A phenomenological model of macrocrack initiation and growth in cyclically deformed material

Ostash, O. P.; Panasyuk, V. V.

Будь ласка, використовуйте цей ідентифікатор, щоб цитувати або посилатися на цей матеріал: http://elartu.tntu.edu.ua/handle/123456789/16779

Повний запис метаданих

Поле DC	Значення	Мова
dc.contributor.author	Ostash, O. P.	uk
dc.contributor.author	Panasyuk, V. V.	uk
dc.coverage.temporal	25-28 вересня 2006 року	uk
dc.coverage.temporal	25-28 September 2006	uk
dc.date.accessioned	2016-06-05T07:00:29Z	-
dc.date.available	2016-06-05T07:00:29Z	-
dc.date.created	2006-09-25	uk
dc.date.issued	2006-09-25	uk
dc.identifier.citation	Ostash O. P. A phenomenological model of macrocrack initiation and growth in cyclically deformed material / O. P. Ostash, V. V. Panasyuk // Механічна втома металів. Праці 13-го міжнародного колоквіуму (МВМ-2006), 25-28 вересня 2006 року — Т. : ТДТУ, 2006 — С. 152-159. — (Фізичні та феноменологічні підходи до опису втомного пошкодження).	uk
dc.identifier.isbn	966-305-027-6	uk
dc.identifier.uri	http://elartu.tntu.edu.ua/handle/123456789/16779	-
dc.description.abstract	Role of the process zone in fatigue macrocrack initiation and propagation is considered. An examples of the assessment of the fatigue macrocrack initiation period, Ni, and the failure period, Nf, of a notched specimens on the base of unified model using fatigue macrocrack growth rates only are shown. Some backgrounds and well-known fatigue phenomena (Kitagawa's and Smith's diagrams, etc) are discussed.	uk
dc.format.extent	152-159	uk
dc.language.iso	en	uk
dc.publisher	ТДТУ	uk
dc.publisher	TDTU	uk
dc.relation.ispartof	ⅩⅢ міжнародний колоквіум „Механічна втома металів“	uk
dc.relation.ispartof	ⅩⅢ Internation Colloquium "Mechanical fatigue of metals"	uk
dc.title	A phenomenological model of macrocrack initiation and growth in cyclically deformed material	uk
dc.type	Article	uk
dc.rights.holder	© Тернопільський державний технічний університет імені Івана Пулюя	uk
dc.coverage.placename	Україна, Тернопіль	uk
dc.coverage.placename	Ukraine, Ternopil	uk
dc.format.pages	8	uk
dc.relation.references	1. Schijve J. Fatigue of structures and materials in the 20th century and the state of the art // International Journal of Fatigue.- 2003.- 25 (8).- p. 679-702.	uk
dc.relation.references	2. Ostash O.P., Panasyuk V.V., Kostyk C.M. A phenomenological model of fatigue macrocrack initiation near stress concentrators // Fatigue Fract. Engng Mater. Struct.- 1999.- 22 (2).- p. 161-172.	uk
dc.relation.references	3. Ostash O.P., Panasyuk V.V. Fatigue process zone at notches // Int. J. Fatigue.- 2001.- 23 (7).- p. 627-636.	uk
dc.relation.references	4. Ostash O.P., Panasyuk V.V. A unified approach to fatigue macrocrack initiation and propagation // Int. J. Fatigue.- 2003.- 25 (8).- p. 703-708.	uk
dc.relation.references	5. Neuber H. Kerbspannungslehre, Berlin, Springer, 1945. (Trans. Theory of Notch Stress, U.S. Office of Technical Services, 1961).	uk
dc.relation.references	6. Peterson R.E. Notch sensitivity, Metal fatigue (Sines G., Weisman I.L., editors), New York, Mc Craw-Hill, 1959.- p. 293-306.	uk
