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Comparison of the calculated and experimental fatigue lives under non-proportional bending with torsion of 10hnap steel

DSpace at Ternopil State Ivan Puluj Technical University

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Title Comparison of the calculated and experimental fatigue lives under non-proportional bending with torsion of 10hnap steel
 
Creator Marciniak, Z.
Rozumek, D.
Macha, E.
 
Contributor Opole University of Technology, ul. Mikołajczyka 5, 45-271 Opole, Poland
 
Description The paper contains the results of fatigue tests of 10HNAP steel under nonproportional
bending with torsion. The circular smooth specimens were tested. The tests were
carried out at the fatigue test stands MZGS-200PL and MZGS-200L. The best results of
experimental and calculation lives consistence for the considered materials was obtained
using the criterion of maximum shear stresses in the critical plane and the Palmgren-Miner
hypothesis of damage accumulation.
 
Date 2016-06-05T07:03:14Z
2016-06-05T07:03:14Z
2006-09-25
2006-09-25
 
Type Article
 
Identifier Marciniak Z. Comparison of the calculated and experimental fatigue lives under non-proportional bending with torsion of 10hnap steel / Z. Marciniak, D. Rozumek, E. Macha // Механічна втома металів. Праці 13-го міжнародного колоквіуму (МВМ-2006), 25-28 вересня 2006 року — Т. : ТДТУ, 2006 — С. 283-289. — (Розвиток втомних тріщин із урахуванням впливу корозійного середовища, температури, виду навантаження та інших факторів).
966-305-027-6
http://elartu.tntu.edu.ua/handle/123456789/16799
Marciniak Z., Rozumek D., Macha E. (2006) Comparison of the calculated and experimental fatigue lives under non-proportional bending with torsion of 10hnap steel. Mechanical Fatigue of Metals: Proceeding of the 13-th International Colloquium (MFM) (Tern., 25-28 September 2006), pp. 283-289 [in English].
 
