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Investigation of The Effect of Mechanical Vibration Applied During Solidification on The Microstructure and Properties of Aluminum 356 Alloy

Taha Süreyya Özgü Recep Çalın Naci Arda Tanış
Archives of Foundry Engineering | 2024 | vol. 24 | No 1 | 26-31 | DOI: 10.24425/afe.2024.149248
Keywords Casting A356 Aluminum vibration
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Abstract

Manufacturing by casting method in aluminum and its alloys is preferred by different industries today. It may be necessary to improve the mechanical properties of the materials according to different industries and different strength requirements. The mechanical properties of metal alloys are directly related to the microstructure grain sizes. Therefore, many grain reduction methods are used during production or heat treatment. In this study, A356 alloys were molded into molds at 750 °C and exposed to vibration frequency at 0, 8.33, 16.66, 25, and 33.33 Hz during solidification. Optical microscopes images were analyzed in image analysis programs to measure the grain sizes of the samples that solidified after solidification. In addition, microhardness tests of samples were carried out to examine the effect of vibration and grain reduction on mechanical behavior. In the analyzes made, it was determined that the grain sizes decreased from 54.984 to 26.958 μm and the hardness values increased from 60.48 to 126.94 HV with increasing vibration frequency.
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Bibliography

[1] Mondolfo, L.F. (1979). Aluminium Alloys Structures and Properties. London: Butterworths, 806.
[2] Kocatepe, K. & Burdett, C.F. (2000) Effect of low frequency vibration on macro and micro structures of LM6 alloys. Journal of Materials Science, 35(13), 3327-3335. https://doi.org/10.1023/A:1004891809731.
[3] Schaffer, P.L. & Dahle, A.K. (2005). Settling behaviour of different grain refiners in aluminium. Materials Science and Engineering. A, 413, 373-378. https://doi.org/10.1016/j.msea.2005.08.202.
[4] Kumar, P.S., Abhilash, E., Joseph, M.A. (2010). Solidification under mechanical vibration: variation in metallurgical structure of gravity die cast A356 aluminium alloy. In International Conference on Frontiers in Mechanical Engineering (FIME), 20-22 May 2010 (pp. 140-146). India.
[5] Taghavi, F., Saghafian, H. & Kharrazi, Y.H. (2009). Study on the effect of prolonged mechanical vibration on the grain refinement and density of A356 aluminum alloy. Materials & Design. 30(5), 1604-1611. https://doi.org/10.1016/j.matdes.2008.07.032.
[6] Hernandez, F.R. & Sokolowski, J.H. (2006). Comparison among chemical and electromagnetic stirring and vibration melt treatments for Al–Si hypereutectic alloys. Journal of Alloys and Compounds. 426(1-2), 205-212. https://doi.org/10.1016/j.jallcom.2006.09.039.
[7] Jian, X., Meek, T.T. & Han, Q. (2006). Refinement of eutectic silicon phase of aluminum A356 alloy using high-intensity ultrasonic vibration. Scripta Materialia. 54(5), 893-896. https://doi.org/10.1016/j.scriptamat.2005.11.004.
[8] Chirita, G., Stefanescu, I., Soares, D. & Silva, F.S. (2009). Influence of vibration on the solidification behaviour and tensile properties of an Al–18 wt% Si alloy. Materials & Design. 30(5), 1575-1580. https://doi.org/10.1016/ j.matdes.2008.07.045.
[9] Promakhov, V.V., Khmeleva, M.G., Zhukov, I.A., Platov, V.V., Khrustalyov, A.P., & Vorozhtsov, A.B. (2019). Influence of vibration treatment and modification of A356 aluminum alloy on its structure and mechanical properties. Metals. 9(1), 87. https://doi.org/10.3390/met9010087.
[10] Selivorstov, V., Dotsenko, Y. & Borodianskiy, K. (2017). Influence of low-frequency vibration and modification on solidification and mechanical properties of Al-Si casting alloy. Materials. 10(5), 560. https://doi.org/10.3390/ma10050560.
[11] Yüksel, Ç. (2018). Titreşimli katilaştirmanin birincil ve ikincil Al7Si0, 3mg alüminyum alaşimlarinin içyapisina etkisi. Niğde Ömer Halisdemir Üniversitesi Mühendislik Bilimleri Dergisi. 7(2), 986-992.
[12] Sulaiman, S. & Zulkifli, Z.A. (2018). Effect of mould vibration on the mechanical properties of aluminium alloy castings. Advances in Materials and Processing Technologies. 4(2), 335-343. https://doi.org/10.1080/ 2374068X.2017.1421737.
[13] Y. Seetharama Rao, Rajana Vara Prasad, Sri Ram Murthy Paladugu (2019). Experimental investigations of microstructure and mechanical properties of aluminium alloy using vibration mold. Journal of Recent Activities in Production e-ISSN: 2581-9779. 4(2), 25-34.
[14] ASM International Handbook Committee. (1990). ASM Handbook, Volume 02 - Properties and Selection: Nonferrous Alloys and Special-Purpose Materials. ASM International.
[15] Kocatepe, K. (2007). Effect of low frequency vibration on porosity of LM25 and LM6 alloys. Materials & Design. 28(6), 1767-1775. https://doi.org/10.1016/ j.matdes.2006.05.004.
[16] Naik, S.N., & Walley, S.M. (2020). The Hall–Petch and inverse Hall–Petch relations and the hardness of nanocrystalline metals. Journal of Materials Science. 55(7), 2661-2681. https://doi.org/10.1007/s10853-019-04160-w.
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Authors and Affiliations