dc.relation.references	7. Qylafsku G., Azari Z., Kadi N., Gjonaj N., Pluvinage G. Application of a new model proposal for the fatigue life prediction on notches and key-seats // Int. J. Fatigue.- 1999.- 21 (8).- p. 753-760.	uk
dc.relation.references	8. Taylor D., Wang G. The validation of some methods of notch fatigue analysis // Fatigue Fract. Engng Mater. Struct.- 2000.- 23.- p. 387-394.	uk
dc.relation.references	9. Klesnil M., Lukas P. Fatigue of metallic materials, Prague, Academia, 1980.- 239 p.p.	uk
dc.relation.references	10. Troshchenko V.T. Investigation of the threshold stress intensity factors at cyclic loading. Communication 2. Prediction of the fatigue limit and the fatigue crack propagation // Strength of Materials.- 1998.- № 5.- p. 5-11 (in Russian).	uk
dc.relation.references	11. Kitagawa H., Takahashi S. Applicability of fracture mechanics to very small cracks in the early stage // Proceedings 2nd Int. Conf. on Mechanical Behaviour of Materials, Boston, Massachusetts, 1976.- p. 627-631.	uk
dc.relation.references	12. El Haddad M. H., Dowling N. F., Topper T. H., Smith K. N. J-integral application for short fatigue cracks at notches // Int. J. of Fracture.- 1980.- 16.- p. 15-24.	uk
dc.relation.references	13. Taylor D. Geometrical effects in fatigue: a unifying theoretical model // Int. J. of Fatigue.- 1999.-21.- p. 413-420.	uk
dc.relation.references	14. Yarema S.Ya., Ostash O.P. About the fracture toughness of materials at cyclic loading // Soviet Material Science.- 1978.- 5.- p. 112-114.	uk
dc.relation.references	15. Ostash O. P. Assessment of materials degradation in structures after long-term service using unified model of fatigue fracture.—Fracture Mechanics of Materials and Strength of Structures (Editor Panasyuk V. V.), Lviv, Karpenko Physico-Mechanical Institute, 2004.- p.p. 457-464 (in Ukrainian).	uk
dc.relation.references	16. Saanouni K., Bathias C. Study of fatigue initiation in the vicinity of notches // Engng Fract. Mech.- 1982.- 16 (5).- p. 615-706.	uk
dc.relation.references	17. Smith R. A., Miller K. J. Prediction of fatigue regimes in notched component // Int. J. Mech. Sci.-1978.- 20 (3).- p. 201-206.	uk
dc.relation.referencesen	1. Schijve J. Fatigue of structures and materials in the 20th century and the state of the art, International Journal of Fatigue, 2003, 25 (8), p. 679-702.	uk
dc.relation.referencesen	2. Ostash O.P., Panasyuk V.V., Kostyk C.M. A phenomenological model of fatigue macrocrack initiation near stress concentrators, Fatigue Fract. Engng Mater. Struct, 1999, 22 (2), p. 161-172.	uk
dc.relation.referencesen	3. Ostash O.P., Panasyuk V.V. Fatigue process zone at notches, Int. J. Fatigue, 2001, 23 (7), p. 627-636.	uk
dc.relation.referencesen	4. Ostash O.P., Panasyuk V.V. A unified approach to fatigue macrocrack initiation and propagation, Int. J. Fatigue, 2003, 25 (8), p. 703-708.	uk
dc.relation.referencesen	5. Neuber H. Kerbspannungslehre, Berlin, Springer, 1945. (Trans. Theory of Notch Stress, U.S. Office of Technical Services, 1961).	uk
dc.relation.referencesen	6. Peterson R.E. Notch sensitivity, Metal fatigue (Sines G., Weisman I.L., editors), New York, Mc Craw-Hill, 1959, p. 293-306.	uk
dc.relation.referencesen	7. Qylafsku G., Azari Z., Kadi N., Gjonaj N., Pluvinage G. Application of a new model proposal for the fatigue life prediction on notches and key-seats, Int. J. Fatigue, 1999, 21 (8), p. 753-760.	uk