Language en
 
Relation ⅩⅢ міжнародний колоквіум „Механічна втома металів“
ⅩⅢ Internation Colloquium "Mechanical fatigue of metals"
1. Stephens R.I., Fatemi A., Stephens R.R., Fuchs H.O.: Metal Fatigue in Engineering, Second Edition, John Wiley & Sons, Inc., 2001, ps 472
2. Macha E.: Generalization of fatigue fracture criteria for multiaxial sinusoidal loadings in the range of random loadings, Biaxial and Multiaxial Fatigue, EGF 3, Eds M.W. Brown and K.J. Miller, Mechanical Engineering Publications, London 1989, pp. 425-436
3. Brown M.W., Miller K.J.: Two decades of progress in the assessment of multiaxial low-cycle fatigue life, in: Low-Cycle Fatigue and Life Prediction, Amzallag C., Leis B., Rabbe P., Eds ASTM STP 770, Philadelphia, 1982, pp. 482-499
4. Łagoda T., Macha E. & Niesłony A.: Comparison of the rain flow algorithm and the spectral method for fatigue life determination under uniaxial and multiaxial random loading, Journal of ASTM International, Vol. 1, No. 8, 2004, pp. 544-556
5. Gough H.J., Pollard H.V.: The effect of specimen form on the resistance of metals to combined alternating stresses, Proc. of the Institution of Mechanical Engineers, Vol. 135, 1935, pp. 549-573
6. McDiarmid D. L.: Fatigue behaviour under out-of-phase bending and torsion, The Aeronautical Journal of the Royal Aeronautical Society, March 1981, pp. 118-122
7. Papadopoulos I.V.: A new criterion of fatigue strength for out-of-phase bending and torsion of hard metals, Int. J. Fatigue, Vol. 16, 1994, pp. 377-384
8. Nishihara T., Kawamoto M.: The Strength of Metals under Combined Alternating Bending and Torsion with Phase Difference, Memoirs of the College of Engineering, Kyoto Imperial University, Vol. XI, No. 5, 1945, pp. 85-112
9. Liu J., Zenner H.: The fatigue limit of ductile metals under multiaxial loading, Biaxial/Multiaxial Fatigue and Fracture, ESIS 31, Eds A. Carpinteri, M. de Freitas and A. Spagnoli, Elsevier, London 2003, pp. 147-164
10. Marciniak Z.: Fatigue life of structural steels under non-proportional bending with torsion, Doctoral thesis, Opole University of Technology, 2005, p. 149 (in Polish)
11. Sanetra C.: Untersuchungen zum Festigkeitsverhalten bei mehrachsiger Randombeanspruchung unter Biegung und Torsion, Disseration, Technischen Universität Clausthal, Clausthal-Zellerfeld, 1991, s. 151
12. Palmgren A.: Die Labensdauer von Kugellagern, VDI-Z, Vol. 68, 1924, ss. 339-341
13. Miner M. A.: Cumulative damage in fatigue, Journal of Applied Mechanics Vol. 12, 1945
14. Serensen S.V., Kogayev V.P., Shnejderovich R.M.: Permissible loading and strength calculations of machine components, Third Edn., Mashinostroenie, Moskva 1975, 488 ps (in Russian)
15. Corten H. T., Dolan T. J.: Cumulative fatigue damage, Proc. of Int. Conf. on Fatigue of Metals, The Institution of Mechanical Engineers and ASME, London, New York 1956, pp. 235-246
1. Stephens R.I., Fatemi A., Stephens R.R., Fuchs H.O., Metal Fatigue in Engineering, Second Edition, John Wiley & Sons, Inc., 2001, ps 472
2. Macha E., Generalization of fatigue fracture criteria for multiaxial sinusoidal loadings in the range of random loadings, Biaxial and Multiaxial Fatigue, EGF 3, Eds M.W. Brown and K.J. Miller, Mechanical Engineering Publications, London 1989, pp. 425-436
3. Brown M.W., Miller K.J., Two decades of progress in the assessment of multiaxial low-cycle fatigue life, in: Low-Cycle Fatigue and Life Prediction, Amzallag C., Leis B., Rabbe P., Eds ASTM STP 770, Philadelphia, 1982, pp. 482-499
4. Łagoda T., Macha E. & Niesłony A., Comparison of the rain flow algorithm and the spectral method for fatigue life determination under uniaxial and multiaxial random loading, Journal of ASTM International, Vol. 1, No. 8, 2004, pp. 544-556
5. Gough H.J., Pollard H.V., The effect of specimen form on the resistance of metals to combined alternating stresses, Proc. of the Institution of Mechanical Engineers, Vol. 135, 1935, pp. 549-573
6. McDiarmid D. L., Fatigue behaviour under out-of-phase bending and torsion, The Aeronautical Journal of the Royal Aeronautical Society, March 1981, pp. 118-122
7. Papadopoulos I.V., A new criterion of fatigue strength for out-of-phase bending and torsion of hard metals, Int. J. Fatigue, Vol. 16, 1994, pp. 377-384
8. Nishihara T., Kawamoto M., The Strength of Metals under Combined Alternating Bending and Torsion with Phase Difference, Memoirs of the College of Engineering, Kyoto Imperial University, Vol. XI, No. 5, 1945, pp. 85-112
9. Liu J., Zenner H., The fatigue limit of ductile metals under multiaxial loading, Biaxial/Multiaxial Fatigue and Fracture, ESIS 31, Eds A. Carpinteri, M. de Freitas and A. Spagnoli, Elsevier, London 2003, pp. 147-164
10. Marciniak Z., Fatigue life of structural steels under non-proportional bending with torsion, Doctoral thesis, Opole University of Technology, 2005, p. 149 (in Polish)
11. Sanetra C., Untersuchungen zum Festigkeitsverhalten bei mehrachsiger Randombeanspruchung unter Biegung und Torsion, Disseration, Technischen Universität Clausthal, Clausthal-Zellerfeld, 1991, s. 151
12. Palmgren A., Die Labensdauer von Kugellagern, VDI-Z, Vol. 68, 1924, ss. 339-341
13. Miner M. A., Cumulative damage in fatigue, Journal of Applied Mechanics Vol. 12, 1945
14. Serensen S.V., Kogayev V.P., Shnejderovich R.M., Permissible loading and strength calculations of machine components, Third Edn., Mashinostroenie, Moskva 1975, 488 ps (in Russian)
15. Corten H. T., Dolan T. J., Cumulative fatigue damage, Proc. of Int. Conf. on Fatigue of Metals, The Institution of Mechanical Engineers and ASME, London, New York 1956, pp. 235-246
 
Rights © Тернопільський державний технічний університет імені Івана Пулюя
 
Format 283-289
7
 
Coverage 25-28 вересня 2006 року
25-28 September 2006
Україна, Тернопіль
Ukraine, Ternopil
 
Publisher ТДТУ
TDTU