Taha Süreyya Özgü
1
ORCID: ORCID
Recep Çalın
1
ORCID: ORCID
Naci Arda Tanış
1
ORCID: ORCID
  1. Kırıkkale University, Turkey

Effect of Sr and Ti Addition on the Corrosion Behaviour of Al-7Si-0.3Mg Alloy

M. Uludağ M. Kocabaş D. Dışpınar R. Çetin N. Cansever
Archives of Foundry Engineering | 2017 | vol. 17 | No 2 | DOI: 10.1515/afe-2017-0063
Keywords A356 alloy Bifilm index Grain refinement Modification Electrochemical corrosion
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Abstract

In the present study, the corrosion behaviour of A356 (Al-7Si-0.3Mg) alloy in 3.5% NaCl solution has been evaluated using

cyclic/potentiodynamic polarization tests. The alloy was provided in the unmodified form and it was then modified with AlTi5B1 for grain

refinement and with AlSr15 for Si modifications. These modifications yield to better mechanical properties. Tensile tests were performed.

In addition, bifilm index and SDAS values were calculated and microstructure of the samples was investigated. As a result of the corrosion

test, the Ecorr values for all conditions were determined approximately equal, and the samples were pitted rapidly. The degassing of the

melt decreased the bifilm index (i.e. higher melt quality) and thereby the corrosion resistance was increased. The lowest corrosion rate was

founded at degassing and as-received condition (3.9x10-3 mm/year). However, additive elements do not show the effect which degassing

process shows.

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Authors and Affiliations

M. Uludağ
M. Kocabaş
D. Dışpınar
R. Çetin
N. Cansever

Observation of Hot Tearing in Sr-B Modified A356 Alloy

M. Uludağ R. Çetin D. Dışpınar
Archives of Foundry Engineering | 2017 | vol. 17 | No 4 | DOI: 10.1515/afe-2017-0151
Keywords A356 Casting Melt quality Grain refinement hot tearing
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Abstract

In this work, T-shaped mould design was used to generate hot spot and the effect of Sr and B on the hot tearing susceptibility of A356 was investigated. The die temperature was kept at 250o C and the pouring was carried out at 740o C. The amonut of Sr and B additions were 30 and 10 ppm, respectively. One of the most important defects that may exist in cast aluminium is the presence of bifilms. Bifilms can form by the surface turbulence of liquid metal. During such an action, two unbonded surfaces of oxides fold over each other which act as a crack. Therefore, this defect cause many problems in the cast part. In this work, it was found that bifilms have significant effect over the hot tearing of A356 alloy. When the alloy solidifies directionally, the structure consists of elongated dendritic structure. In the absence of equiaxed dendrites, the growing tips of the dendrites pushed the bifilms to open up and unravel. Thus, leading to enlarged surface of oxide to become more harmful. In this case, it was found that these bifilms initiate hot tearing.

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Authors and Affiliations

M. Uludağ
R. Çetin
D. Dışpınar

Evolution of Aluminium Melt Quality of A356 After Several Recycling

O. Gursoy E. Erzi K. Tur D. Dispinar
Archives of Foundry Engineering | 2020 | vol. 20 | No 4 | 61-66 | DOI: 10.24425/afe.2020.133348
Keywords A356 Bifilm index Recycling Melt quality Reduce pressure test
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Abstract

Recyclability is one of the great features of aluminium and its alloys. However, it has been typically considered that the secondary aluminium quality is low and bad. This is only because aluminium is so sensitive to turbulence. Uncontrolled transfer and handling of the liquid aluminium results in formation of double oxide defects known as bifilms. Bifilms are detrimental defects. They form porosity and deteriorate the properties. The detection and quantification of bifilms in liquid aluminium can be carried out by bifilm index measured in millimetres as an indication of melt cleanliness using Reduced Pressure Test (RPT). In this work, recycling efficiency and quality change of A356 alloy with various Ti additions have been investigated. The charge was recycled three times and change in bifilm index and bifilm number was evaluated. It was found that when high amount of Ti grain refiner was added, the melt quality was increased due to sedimentation of bifilms with Ti. When low amount of Ti is added, the melt quality was degraded.

