-1369-8.
[24] M.P. Jenarthanan and R. Jeyapaul. Optimisation of machining parameters on milling of GFRP composites by desirability function analysis using Taguchi method. International Journal of Engineering, Science and Technology, 5(4):23–36. doi: 10.4314/ijest.v5i4.3.
[25] P. Raveendran and P. Marimuthu. Multi-response optimization of turning parameters for machining glass fiber-reinforced plastic composite rod. Advances in Mechanical Engineering, 7:1–10, 2015. doi: 10.1177/1687814015620109.
[26] D.I. Poór, N. Geier, C. Pereszlai, and J. Xu. A critical review of the drilling of CFRP composites: Burr formation, characterisation and challenges. Composites Part B: Engineering, 223:109155, 2021. doi: 10.1016/j.compositesb.2021.109155.
[27] R. Higuchi, S. Warabi, W. Ishibashi, and T. Okabe. Experimental and numerical investigations on push-out delamination in drilling of composite laminates. Composites Science and Technology, 198:108238, 2020. doi: 10.1016/j.compscitech.2020.108238.
[28] J. Kumar, R.K. Verma, and A.K. Mondal. Predictive modeling and machining performance optimization during drilling of polymer nanocomposites reinforced by graphene oxide/carbon fiber. Archive of Mechanical Engineering, 67(2):229–258. doi: 10.24425/ame.2020.131692.
[29] N. Hoffmann, G.S.C. Souza, A.J. Souza, and V. Tita. Delamination and hole wall roughness evaluation in air-cooled drilling of carbon fiber-reinforced polymer. Journal of Composite Materials, 55(23):3161–3174, 2021. doi: 10.1177/00219983211009281.
[30] A.T. Erturk, F. Vatansever, E. Yarar, E.A. Guven, and T. Sinmazcelik. Effects of cutting temperature and process optimization in drilling of GFRP composites. Journal of Composite Materials, 55(2):235–249, 2021. doi: 10.1177/0021998320947143.
[31] R. Pramod, S. Basavarajappa, G.B. Veeresh Kumar, and M. Chavali. Drilling induced delamination assessment of nanoparticles reinforced polymer matrix composites. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2021. doi: 10.1177/09544062211030967.
[32] P.K. Kharwar, R.K. Verma, N.K. Mandal, and A.K. Mondal. Swarm intelligence integrated approach for experimental investigation in milling of multiwall carbon nanotube/polymer nanocomposites. Archive of Mechanical Engineering, 67(3):353–376, 2020. doi: 10.24425/ame.2020.131698.
[33] S. Gokulkumar, P.R. Thyla, R. ArunRamnath, and N. Karthi. Acoustical analysis and drilling process optimization of Camellia Sinensis / Ananas Comosus / GFRP / Epoxy composites by TOPSIS for indoor applications. Journal of Natural Fibers, 18(12):2284–2301. doi: 10.1080/15440478.2020.1726240.
[34] S. Liu, T. Yang, C. Liu, Y. Jin, D. Sun, and Y. Shen. Modelling and experimental validation on drilling delamination of aramid fiber reinforced plastic composites. Composite Structures, 236:111907, 2020. doi: 10.1016/j.compstruct.2020.111907.
[35] U. Bhushi, J. Suthar, and S.N. Teli. Performance analysis of metaheuristics optimization techniques for drilling process on CFRP composites. Materials Today: Proceedings, 28(2):1106–1114, 2020. doi: 10.1016/j.matpr.2020.01.091.
[36] A. Janakiraman, S. Pemmasani, S. Sheth, C. Kannan, and A.S.S. Balan. Experimental investigation and parametric optimization on hole quality assessment during drilling of CFRP/GFRP/Al stacks. Journal of The Institution of Engineers (India): Series C, 101:291–302, 2020. doi: 10.1007/s40032-020-00563-w.
[37] M. Mudhukrishnan, P. Hariharan, and K. Palanikumar. Measurement and analysis of thrust force and delamination in drilling glass fiber reinforced polypropylene composites using different drills. Measurement, 149:106973, 2020. doi: 10.1016/j.measurement.2019.106973.
