Published date: Apr 15 2019

Journal Title: KnE Engineering

Issue title: XIX International scientific-technical conference “The Ural school-seminar of metal scientists-young researchers”

Pages: 135–144

DOI: 10.18502/keg.v1i1.4401

Shimov Georgy

The paper describes the method of the metal surface layer etching from the pipes and the measurement of elastic relaxation for the analysis of the residual stresses of cold-rolled stainless steel pipes. The results of the experimental determination of the residual stresses of pipes made of steel AISI 321 are given.

Keywords: residual stresses, measurement of residual stresses, stresses distribution, tubes for nuclear steam generators, etching, experimental installation

[1] Schajer, G. S. (2013). Practical residual stress measurement methods. Practical residual stress measurement methods (pp. 1-310) doi:10.1002/9781118402832


[2] Withers, P. J., & Bhadeshia, H. K. D. H. (2001). Residual stress part 1 - measurement techniques. Materials Science and Technology, 17(4), 355-365. doi:10.1179/026708301101509980


[3] Withers, P. J., & Bhadeshia, H. K. D. H. (2001). Residual stress part 2 - nature and origins. Materials Science and Technology, 17(4), 366-375. doi:10.1179/026708301101510087


[4] Sokolov I.A. Residual stresses and quality of metal products / I.A. Sokolov, V.I. Uralskii. - M.: Metallurgy, 1981. - 96 p.


[5] Da Silva, L. L., Ribeiro, V. S., Scaldaferri, D. H. B., Rabello, E. G., Campos, W. R. C., & Mansur, T. R. (2016). Development and test of an equipment to measure residual strain inside pipes using the hole-drilling method. Latin American Journal of Solids and Structures, 13(13), 2439-2450. doi:10.1590/1679-78253126


[6] De Abreu Mendonça Schvartzman, M. M., Quinan, M. A. D., da Costa Campos, W. R., & Lima, L. I. L. (2011). Stress corrosion cracking of the aisi 316l stainless steel haz in a pwr nuclear reactor environment. Welding International, 25(1), 15-23. doi:10.1080/09507110903569073.


[7] Hu, J., Chen, B., Smith, D., Flewitt, P., & Cocks, A. C. F. (2013). A self-consistent model in the local residual stress evaluation of 316H stainless steel. Paper presented at the 13th International Conference on Fracture 2013, ICF 2013, 4, 3351-3360.


[8] James, Malcolm & Hattingh, D.G. & Asquith, David & Newby, Mark & Doubell, Philip. (2016). Applications of Residual Stress in Combatting Fatigue and Fracture. Procedia Structural Integrity. 2. 11-25. 10.1016/j.prostr.2016.06.003.


[9] M.A. Rozenbaum, A.V. Serebryakov, I. Bazhukov, G.V. Shimov. Study of Residual Stresses and Surface Hardening in Tubes for Nuclear Steam Generators. Solid State Phenomena. 2018. Vol. 265, pp. 53-59. doi:10.4028/www.scientific.net/SSP.265.53.


[10] Shimov G.V. Rapid Method for Determining the Distribution of Residual Patterns in Pipes. Materials Performance and Characterization. Vol. 4, No. 7, 2018. doi: 10.1520 / MPC20170050


[11] Kolmogorov G.L., Kuznetsova E.V., Tiunov V.V. Technological residual stresses and their impact on the durability and reliability of metal products. Perm: Publishing House Perm National Research Polytechnic University, 2012. - 226 p.


[12] Shimov, G., Rozenbaum, M., Serebryakov, A., & Serebryakov, A. (2016). The method for measuring residual stress in stainless steel pipes. Journal of Chemical Technology and Metallurgy, 51(4), 458-464.