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Authors and Affiliations

O. Gursoy
E. Erzi
K. Tur
D. Dispinar
ORCID: ORCID

Prediction of Fracture Stress with Regard to Porosity in Cast A356 Alloy

H. Sahin M. Atik F. Tezer S. Temel O. Aydin O. Kesen O. Gursoy D. Dispinar
Archives of Foundry Engineering | 2021 | vo. 21 | No 4 | 21-28 | DOI: 10.24425/afe.2021.138675
Keywords Casting defects Mechanical properties A356 Bifilm porosity Fracture stress
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Abstract

Production of the defect-free casting of aluminium alloys is the biggest challenge. Porosity is known to be the most important defect. Therefore, many cast parts are subjected to several non-destructive tests in order to check their acceptability. There are several standards, yet, the acceptance limit of porosity size and distribution may change according to the customer design and requirements. In this work, the aim was targeted to evaluate the effect of size, location, and distribution of pores on the tensile properties of cast A356 alloy. ANSYS software was used to perform stress analysis where the pore sizes were changed between 0.05 mm to 3 mm by 0.05 mm increments. Additionally, pore number was changed from 1 to 5 where they were placed at different locations in the test bar. Finally, bifilms were placed inside the pore at different sizes and orientations. The stress generated along the pores was recorded and compared with the fracture stress of the A356 alloy. It was found that as the bifilm size was getting smaller, their effect on tensile properties was lowered. On the other hand, as bifilms were larger, their orientation became the dominant factor in determining the fracture.
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Bibliography