[38] B.-C. Kwon, N.D.D. Mai, E.S. Cheon, and S.L. Ko. Development of a step drill for minimization of delamination and uncut in drilling carbon fiber reinforced plastics (CFRP). The International Journal of Advanced Manufacturing Technology , 106:1291–1301, 2020. doi: 10.1007/s00170-019-04423-5.
[39] T. Panneerselvam, S. Raghuraman, T.K. Kandavel, and K. Mahalingam. Evaluation and analysis of delamination during drilling on Sisal-Glass Fibres Reinforced Polymer. Measurement, 154:107462, 2020. doi: 10.1016/j.measurement.2019.107462.
[40] A. Landesmann, C.A. Seruti, and E. de Miranda Batista. Mechanical properties of glass fiber reinforced polymers members for structural applications. Materials Research, 18(6):1372–1383, 2015. doi: 10.1590/1516-1439.044615.
[41] K. Askaripour and A. Zak. A survey of scrutinizing delaminated composites via various categories of sensing apparatus. Journal of Composites Science, 3(4):95, 2019 doi: 10.3390/jcs3040095.
[42] M.R. Sanjay and B. Yogesha. Studies on natural/glass fiber reinforced polymer hybrid composites: An evolution. Materials Today: Proceedings, 4(2):2739–2747, 2017. doi: 10.1016/j.matpr.2017.02.151.
[43] M.Y. Abdellah, M.S. Alsoufi, M.K. Hassan,H.A. Ghulman, and A.F. Mohamed. Extended finite element numerical analysis of scale effect in notched glass fiber reinforced epoxy composite. Archive of Mechanical Engineering, 62(2):217–236, 2015. doi: 10.1515/meceng-2015-0013.
[44] K. Rodsin, Q. Hussain, P. Joyklad, A. Nawaz, and H. Fazliani. Seismic strengthening of nonductile bridge piers using low-cost glass fiber polymers. B Bulletin of the Polish Academy of Sciences: Technical Sciences, 68(6):1457–1470, 2020. doi: 10.24425/bpasts.2020.135383.
[45] R. Bielawski, M. Kowalik, K. Suprynowicz, R. Rządkowski,and P. Pyrzanowski. Experimental study on the riveted joints in glass fibre reinforced plastics (GFRP). Archive of Mechanical Engineering, 64(3):301–313, 2017. doi: 10.1515/meceng-2017-0018.
[46] N. Rasana, K. Jayanarayanan, B.D.S. Deeraj, and K. Joseph. The thermal degradation and dynamic mechanical properties modeling of MWCNT/glass fiber multiscale filler reinforced polypropylene composites. Composites Science and Technology, 169:249–259, 2019. doi: 10.1016/j.compscitech.2018.11.027.
[47] A.D. Dobrzańska-Danikiewicz, D. Łukowiec, D. Cichocki, and W. Wolany. Comparison of the MWCNTs-Rh and MWCNTs-Re carbon-metal nanocomposites obtained in hightemperature. Archives of Metallurgy and Materials, 60(3):2053–2060, 2015. doi: 10.1515/amm-2015-0348.
[48] Ö Demircan, K. Kadıoğlu, P. Çolak, E. Günaydın, M. Doğu, N. Topalömer, and V. Eskizeybekl. Compression after impact and Charpy impact characterizations of glass fiber/epoxy/MWCNT composites. Fibers and Polymers, 21(8):1824–1831, 2020. doi: 10.1007/s12221-020-9921-9.
[49] P.K. Kharwar and R.K. Verma. Machining performance optimization in drilling of multiwall carbon nano tube /epoxy nanocomposites using GRA-PCA hybrid approach. Measurement, 158:107701, 2020. doi: 10.1016/j.measurement.2020.107701.
[50] C.R.Raajeshkrishna, P. Chandramohan, and V.S. Saravanan. Thermomechanical characterization and morphological analysis of nano basalt reinforced epoxy nanocomposites. International Journal of Polymer Analysis and Characterization, 25(4):216–226, 2020. doi: 10.1080/1023666X.2020.1781479.