dc.relation.referencesen	8. Taylor D., Wang G. The validation of some methods of notch fatigue analysis, Fatigue Fract. Engng Mater. Struct, 2000, 23, p. 387-394.	uk
dc.relation.referencesen	9. Klesnil M., Lukas P. Fatigue of metallic materials, Prague, Academia, 1980, 239 p.p.	uk
dc.relation.referencesen	10. Troshchenko V.T. Investigation of the threshold stress intensity factors at cyclic loading. Communication 2. Prediction of the fatigue limit and the fatigue crack propagation, Strength of Materials, 1998, No 5, p. 5-11 (in Russian).	uk
dc.relation.referencesen	11. Kitagawa H., Takahashi S. Applicability of fracture mechanics to very small cracks in the early stage, Proceedings 2nd Int. Conf. on Mechanical Behaviour of Materials, Boston, Massachusetts, 1976, p. 627-631.	uk
dc.relation.referencesen	12. El Haddad M. H., Dowling N. F., Topper T. H., Smith K. N. J-integral application for short fatigue cracks at notches, Int. J. of Fracture, 1980, 16, p. 15-24.	uk
dc.relation.referencesen	13. Taylor D. Geometrical effects in fatigue: a unifying theoretical model, Int. J. of Fatigue, 1999.-21, p. 413-420.	uk
dc.relation.referencesen	14. Yarema S.Ya., Ostash O.P. About the fracture toughness of materials at cyclic loading, Soviet Material Science, 1978, 5, p. 112-114.	uk
dc.relation.referencesen	15. Ostash O. P. Assessment of materials degradation in structures after long-term service using unified model of fatigue fracture.-Fracture Mechanics of Materials and Strength of Structures (Editor Panasyuk V. V.), Lviv, Karpenko Physico-Mechanical Institute, 2004, p.p. 457-464 (in Ukrainian).	uk
dc.relation.referencesen	16. Saanouni K., Bathias C. Study of fatigue initiation in the vicinity of notches, Engng Fract. Mech, 1982, 16 (5), p. 615-706.	uk
dc.relation.referencesen	17. Smith R. A., Miller K. J. Prediction of fatigue regimes in notched component, Int. J. Mech. Sci.-1978, 20 (3), p. 201-206.	uk
dc.identifier.citationen	Ostash O. P., Panasyuk V. V. (2006) A phenomenological model of macrocrack initiation and growth in cyclically deformed material. Mechanical Fatigue of Metals: Proceeding of the 13-th International Colloquium (MFM) (Tern., 25-28 September 2006), pp. 152-159 [in English].	uk
dc.contributor.affiliation	Karpenko Physico-Mechanical Institute, National Academy of Science of Ukraine, 5, Naukova Str., 79601, Lviv, Ukraine	uk
dc.citation.journalTitle	ⅩⅢ міжнародний колоквіум „Механічна втома металів“	uk
dc.citation.spage	152	uk
dc.citation.epage	159	uk
dc.citation.conference	13-ий міжнародний колоквіум (МВМ-2006) „Механічна втома металів“	uk
Розташовується у зібраннях:	13-ий міжнародний колоквіум (МВМ-2006) „Механічна втома металів“ (2006)

Файли цього матеріалу:

Файл	Розмір	Формат
Conf_2006_Ostash_O_P-A_phenomenological_model_152-159.pdf	150,87 kB	Adobe PDF	Переглянути/відкрити
Conf_2006_Ostash_O_P-A_phenomenological_model_152-159.djvu	132,21 kB	DjVu	Переглянути/відкрити
Conf_2006_Ostash_O_P-A_phenomenological_model_152-159__COVER.jpg	189,61 kB	JPEG	Переглянути/відкрити

Показати базовий опис матеріалу Перегляд статистики

Усі матеріали в архіві електронних ресурсів захищені авторським правом, всі права збережені.