[1] Buffiere, J.-Y., Savelli, S., Jouneau, P.-H., Maire, E. & Fougeres, R. (2001). Experimental study of porosity and its relation to fatigue mechanisms of model Al–Si7–Mg0. 3 cast Al alloys. Materials Science and Engineering: A. 316(1-2), 115-126. DOI: 10.1016/S0921-5093(01)01225-4.
[2] Dispinar, D. & Campbell, J. (2011). Porosity, hydrogen and bifilm content in Al alloy castings. Materials Science and Engineering: A. 528(10-11), 3860-3865. DOI: 10.1016/j.msea.2011.01.084.
[3] Dispinar, D. & Campbell, J. (2004). Critical assessment of reduced pressure test. Part 1: Porosity phenomena. International Journal of Cast Metals Research. 17, 280-286. DOI: 10.1179/136404604225020696.
[4] Dispinar, D. & Campbell, J. (2004). Critical assessment of reduced pressure test. Part 2: Quantification. International Journal of Cast Metals Research. 17, 287-294. DOI: 10.1179/136404604225020704.
[5] Dispinar, D. & Campbell, J. (2006). Use of bifilm index as an assessment of liquid metal quality. International Journal of Cast Metals Research. 19, 5-17. DOI: 10.1179/136404606225023300.
[6] Dispinar, D. & Campbell, J. (2007). Effect of casting conditions on aluminium metal quality. Journal of Materials Processing Technology. 182, 405-410. DOI: 10.1016/j.jmatprotec.2006.08.021.
[7] Campbell, J. (2015). Complete casting handbook: metal casting processes, metallurgy, techniques and design. Butterworth-Heinemann.
[8] Dispinar, D. & Campbell, J. (2014). Reduced pressure test (RPT) for bifilm assessment. in Shape Casting: 5th International Symposium 2014, 243-251.
[9] Asadian Nozari, M., Taghiabadi, R., Karimzadeh, M. & Ghoncheh, M. H. (2015). Investigation on beneficial effects of beryllium on entrained oxide films, mechanical properties and casting reliability of Fe-rich Al–Si cast alloy. Materials Science and Technology. 31, 506-512. DOI: 10.1179/1743284714Y.0000000656.
[10] Bagherpour-Torghabeh, H., Raiszadeh, R. & Doostmohammadi, H. (2017). Role of Mechanical Stirring of Al-Mg Melt in the Healing of Bifilm Defect. Metallurigical and Materials Transactions B. 48, 3174-3184. DOI: 10.1007/s11663-017-1067-9.
[11] Bjurenstedt, A., Seifeddine, S. & Jarfors, A. E. W. (2015). On the complexity of the relationship between microstructure and tensile properties in cast aluminum. International Journal of Modern Physics B. 29, 1540011. DOI: 10.1142/S0217979215400111.
[12] Bozchaloei, G. E., Varahram, N., Davami, P. & Kim, S. K. (2012). Effect of oxide bifilms on the mechanical properties of cast Al–7Si–0.3 Mg alloy and the roll of runner height after filter on their formation. Materials Science and Engineering A. 548, 99-105. DOI: 10.1016/j.msea.2012.03.097.
[13] Çolak, M., Kayikci, R. & Dispinar, D. (2016). Melt cleanliness comparison of chlorine fluxing and ar degassing of secondary Al-4Cu. Metallurgical and Materials Transactions B. 47, 2705-2709. DOI: 10.1007/s11663-016-0745-3.
[14] Davami, P., Kim, S. K. & Varahram, N. (2012). Effects of hydrogen and oxides on tensile properties of Al–Si–Mg cast alloys. Materials Science and Engineering A. 552, 36-47. DOI: 10.1016/j.msea.2012.04.111.
[15] Davami, P., Kim, S. K. & Tiryakioğlu, M. (2013). The effect of melt quality and filtering on the Weibull distributions of tensile properties in Al–7% Si–Mg alloy castings. Materials Science and Engineering A. 579, 64-70. DOI: 10.1016/j.msea.2013.05.014.
[16] Dispinar, D., Akhtar, S., Nordmark, A., Di Sabatino, M. & Arnberg, L. (2010). Degassing, hydrogen and porosity phenomena in A356. Materials Science and Engineering A. 527, 3719-3725. DOI: 10.1016/j.msea.2010.01.088.
[17] El-Sayed, M. A., Hassanin, H. & Essa, K. (2016). Bifilm defects and porosity in Al cast alloys. The International Journal of Advanced Manufacturing Technology. 86, 1173-1179. DOI: 10.1007/s00170-015-8240-6.
[18] El-Sayed, M. A., Hassanin, H. & Essa, K. (2016). Effect of casting practice on the reliability of Al cast alloys. International Journal of Cast Metals Research. 29, 350-354. DOI: 10.1080/13640461.2016.1145966.
[19] El-Sayed, M. A., Salem, H. A. G., Kandeil, A. Y. & Griffiths, W. D. (2014). Determination of the lifetime of a double-oxide film in al castings. Metallurgical and Materials Transactions B. 45, 1398-1406. DOI: 10.1007/s11663-014-0035-x.
[20] Erzi, E., Gürsoy, Ö., Yüksel, Ç., Colak, M. & Dispinar, D. (2019). Determination of acceptable quality limit for casting of A356 aluminium alloy: supplier’s quality index (SQI). Metals. 9, 957. DOI: 10.3390/met9090957.
[21] Fiorese, E., Bonollo, F., Timelli, G., Arnberg, L. & Gariboldi, E. (2015). New classification of defects and imperfections for aluminum alloy castings. International Journal of Metalcasting. 9, 55-66. DOI: 10.1007/BF03355602.