[51] K.M. Tripathi, A. Sachan, M. Castro, V. Choudhary, S.K. Sonkar, and J.F. FellerF. Green carbon nanostructured quantum resistive sensors to detect volatile biomarkers. Sustainable Materials and Technologies, 16:1–11, 2018. doi: 10.1016/j.susmat.2018.01.001.
[52] P. Rawat and K.K. Singh. A strategy for enhancing shear strength and bending strength of FRP laminate using MWCNTs. IOP Conference Series: Materials Science and Engineering, 149:012105, 2015. doi: 10.1088/1757-899X/149/1/012105.
[53] S. Yeasmin, J.H. Yeum, and S.B Yang. Fabrication and characterization of pullulan-based nanocomposites reinforced with montmorillonite and tempo cellulose nanofibril. Carbohydrate Polymers, 240:116307, 2020. doi: 10.1016/j.carbpol.2020.116307.
[54] K. Hosseinpour and A.R. Ghasemi. Agglomeration and aspect ratio effects on the long-term creep of carbon nanotubes/fiber/polymer composite cylindrical shells. Journal of Sandwich Structures & Materials, 23(4):1272–1291, 2021. doi: 10.1177/1099636219857200.
[55] A.R. Ghasemi, M. Mohandes, R. Dimitri, and F. Tornabene. Agglomeration effects on the vibrations of CNTs/fiber/polymer/metal hybrid laminates cylindrical shell. Composites Part B: Engineering, 167:700–716, 2019. doi: 10.1016/j.compositesb.2019.03.028.
[56] G.C. Onwubolu and S. Kumar. Response surface methodology-based approach to CNC drilling operations. Journal of Materials Processing Technology, 171(1):41–47, 2006. doi: 10.1016/j.jmatprotec.2005.06.064.
[57] E. Kilickap, M. Huseyinoglu, and A. Yardimeden. Optimization of drilling parameters on surface roughness in drilling of AISI 1045 using response surface methodology and genetic algorithm. The International Journal of Advanced Manufacturing Technology, 52:79–88, 2011. doi: 10.1007/s00170-010-2710-7.
[58] C.C. Tsao. Comparison between response surface methodology and radial basis function network for core-center drill in drilling composite materials. The International Journal of Advanced Manufacturing Technology, 37:1061–1068, 2008. doi: 10.1007/s00170-007-1057-1.
[59] E. Kilickap. Modeling and optimization of burr height in drilling of Al-7075 using Taguchi method and response surface methodology. The International Journal of Advanced Manufacturing Technology, 49:911–923, 2010. doi: 10.1007/s00170-009-2469-x.
[60] A. Ramaswamy and A.V. Perumal. Multi-objective optimization of drilling EDM process parameters of LM13 Al alloy–10ZrB$_2$–5TiC hybrid composite using RSM. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 42:432, 2020. doi: 10.1007/s40430-020-02518-9.
[61] K.K. Panchagnula and K. Palaniyandi. Drilling on fiber reinforced polymer/nanopolymer composite laminates: A review. Journal of Materials Research and Technology, 7(2):180–189, 2018. doi: 10.1016/j.jmrt.2017.06.003.
[62] D. Kumar and K.K. Singh. An experimental investigation of surface roughness in the drilling of MWCNT doped carbon/epoxy polymeric composite material. IOP Conference Series: Materials Science and Engineering, 149:012096, 2016. doi: 10.1088/1757-899X/149/1/012096.
[63] M. Mudegowdar. Influence of cutting parameters during drilling of filled glass fabric-reinforced epoxy composites. Science and Engineering of Composite Materials, 22(1):81–88, 2013. doi: 10.1515/secm-2013-0198.
[64] Ş Bayraktar and Y. Turgut. Determination of delamination in drilling of carbon fiber reinforced carbon matrix composites/Al 6013-T651 stacks. Measurement, 154:107493, 2020. doi: 10.1016/j.measurement.2020.107493.
[65] K.M. John and T.S. Kumaran. Backup support technique towards damage-free drilling of composite materials: A review. International Journal of Lightweight Materials and Manufacture, 3(4):357–364, 2020. doi: 10.1016/j.ijlmm.2020.06.001.
