Geodesic
Numerical solution of the problem of stress-strain state of~a~surface-hardened prismatic V-notched specimen in~elastic and elastoplastic formulations
Journal of Samara State Technical University, Ser. Physical and Mathematical Sciences, Tome 27 (2023) no. 3, pp. 491-508.

Voir la notice de l'article provenant de la source Math-Net.Ru

A method has been developed for solving the problem of calculating the stress-strain state in a surface-hardened prismatic V-notched specimen at different values of the opening angle in both elastic and elastoplastic formulations. The method is based on finite element modeling and the known initial stress-strain state for a smooth hardened specimen. A detailed study was conducted on the influence of the notch opening angle and its depth on the level and distribution of residual stresses from the stress concentrator bottom throughout the thickness of the hardened layer for both formulations of the problem. Based on the calculation data, the feasibility of investigating the problem in the elastoplastic formulation was justified when the notch is located completely or partially in the hardened layer, as the magnitudes of residual stresses in the elastic formulation are physically unrealizable, since their values exceed the material's yield strength several times. In this case, the error between solutions in the elastic and elastoplastic formulations for residual stresses reaches 100–200 % in the root-mean-square norm, and reaches several hundred percent in the uniform estimate (Chebyshev norm). If the depth of the stress concentrator exceeds the thickness of the hardened layer by more than 1.5 times, the elastic and elastoplastic solutions yield similar results.
Keywords: advanced surface plastic deformation, prismatic specimen, V-shaped notch, residual stresses, finite element modeling, elastic and elastic plastic solutions. 
@article{VSGTU_2023_27_3_a5,
     author = {V. P. Radchenko and D. M. Shishkin and M. N. Saushkin},
     title = {Numerical solution of the problem of stress-strain state of~a~surface-hardened prismatic  {V-notched} specimen  in~elastic and elastoplastic formulations},
     journal = {Journal of Samara State Technical University, Ser. Physical and Mathematical Sciences},
     pages = {491--508},
     publisher = {mathdoc},
     volume = {27},
     number = {3},
     year = {2023},
     language = {ru},
     url = {http://geodesic.mathdoc.fr/item/VSGTU_2023_27_3_a5/}
}
TY  - JOUR
AU  - V. P. Radchenko
AU  - D. M. Shishkin
AU  - M. N. Saushkin
TI  - Numerical solution of the problem of stress-strain state of~a~surface-hardened prismatic  V-notched specimen  in~elastic and elastoplastic formulations
JO  - Journal of Samara State Technical University, Ser. Physical and Mathematical Sciences
PY  - 2023
SP  - 491
EP  - 508
VL  - 27
IS  - 3
PB  - mathdoc
UR  - http://geodesic.mathdoc.fr/item/VSGTU_2023_27_3_a5/
LA  - ru
ID  - VSGTU_2023_27_3_a5
ER  - 
%0 Journal Article
%A V. P. Radchenko
%A D. M. Shishkin
%A M. N. Saushkin
%T Numerical solution of the problem of stress-strain state of~a~surface-hardened prismatic  V-notched specimen  in~elastic and elastoplastic formulations
%J Journal of Samara State Technical University, Ser. Physical and Mathematical Sciences
%D 2023
%P 491-508
%V 27
%N 3
%I mathdoc
%U http://geodesic.mathdoc.fr/item/VSGTU_2023_27_3_a5/
%G ru
%F VSGTU_2023_27_3_a5
V. P. Radchenko; D. M. Shishkin; M. N. Saushkin. Numerical solution of the problem of stress-strain state of~a~surface-hardened prismatic  V-notched specimen  in~elastic and elastoplastic formulations. Journal of Samara State Technical University, Ser. Physical and Mathematical Sciences, Tome 27 (2023) no. 3, pp. 491-508. http://geodesic.mathdoc.fr/item/VSGTU_2023_27_3_a5/

[1] Eriksson R., Moverare J., Chen Z., Simonsson K., “The effect of notches on the fatigue life of a nickel-base gas turbine disk material”, Acta Polytechnica CTU Proceedings, 20 (2018), 34–42 | DOI

[2] Liu B., Yan X., “An extension research on the theory of critical distances for multiaxial notch fatigue finite life prediction”, Int. J. Fatigue, 117 (2018), 217–229 | DOI

[3] Bressan S., Ogawa F., Itoh T., Berto F., “Influence of notch sensitivity and crack initiation site on low cycle fatigue life of notched components under multiaxial nonproportional loading”, Frattura ed Integrità Strutturale, 13:47 (2019), 126–140 | DOI

[4] Macek W., “Fracture surface formation of notched 2017A-T4 aluminium alloy under bending fatigue”, Int. J. Fract., 234 (2022), 141–157 | DOI

[5] Birger I. A., Ostatochnye napriazheniia [Residual Stresses], Mashgiz, Moscow, 1963, 232 pp. (In Russian)

[6] Grinchenko I. G., Uprochnenie detalei iz zharoprochnykh i titanovykh splavov [Hardening Parts Made of High-Resistant and Titanium Alloys], Mashinostroenie, Moscow, 1971, 120 pp. (In Russian)