[22] Gopalan, R. & Prabhu, N. K. (2011). Oxide bifilms in aluminium alloy castings–a review. Materials Science and Technology. 27, 1757-1769. DOI: 10.1179/1743284711Y.0000000033.
[23] Hsu, F.-Y., Jolly, M. R. & Campbell, J. (2007). The design of L-shaped runners for gravity casting. in Metals & Materials Society The Minerals, Proceedings of Shape Casting: 2nd International Symposium, Orlando, FL, USA.
[24] Kang, M. et al. (2014). Tensile properties and microstructures of investment complex shaped casting. Materials Science and Technology. 30, 1349-1353. DOI: 10.1179/1743284713Y.0000000444.
[25] Mostafaei, M., Ghobadi, M., Eisaabadi, G., Uludağ, M. & Tiryakioğlu, M. (2016). Evaluation of the effects of rotary degassing process variables on the quality of A357 aluminum alloy castings. Metallurgical and Materials Transactions B. 47, 3469-3475. DOI: 10.1007/s11663-016-0786-7.
[26] Puga, H., Barbosa, J., Azevedo, T., Ribeiro, S. & Alves, J. L. (2016). Low pressure sand casting of ultrasonically degassed AlSi7Mg0.3 alloy: modelling and experimental validation of mould filling. Materials and Design. 94, 384-391. DOI: 10.1016/j.matdes.2016.01.059.
[27] Stefanescu, D. M. (2005). Computer simulation of shrinkage related defects in metal castings–a review. International Journal of Cast Metals Research. 18, 129-143. DOI: 10.1179/136404605225023018.
[28] Tiryakioğlu, M., Campbell, J. & Nyahumwa, C. (2011). Fracture surface facets and fatigue life potential of castings. Metallurgical and Materials Transactions B. 42, 1098-1103. DOI: 10.1007/s11663-011-9577-3.
[29] Tunçay, T. & Bayoğlu, S. (2017). The effect of iron content on microstructure and mechanical properties of A356 cast alloy. Metallurgical and Materials Transactions B. 48, 794-804. DOI: 10.1007/s11663-016-0909-1.
[30] Tunçay, T., Tekeli, S., Özyürek, D. & Dispinar, D. (2017). Microstructure–bifilm interaction and its relation with mechanical properties in A356. International Journal of Cast Metals Research. 30, 20-29. DOI: 10.1080/13640461.2016.1192826.
[31] Uludağ, M., Çetin, R., Dispinar, D. & Tiryakioğlu, M. (2017). Characterization of the Effect of Melt Treatments on Melt Quality in Al-7wt %Si-Mg Alloys. Metals. 7(5), 157. DOI: 10.3390/met7050157.
[32] Uludağ, M., Çetin, R., Dişpinar, D. & Tiryakioğlu, M. (2018). On the interpretation of melt quality assessment of A356 aluminum alloy by the reduced pressure test: the bifilm index and its physical meaning. International Journal of Metalcasting. 12, 853–860. DOI: 10.1007/s40962-018-0217-4.
[33] Yorulmaz, A., Erzi, E., Gursoy, O. & Dispinar, D. (2019). End product rejection rate and its correlation with melt treatment in direct-chill casted hot rolling slabs. International Journal of Cast Metals Research. 32, 164-170. DOI: 10.1080/13640461.2019.1598684.
[34] Zahedi, H. et al. (2007). The effect of Fe-rich intermetallics on the Weibull distribution of tensile properties in a cast Al-5 pct Si-3 pct Cu-1 pct Fe-0.3 pct Mg alloy. Metallurgical and Materials Transactions A. 38, 659-670. DOI: 10.1007/s11661-006-9068-3.
[35] Kuwazuru, O. et al. (2008). X-ray CT inspection for porosities and its effect on fatigue of die cast aluminium alloy. Journal of Solid Mechanics and Materials Engineering. 2(9), 1220-1231. DOI: 10.1299/jmmp.2.1220.
[36] Le, V.-D., Saintier, N., Morel, F., Bellett, D. & Osmond, P. (2018). Investigation of the effect of porosity on the high cycle fatigue behaviour of cast Al-Si alloy by X-ray micro-tomography. International Journal of Fatigue. 106, 24-37. DOI: 10.1016/j.ijfatigue.2017.09.012.
[37] Wang, L. et al. (2016). Influence of pores on crack initiation in monotonic tensile and cyclic loadings in lost foam casting A319 alloy by using 3D in-situ analysis. Materials Science and Engineering A. 673, 362-372. DOI: 10.1016/j.msea.2016.07.036.
[38] Vincent, M., Nadot-Martin, C., Nadot, Y. & Dragon, A. (2014). Fatigue from defect under multiaxial loading: efect Stress Gradient (DSG) approach using ellipsoidal Equivalent Inclusion Method. International Journal of Fatigue. 59, 176-187. DOI: 10.1016/j.ijfatigue.2013.08.027.
[39] Gyarmati, G., Fegyverneki, G., Mende, T. & Tokár, M. (2019). Characterization of the double oxide film content of liquid aluminum alloys by computed tomography. Materials Characterization. 157, 109925. DOI: 10.1016/j.matchar.2019.109925.
[40] Kobayashi, M., Dorce, Y., Toda, H. & Horikawa, H. (2010). Effect of local volume fraction of microporosity on tensile properties in Al–Si–Mg cast alloy. Materials Science and Technology. 26, 962-967. DOI: 10.1179/174328409X 441283.
[41] Nikishkov, G. P. (2004). Introduction to the finite element method. Univ. Aizu 1-70.
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Authors and Affiliations

