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Generation of a service loading with the desired probability distribution and autocorrelation for fatigue tests using MATLAB

Ewald Macha Roland Pawliczek
Archive of Mechanical Engineering | 2007 | vol. 54 | No 2 | 137-145 | DOI: 10.24425/ame.2007.131549
Keywords signal generation random loading fatigue of materials probability characteristics of loadaing Markov matrix
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Abstract

The aim of the paper is to present a procedure for generating service loading for fatigue tests of materials and structures. The generated loading characterizes desired functions of probability distribution and autocorrelation. The proposed numerical procedure uses MATLAB toolboxes and consists of three steps: (a) generation of a sequence of real numbers with the desired autocorrelation function and with any probability distribution function; (b) generation of loading history with the desired probability distribution function; (c) rearrangement of loading history (mentioned in item b) based on a sequence of real numbers with the desired correlation (mentioned in item a).

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Authors and Affiliations

Ewald Macha
Roland Pawliczek

The control system based on FPGA technology for fatigue test stand MZGS-100 PL

Wojciech Macek Ewald Macha
Archive of Mechanical Engineering | 2015 | vol. 62 | No 1 | 85-100 | DOI: 10.1515/meceng-2015-0006
Keywords FPGA control system mechatronics fatigue test strain energy parameter
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Abstract

The paper presents a solution of the control system for fatigue test stand MZGS-100 PL, comprising the integrated Real-Time controller based on FPGA (Field-Programmable Gate Array) technology with LabVIEW software. The described control system performs functions such as continuous regulation of speed induction motor, measuring strain of the lever machine and the test specimen, displacement of the polyharmonic vibrator, as well as the elimination of interferences, overload protection and emergency stop of the machine. The fatigue test stand also allows to set the pseudo-random history of energy parameter W(t).

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Authors and Affiliations

Wojciech Macek
Ewald Macha

A review of energy-based multiaxial fatigue failure criteria

Ewald Macha
Archive of Mechanical Engineering | vol. 48 | No 1 | 71-101
Keywords strain energv density cyclic and random loading multiaxial louding critical plane effect of mean stresses
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Abstract

The paper contains a review of energy-based multiaxial fatigue failure criteria for cyclic and random loading. The criteria for cyclic loading have been divided into three groups, depending on the kind of strain energy density per cycle which is assumed as a damage parameter. They are: a) criteria based on elastic strain energy for high-cycle fatigue, b) criteria based on plastic strain energy for low-cycle fatigue. and c) criteria based on the sum of plastic and elastic strain energies for both low- and high-cycle fatigue. The criterion for random loading is based on the new definition of energy parameter which distinguishes plus and minus signs in history or specific work of stress on strain along chosen directions in the critical fracture plane. The criteria which rake into account strain energy density in the critical plane dominate in the energy description or multiaxial fatigue. Parameters dependent on loading and factors dependent on a kind or marcrial and inlluencing selection of the critical plane have been given. The author presented the mathematical models or the criteria and next distinguished those including influence of mean stresses and stress gradients as well as proportional and non-proportional loading. It has been emphasised that the generalized criterion of maximum shear and normal strain energy density in the critical plane seems to be the most efficient in practice and it should be developed and verified in a future.
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Authors and Affiliations

Ewald Macha

Critical and fracture plane orientations under multiaxial cyclic and random loading

Aleksander Karolczuk Ewald Macha
Archive of Mechanical Engineering | 2004 | vol. 51 | No 3 | 415-435
Keywords damage accumulation method weight function method multiaxial random loading fatigue fracture planes
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Abstract

The critical plane orientations determined with account for maximum value of energy density parameters and the weight function method were compared to experimental fatigue fracture plane orientations. Energy density parameters used in two multiaxial fatigue failure criteria, i.e. (i) criterion of the maximum normal strain energy density on the critical plane and (ii) criterion of the maximum shear strain energy density on the critical plane were employed. In the other method, the weight functions were formed on the basis of energy parameters. These two methods were verified by experimental tests of 1802A steel. The material was subjected to cyclic and random bending, torsion and combined bending with torsion with different coefficients of cross correlation between normal and shear stresses. The calculated results are satisfactory for both methods.
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Authors and Affiliations

Aleksander Karolczuk
Ewald Macha

The fatigue characteristics of materials with the controlled strain energy density parameter

Włodzimierz Będkowski Ewald Macha Jacek Slowik
Archive of Mechanical Engineering | 2004 | vol. 51 | No 3 | 437-451
Keywords energy fatigue characteristics fatigue tests energy parameter Cyclic Loading 10HNAP steel PA6 aluminium
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Abstract

The subject of this paper is a new procedure applied for more precise determination of material fatigue characteristics. The proposed approach is based on a special definition of the strain energy density parameter used for material fatigue property descriptions and, in the consequence, on the new algorithm of the fatigue machine control in the feedback loop. On the basis of fatigue tests under uniaxial tension-compression with the strain energy density parameter control it was proved that the fatigue characteristics in energy approach (Wa - N1) determined directly from the tests and indirectly from the Manson-Coffin relation (E,, - Nj) with the strain control for material showing cyclic stability are similar. However, for material cyclic hardening these characteristics differ significantly in high cycle fatigue regime.
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Authors and Affiliations

Włodzimierz Będkowski
Ewald Macha
Jacek Slowik

Fatigue life of cast irons GGG40, GGG60 and GTS45 under combined variable amplitude tension with torsion

Tadeusz Łagoda Ewald Macha Adam Nieslony Andreas Muller
Archive of Mechanical Engineering | vol. 48 | No 1 | 55-69
Keywords biaxial fatigue variable amplitude energy criterion life time
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Abstract

The paper contains the tatigue tests results for specimens made of three cast irons under proportional and non-proportional variable amplitude tension with torsion. The experimental data for long fatigue life have been compared with those calculated according to the algorithm with use of the modified criterion of the maximum normal stress in the critical plane. In the considered algorithm the Palmgren-Miner hypothesis of damage cumulation seems to he useless whereas the Serensen-Kcgaycv hypothesis gives satisfactory results. Applying the method of fatigue damage cumulation we obtain the critical plane direction which agrees with the experimental fracture plane very well.
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Authors and Affiliations

Tadeusz Łagoda
Ewald Macha
Adam Nieslony
Andreas Muller

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