Abstract
Fracture criteria will be used in fatigue life estimation involving both crack initiation and propagation. The consideration of static fracture work [1] alone may not be sufficient because experiments [2] have shown that the energy spent in the cyclic deformation of a material can be much larger than the static fracture energy. Moreover, energy dissipated in the form of heat [3] can be a large portion of the total energy under both static and cyclic loading.
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References
ROMANOV, A.N., Energy of fracture for cyclic loading, Problemy protchnosti, No. 3, 1971, pp. 3–9 (in Russian).
ROMANOV, A.N., Energy criteria of fracture for low-cyclic loading, Problemy protchnosti, No. 1, 1974, pp. 3–18 (in Russian).
FASTOV, N.S., Heat conduction in plastic deformation, Doklady AN SSSR (novaj seria), Vol. XXXIII, No. 6, 1952, pp. 851–854 (in Russian).
GRIFFITH, A A., The phenomena of rupture and flow in solids, Philosophical Transactions Royal Society, Ser. A, Vol. 221, 1920–21, pp. 163–168.
OROWAN, E., Energy criteria of fracture. Modifications of the Griffith theory are presented to cover the case for a rapidly running crack and for starting in a stationary crack, Welding Journal, No. 3, 1955, pp. 157–160.
RICE, J.R., Path independent integral and approximate analysis of strain concentration by notches and cracks, ASME Paper 68-APM-31, 1968, p. 8.
FEDOROV, V.V., Thermodynamic of strength and fracture of solid copper, Problemy protchnosti, No. 11, 1971 pp. 32 - 34 (in Russian).
GADENIN, M.M. and ROMANOV, A.N., Method for experimental determination of energy in static and cyclic elasto-plastic deformation and fracture, Zavodskaj laboratorio, No. 8, 1978, pp. 997–1002 (in Russian).
ROMANOV, A.N., GADENIN, M.M. and JUNIN, V.M., High-temperature vacuum programmable machines for investigation of low-cyclic fracture processes. Temperature Microscopic Investigation of Metals and Alloys, Moscow, Nauka, 1974, pp. 13–19 (in Russian).
ROMANOV, A.N., High-temperature vacuum camera for low-cycle testing machine under tension-compression, Zavodskaj laboratorio, Vol. XXXVII, No. 6, 1971, pp. 727–730 (in Russian).
JILIMO, L., Construction steel properties. Characterizing by work of limit strain, New Problems of Metallurgy, Moscow, An SSSR, 1958, pp. 572–582 (in Russian).
GADENIN, M.M. and ROMANOV, A.N., Range of Strain under Tension-Compression Cyclic Elasto-Plastic Deformation. Structure Factors under Low-Cycle Fracture of Metals, Moscow, Nauka, 1977, pp. 115–129 (in Russian).
IVANOVA, V.S. and TERENTIEV, V.F., Nature of Metal Fatigue, Moscow, Metallurgia, 1975 (in Russian).
JASTRGEMBSKI, A.S., Technical Thermodynamics, Moscow-Leningrad, Gosenergoizdat, 1953 (in Russian).
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© 1990 Kluwer Academic Publishers
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Romanov, A.N., Gadenin, M.M. (1990). Energy balance for elastoplastic fracture: static and cyclic loading. In: Sih, G.C., Ishlinsky, A.J., Mileiko, S.T. (eds) Plasticity and failure behavior of solids. Fatigue and Fracture, vol 3. Springer, Dordrecht. https://doi.org/10.1007/978-94-009-1866-5_9
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DOI: https://doi.org/10.1007/978-94-009-1866-5_9
Publisher Name: Springer, Dordrecht
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