H. Sahin
1
ORCID: ORCID
M. Atik
1
F. Tezer
1
S. Temel
1
O. Aydin
1
O. Kesen
1
O. Gursoy
2
D. Dispinar
3
ORCID: ORCID
  1. Istanbul Technical University, Turkey
  2. University of Padova, Italy
  3. Foseco, Netherlands

Effect of Chip Amount on Microstructural and Mechanical Properties of A356 Aluminum Casting Alloy

A.Y. Kaya O. Özaydın T. Yağcı A. Korkmaz E. Armakan O. Çulha
Archives of Foundry Engineering | 2021 | vo. 21 | No 3 | 19-26 | DOI: 10.24425/afe.2021.136108
Keywords A356 Gravity casting Chip melting Mechanical properties Recycling
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Abstract

Aluminum casting alloys are widely used in especially automotive, aerospace, and other industrial applications due to providing desired mechanical characteristics and their high specific strength properties. Along with the increase of application areas, the importance of recycling in aluminum alloys is also increasing. The amount of energy required for producing primary ingots is about ten times the amount of energy required for the production of recycled ingots. The large energy savings achieved by using the recycled ingots results in a significant reduction in the amount of greenhouse gas released to nature compared to primary ingot production. Production can be made by adding a certain amount of recycled ingot to the primary ingot so that the desired mechanical properties remain within the boundary conditions. In this study, by using the A356 alloy and chips with five different quantities (100% primary ingots, 30% recycled ingots + 70% primary ingots, 50% recycled ingots + 50% primary ingots, 70% recycled ingots + 30% primary ingots, 100% recycled ingots), the effect on mechanical properties has been examined and the maximum amount of chips that can be used in production has been determined. T6 heat treatment was applied to the samples obtained by the gravity casting method and the mechanical properties were compared depending on the amount of chips. Besides, microstructural examinations were carried out with optical microscopy techniques. As a result, it has been observed that while producing from primary ingots, adding 30% recycled ingot to the alloy composition improves the mechanical properties of the alloy such as yield strength and tensile strength to a certain extent. However, generally a downward pattern was observed with increasing recycled ingot amount.
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Bibliography