[7] Sulima A. M., Shuvalov V. A., Yagodkin Yu. D., Poverkhnostnyi sloi i ekspluatatsionnye svoistva detalei mashin [Surface Layer and Performance of Machine Parts], Mashinostroenie, Moscow, 1988, 240 pp. (In Russian)

[8] Kudryavtsev I. V., Poverkhnostnyi naklep dlia povysheniia prochnosti i dolgovechnosti detalei mashin poverkhnostnym plasticheskim deformirovaniem [Surface Strain Hardening to Increase the Strength and Durability of Machine Parts], Mashinostroenie, Moscow, 1969, 100 pp. (In Russian)

[9] Nozhnitskii Yu. A., Fishgoit A. V., Tkachenko R. I., Teplova S. V., “Development and application of new GTE parts hardening methods based on the plastic deformation of the surface layers”, Vestn. Dvigatel., 2006, no. 2, 8–16 (In Russian)

[10] Radchenko V. P., Shishkin D. M., “The method of reconstruction of residual stresses in a prismatic specimen with a notch of a semicircular profile after advanced surface plastic deformation”, Izv. Saratov Univ. Math. Mech. Inform., 20:4 (2020), 478–492 (In Russian) | DOI

[11] Radchenko V. P., Shishkin D. M., “Numerical method for calculating the stress-strain state in a prismatic surface-hardened spacemen with a notch in elastic and elastoplastic formulations”, Izv. Saratov Univ. Math. Mech. Inform., 21:4 (2021), 503–519 (In Russian) | DOI

[12] Radchenko V. P., Pavlov V. Ph., Saushkin M. N., “Investigation of surface plastic hardening anisotropy influence on residual stresses distribution in hollow and solid cylindrical specimens”, PNRPU Mechanics Bulletin, 2015, no. 1, 130–147 (In Russian) | DOI

[13] Pavlov V. F., Bukaty A. S., Semenova O. Yu., “Forecasting of the endurance limit of surface-hardened parts with stress concentrators”, Vestn. Mashinostroeniya, 2019, no. 1, 3–7 (In Russian)

[14] Pavlov V. F., Kirpichev V. A., Vakulyuk V. S., Prognozirovanie soprotivleniia ustalosti poverkhnostno uprochnennykh detalei po ostatochnym napriazheniiam [Prediction of Fatigue Resistance of Surface Reinforced Parts by Residual Stresses], Samara Sci. Center of RAS, Samara, 2012, 125 pp. (In Russian)

[15] Ivanov S. I., Shatunov M. P., Pavlov V. F., “Influence of residual stresses on notched specimen endurance”, Problems of Strength of Aircraft Structure Elements, v. 1, Kuibyshev Aviation Inst., Kuibyshev, 1974, 88–95 (In Russian)

[16] Saushkin M. N., Radchenko V. P., Kurov A. Yu., “Method of calculating residual stresses in semicircular notches in a surface hardened hollow cylindrical specimen”, J. Appl. Mech. Tech. Phys., 54:4 (2013), 644–650 | DOI

[17] Sazanov V. P., “Analysis of the mechanism of fatigue crack arrest in a cylindrical notched specimen”, Vestnik of Samara University. Aerospace and Mechanical Engineering, 17:1 (2018), 160–169 (In Russian) | DOI

[18] Radchenko V. P., Saushkin M. N., Bochkova T. I., “Mathematical modeling and experimental study of forming and relaxation of the residual stresses in plane samples made of EP742 alloy after the ultrasonic hardening under the hightemperature creep conditions”, PNRPU Mechanics Bulletin, 2016, no. 1, 93–112 (In Russian) | DOI

[19] Fleury R., Nowell D., “Evaluating the influence of residual stresses and surface damage on fatigue life of nickel superalloys”, Int. J. Fatigue, 105 (2017), 27–33 | DOI

[20] Foss B., Gray S., Hardy M., Stekovic S. [et al.], “Analysis of shot-peening and residual stress relaxation in the nickel-based superalloy RR1000”, Acta Materialia, 61:7 (2013), 2548–2559 | DOI

[21] Radchenko V. P., Afanaseva O. S., Glebov V. E., “The effect of surface plastic hardening technology, residual stresses and boundary conditions on the buckling of a beam”, PNRPU Mechanics Bulletin, 2020, no. 1, 87–98 (In Russian) | DOI

[22] Radchenko V. P., Shishkin D. M., “The influence of the dimensions of the surface hardening region on the stress-strain state of a beam with a notch of a semicircular profile”, Vestn. Samar. Gos. Tekhn. Univ., Ser. Fiz.-Mat. Nauki [J. Samara State Tech. Univ., Ser. Phys. Math. Sci.], 24:4 (2020), 663–676 (In Russian) | DOI

[23] Radchenko V. P., Eremin Yu. A., Reologicheskoe deformirovanie i razrushenie materialov i elementov konstruktsii [Rheological Deformation and Fracture of Materials and Structural Elements], Mashinostroenie-1, Moscow, 2004, 264 pp. (In Russian)