[66] L.M.P. Durão, J.M.R.S. Tavares, V.H.C. De Albuquerque, J.F.S. Marques, and O.N.G. Andrade. Drilling damage in composite material. Materials, 7(5):3802–3819, 2014. doi: 10.3390/ma7053802.
[67] B.R.N. Murthy, R. Beedu, R. Bhat, N. Naik, and P. Prabakar. Delamination assessment in drilling basalt/carbon fiber reinforced epoxy composite material. Journal of Materials Research and Technology, 9(4):7427–7433, 2020. doi: 10.1016/j.jmrt.2020.05.001.
[68] S.O. Ojo, S.O. Ismail, M. Paggi, and H.N. Dhakal. A new analytical critical thrust force model for delamination analysis of laminated composites during drilling operation. Composites Part B: Engineering, 124:207–217, 2017. doi: 10.1016/j.compositesb.2017.05.039.
[69] D. Wang, F. Jiao, and X. Mao. Mechanics of thrust force on chisel edge in carbon fiber reinforced polymer (CFRP) drilling based on bending failure theory. International Journal of Mechanical Sciences, 169:105336, 2020. doi: 10.1016/j.ijmecsci.2019.105336.
[70] N. Kaushik and S. Singhal. Hybrid combination of Taguchi-GRA-PCA for optimization of wear behavior in AA6063/SiC$_{\rm p}$ matrix composite. Production & Manufacturing Research , 6(1):171–189, 2018. doi: 10.1080/21693277.2018.1479666.
[71] K. Aslantas, E. Ekici, and A. Çiçek. Optimization of process parameters for micro milling of Ti-6Al-4V alloy using Taguchi-based gray relational analysis. Measurement, 128:419–427, 2018. doi: 10.1016/j.measurement.2018.06.066.
[72] S. Ragunath, C. Velmurugan, and T. Kannan. Optimization of drilling delamination behavior of GFRP/clay nano-composites using RSM and GRA methods. Fibers and Polymers, 18:2400–2409, 2017. doi: 10.1007/s12221-017-7420-4.
[73] P.M. Gopal and K. Soorya Prakash. Minimization of cutting force, temperature and surface roughness through GRA, TOPSIS and Taguchi techniques in end milling of Mg hybrid MMC. Measurement, 116:178–192, 2018. doi: 10.1016/j.measurement.2017.11.011.
[74] S.M. Shahabaz, N. Shetty, S.D. Shetty, and S.S. Sharma. Surface roughness analysis in the drilling of carbon fiber/epoxy composite laminates using hybrid Taguchi-Response experimental design. Materials Research Express, 7(1):015322, 2020. doi: 10.1088/2053-1591/ab6198.
[75] D. Kumar, K.K. Singh, and R. Zitoune. Experimental investigation of delamination and surface roughness in the drilling of GFRP composite material with different drills. Advanced Manufacturing: Polymer & Composites Science, 2(2):47–56, 2016. doi: 10.1080/20550340.2016.1187434.
[76] K. Palanikumar. Experimental investigation and optimisation in drilling of GFRP composites. Measurement, 44(10):2138–2148, 2011. doi: 10.1016/j.measurement.2011.07.023.
[77] B. Latha and V.S. Senthilkumar. Modeling and analysis of surface roughness parameters in drilling GFRP composites using fuzzy logic. Materials and Manufacturing Processes, 25(8):817-827, 2010. doi: 10.1080/10426910903447261.
[78] F. Ficici. Evaluation of surface roughness in drilling particle-reinforced composites. Advanced Composites Letters, 29:1–11, 2020. doi: 10.1177/2633366X20937711.
Go to article

Authors and Affiliations

Kuldeep Kumar
1
ORCID: ORCID
Rajesh Kumar Verma
1
ORCID: ORCID
  1. Materials and Morphology Laboratory, Department of Mechanical Engineering, Madan Mohan Malaviya University of Technology, Gorakhpur, India

This page uses 'cookies'. Learn more