[1] Miller, W.S., Zhuang, L., Bottema, J., Wittebrood, A.J., Smet, P. De., Haszler, A. & Vieregge, A. (2000). Recent development in aluminium alloys for the automotive industry. Materials Science and Engineering: A. 280, 37-49. DOI: 10.1016/S0921-5093(99)00653-X
[2] Cagan, S.C., Venkatesh, B. & Buldum, B.B. (2020). Investigation of surface roughness and chip morphology of aluminum alloy in dry and minimum quantity lubrication machining. Materials Today: Proceedings. 27, 1122-1126. DOI: 10.1016/j.matpr.2020.01.547
[3] Naumova, E.A., Belov, N.A. & Bazlova, T.A. (2015). Effect of heat treatment on structure and strengthening of cast eutectic aluminum alloy Al9Zn4Ca3Mg. Metal Science and Heat Treatment. 57, 5-6. DOI: 10.1007/s11041-015-9874-6
[4] Krolo, J., Gudić, S., Vrsalović, L., Branimir, L., Zvonimir, D. (2020). Fatigue and corrosion behavior of solid-state recycled aluminum alloy EN AW 6082. Journal of Materials Engineering and Performance. 29(7), 4310-4321. DOI: 10.1007/s11665-020-04975-8
[5] TMMOB Metalurji Mühendisleri Odası, Alüminyum Komisyonu, Alüminyum Raporu.
[6] Dhindaw, B.K., Aditya, G.S.L. & Mandal, A. (2020). Recycling and downstream processing of aluminium alloys for automotive applications. In Saleem Hashmi and Imtiaz Ahmed Choudhury (Eds.), Encyclopedia of Renewable and Sustainable Materials. 3 (pp.154-161). Elsevier Inc.
[7] Grjotheim, K., Krohn, C., Malinovsky, M., Matiasovsky, K., Thonstad, J. (1982). Aluminium electrolysis: Fundamentals of the Hall-Heroult Process. 2nd Edition. University of California.
[8] Peng, T., Ou, X., Yan, X. & Wang, G. (2019). Life-cycle analysis of energy consumption and GHG emissions of aluminium production in China. Energy Procedia. 158, 3937- 3943. DOI: 10.1016/j.egypro.2019.01.849
[9] Prasada Rao, A. K. (2011). An approach for predicting the composition of a recycled Al-Alloy. Transactions of the Indian Institute of Metals. 64, 615-617. DOI: 10.1007/s12666-011-0084-7
[10] Capuzzi, S. & Timelli, G. (2018). Preparation and melting of scrap in aluminum recycling: A Review. Metals. 8(4), 249. DOI: 10.3390/met8040249
[11] Khalid, S.N.A.B. (2013). Mechanical strength of ascompacted aluminium alloy waste chips. Malaysia: MSc Thesis, Universiti Tun Hussein Onn Malaysia.
[12] Bjurenstedt, A. (2017). On the influence of imperfections on microstructure and properties of recycled Al-Si casting alloys. Sweden: PhD. Thesis, Jönköping University Jönköping.
[13] Bogdanoff, T., Seifeddine, S. & Dahle, A. K. (2016). The effect of Si content on microstructure and mechanical properties of Al-Si alloy. La Metallurgia Italiana. 108(6), 65- 69.
[14] Wang, Y., Liao, H., Wu, Y. & Yang, J. (2014). Effect of Si content on microstructure and mechanical properties of Al– Si–Mg alloys. Materials & Design. 53, 634-638.
[15] Ozaydin, O. & Kaya, A. (2019). Influence of different Si levels on mechanical properties of aluminium casting alloys. European Journal of Engineering And Natural Sciences. 3(2), 165-172.
[16] Zhang, X., Ahmmed, K., Wang, M. & Hu, H. (2012). Influence of aging temperatures and times on mechanical properties of vacuum high pressure die cast aluminum alloy A356. Advanced Materials Research. 445, 277-282. DOI: 10.4028/www.scientific.net/AMR.445.277
[17] Ozaydin, O., Dokumaci, E., Armakan, E., Kaya, A. (2019). The effects of artificial ageing conditions on a356 aluminum cast alloys. In ECHT 2019 - European Conference on Heat Treatment. Bardolino, Italy.
[18] Peng, J., Tang, X., He, J. & Xu, D. (2011). Effect of heat treatment on microstructure and tensile properties of A356 alloys. Trans. Nonferous Met. Soc. Chinea. 21, 1950-1956. DOI: 10.1016/S1003-6326(11)60955-2
[19] Wang, L., Makhlouf, M. & Apelian, D. (2013). Aluminium die casting alloys: alloy composition, microstructure, and properties-performance relationships. International Materials Reviews. 40(6), 221-238. DOI: 10.1179/imr.1995.40.6.221
[20] Yuksel, C.K., Tamer, O., Erzi, E., Aybarc, U., Cubuklusu, E., Topcuoglu, O., Cigdem, M. & Dispinar, D. (2016). Quality evaluation of remelted A356 scraps. Archives of Foundry Engineering. 16(3), 151-156. DOI: 10.1515/afe-2016-0069
[21] Hu, M., Ji, Z., Chen, X. & Zhang, Z. (2007). Effect of chip size on mechanical property and microstructure of AZ91D magnesium alloy prepared by solid state recycling. Materials Characterization. 59(4), 385-389. DOI: 10.1016/j.matchar.2007.02.002
[22] Testing Of Metallic Materials – Tensile Test Pieces, Prüfung Metallischer Werkstoffe – Zugproben Deutsche Norm DIN 50125, 2016.
[23] Metallic Materials - Tensile Testing - Part 1:Method Of Test at Room Temperature, PN-EN ISO 6892-1: 2020-05
[24] Taylor J.A. (2012). Iron-containing intermetallic phases in AlSi based casting alloys. Procedia Materials Science. 1, 19-33. DOI: 10.1016/j.mspro.2012.06.004
[25] Eisaabadi, G.B., Davami, P., Kim, S.K., Varahram, N., Yoon, Y.O. & Yeom, G.Y. (2012). Effect of oxide films, inclusions and Fe on reproducibility of tensile properties in cast Al–Si– Mg alloys: Statistical and image analysis. Materials Science and Engineering: A 558, 134-143. DOI: 10.1016/j.msea.2012.07.101
[26] Schlesinger, M.E. (2013). Aluminum Recycling. CRC Press. 2nd Edition. CRC Press
[27] Dispinar, D., Akhtar, S., Nordmark, A., Sabatino, M. Di. & Arnberg, L. (2010). Degassing, hydrogen and porosity phenomena in A356. Materials Science and Engineering: A. 527(17), 3719-3725. DOI: 10.1016/j.msea.2010.01.088
[28] Akhtar, S., Dispinar, D., Arnberg, L. & Sabatino, M.Di. (2009). Effect of hydrogen content melt cleanliness and solidification conditions on tensile properties of A356 alloy. International Journal of Cast Metals Research. 22(4), 22-25. DOI: 10.1179/136404609X367245
[29] Bösch, D., Pogatscher, S., Hummel, M., Fragner, W., Uggowitzer, P.J., Göken, M. & Höppel, H.W. (2015). Secondary Al-Si-Mg high-pressure die casting alloys with enhanced ductility. Metallurgical and Materials Transactions A. 46(3), 1035-1045.
[30] Taylor, J.A. (2004). The effect of iron in Al-Si casting alloys. In 35th Australian Foundry Institute National Conference, 31 Oct - 3 Nov 2004 (148-157). Australia: Australian Foundry Institute (AFI).
[31] Campbell, J. (1993). Castings, 2nd Edition. Elsevier
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Authors and Affiliations

A.Y. Kaya
1
O. Özaydın
1
T. Yağcı
2
A. Korkmaz
2
E. Armakan
1
O. Çulha
2
  1. Cevher Alloy Wheels Co. / R&D Dept., İzmir, Turkey
  2. Manisa Celal Bayar University, Engineering Faculty, Dept. of Metallurgical and Materials Engineering, Manisa, Turkey

Using anthropogenic waste (steel slag) to enhance mechanical and wear properties of a commercial aluminium alloy A356

K.S. Sridhar Raja V.K. Bupesh Raja M. Gupta
Archives of Metallurgy and Materials | 2019 | vol. 64 | No 1 | 279-284 | DOI: 10.24425/amm.2019.126249
Keywords A356 Steel slag wear resistance tensile strength Industrial waste environmental hazard
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Abstract

The present study addresses the utilization of induction furnace steel slag which is an anthropogenic waste, for enhancing the mechanical properties of a commercial aluminium alloy A356. Different weight percentage (3wt%, 6wt%, 9wt%, and 12wt%) of steel slag particles in 1 to 10 μm size range were used as reinforcing particles in aluminium alloy A356 matrix. The composites were prepared through stir casting technique. The results revealed an improvement in mechanical properties (i.e. microhardness and tensile strength) and wear resistance with an increase in weight percentage of the steel slag particles. This research work shows promising results for the utilization of the steel slag for enhancing the properties of aluminium alloy A356 at no additional cost while assisting at same time in alleviating land pollution.

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Authors and Affiliations

K.S. Sridhar Raja
V.K. Bupesh Raja
M. Gupta

Modelling and Experimental Characterization of Processing Parameters in Vertical Twin Roll Casting of Aluminium Alloy A356

B. Dhindaw S. Singh A. Mandal A. Pandey
Archives of Foundry Engineering | 2020 | vol. 20 | No 4 | 121-132 | DOI: 10.24425/afe.2020.133358
Keywords Aluminium alloy A356 Structural materials numerical modelling Vertical twin-roll casting
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Abstract

Production of near net shape thin strips using vertical twin roll casting method has been studied. In a typical VTRC process, the simultaneous action of solidification and rolling makes the process quite attractive as well as complicated. An industrially popular alloy A356 has been chosen for the VTRC processing. It is challenging to identify VTRC processing parameters for the alloy to produce thin strips because of its freezing range and complex composition. In the present work processing parameters of VTRC like roll speed, roll gap, melt superheat and the interface convective heat transfer coefficient have been investigated through modelling of the process. The mathematical model was developed which simultaneously solves the heat transfer, fluid flow and solidification, using commercial software COMSOL Multiphysics 5.4. VTRC sheets of alloy A356 were produced in an experimental set up and attempts were made to correlate the microstructures of VTRC A356 alloy to that predicted from the numerical studies to validate the model.

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Authors and Affiliations

B. Dhindaw
S. Singh
A. Mandal
A. Pandey

Application of Modular Die for Fluidity Test and Monitoring of the Pressing Force Flow by Semi-solid Squeeze Casting of AlSi7Mg0.3

D. Martinec R. Pastirčák
Archives of Foundry Engineering | 2020 | vol. 20 | No 3 | 69-73 | DOI: 10.24425/afe.2020.133332
Keywords Innovative Foundry Technologies and Materials Solidification process Semi-solid Squeeze Casting Aluminium alloy AlSi7Mg0.3 (A356) Fluidity test Pressing force flow
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Abstract

The fluidity is the term to determine the materials ability to fill the mold cavity properly. Fluidity is complex property with many variables. Up to this date, there is no methodology for defining the fluidity in a semisolid material state. Submitted paper deals with the proposal of a new method designed for aluminium alloy fluidity evaluation in semi-solid state trough the design of the layered construction die. Die will be primary used for fluidity tests of semi-solid squeeze casted aluminium alloy and to observe the pressing force flow by mentioned casting technology. The modularity consists of possibility to change each die segment. In the experiment the die design was evaluated by simulation in ProCAST 11.5 and by production of experimental castings. The die was made by laser cutting technology from construction steel S355JR. Experimental material was aluminium alloy AlSi7Mg0.3. The temperature of the semisolid state was chosen to achieve 35% of solid phase. The result of next study should be a selected parameters observation and their effect on the fluidity of aluminium alloy in semi-solid state. This will be very important step to determine the optimal conditions to achieve a castings with certain wall thickness produced by the method of semi-solid squeeze casting.

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Authors and Affiliations

D. Martinec
R. Pastirčák
ORCID: ORCID

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