Influence of welding residual stresses on the ductile crack growth resistance of circumferentially cracked pipe

Xiaobo REN; Odd M. AKSELSEN; Bård NYHUS; Zhiliang ZHANG

doi:10.1007/s11709-012-0169-3

Front. Struct. Civ. Eng. ›› 2012, Vol. 6 ›› Issue (3) : 217 -223. DOI: 10.1007/s11709-012-0169-3

RESEARCH ARTICLE

Influence of welding residual stresses on the ductile crack growth resistance of circumferentially cracked pipe

Author information +

History +

PDF (238KB)

Abstract

Welding residual stress is one of the main concerns for fabrication and operation of steel structures due to its potential effect on structural integrity. This paper focuses on the effect of welding residual stress on the ductile crack growth resistance of circumferentially cracked steel pipes. Two-dimensional axi-symmetry model has been used to simulate the pipe. Residual stresses were introduced into the model by using so-called eigenstrain method. The complete Gurson model has been employed to calculate the ductile crack growth resistance. Results show that residual stresses reduce the ductile crack growth resistance. However, the effect of residual stresses on ductile crack growth resistance decreases with the increase of crack growth. The effect of residual stress has also been investigated for cases with different initial void volume fraction, material hardening and crack sizes.

Keywords

residual stress / ductile crack growth resistance / complete Gurson model / eigenstrain method

Cite this article

Download citation ▾

Xiaobo REN, Odd M. AKSELSEN, Bård NYHUS, Zhiliang ZHANG. Influence of welding residual stresses on the ductile crack growth resistance of circumferentially cracked pipe. Front. Struct. Civ. Eng., 2012, 6(3): 217-223 DOI:10.1007/s11709-012-0169-3

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Sherry A H, Wilkes M A, Sharples J K and Budden P J. The assessment of residual stress effects on ductile tearing using continuum damage mechanics. Journal of Pressure Vessel Technology, 2008. 130(4): 041212-1-8

[2]	Liu J, Zhang Z L, Nyhus B. Residual stress induced crack tip constraint. Engineering Fracture Mechanics, 2008, 75(14): 4151-4166

[3]	Ren X B, Zhang Z L, Nyhus B. Effect of residual stresses on the crack-tip constraint in a modified boundary layer model. International Journal of Solids and Structures, 2009, 46(13): 2629-2641

[4]	Ren X B, Zhang Z L, Nyhus B. Effect of residual stresses on ductile crack growth resistance. Engineering Fracture Mechanics, 2010, 77(8): 1325-1337

[5]	Sharples J K, France C C, Ainsworth R A. Experimental validation of R6 treatment of residual stresses. ASME Press Vessels Piping, 1999, 392: 225-238

[6]	Mahmoudi A, Truman C, Smith D. Using local out-of-plane compression (LOPC) to study the effects of residual stress on apparent fracture toughness. Engineering Fracture Mechanics, 2008, 75(6): 1516-1534

[7]	Ueda Y, Nakacho K, Yuan M. A new measuring method of residual stresses with the aid of finite element method and reliability of estimated values. Trans. Japan Welding Research Institute, 1975, 4(2): 123-131

[8]	Zhang Z L, Thaulow C, Ødegård J. A complete Gurson model approach for ductile fracture. Engineering Fracture Mechanics, 2000, 67(2): 155-168

[9]	Gurson A L. Gurson, Continuum theory of ductile rupture by void nucleation and growth: part I-yield criteria and flow rules for porous ductile media. Journal of Engineering Materials and Technology, 1977, 99(1): 2-15

[10]	Tvergaard V. Influence of voids on shear band instabilities under plane strain conditions. International Journal of Fracture, 1981, 17(4): 389-407

[11]	Tvergaard V. On localization in ductile materials containing spherical voids. International Journal of Fracture, 1982, 18(4): 237-252

[12]	Tvergaard V, Needleman A. Analysis of the cup-cone fracture in a round tensile bar. Acta Metallurgica, 1984, 32(1): 157-169

[13]	Thomason P. Ductile Fracture of Metals. 1990, Pergamon

[14]	Østby E, Thaulow C, Zhang Z L. Numerical simulations of specimen size and mismatch effects in ductile crack growth–Part I: Tearing resistance and crack growth paths. Engineering Fracture Mechanics, 2007, 74(11): 1770-1792

[15]	Zhang Z L, Niemi E. A class of generalized mid-point algorithms for the Gurson–Tvergaard material model. International Journal for Numerical Methods in Engineering, 1995, 38(12): 2033-2053

[16]	Zhang Z L, Niemi E. A new failure criterion for the Gurson-Tvergaard dilational constitutive model. International Journal of Fracture, 1995, 70(4): 321-334

[17]	Zhang Z L, Niemi E. Studies on the ductility predictions by different local failure criteria. Engineering Fracture Mechanics, 1994, 48(4): 529-540

[18]	Zhang Z L. On the accuracies of numerical integration algorithms for Gurson-based pressure-dependent elastoplastic constitutive models. Computer Methods in Applied Mechanics and Engineering, 1995, 121(1-4): 15-28

[19]	Zhang Z L. Explicit consistent tangent moduli with a return mapping algorithm for pressure-dependent elastoplasticity models. Computer Methods in Applied Mechanics and Engineering, 1995, 121(1-4): 29-44

[20]	Hill M R. Determination of residual stress based on the estimation of eigenstrain. <DissertationTip/> Stanford University, 1996

[21]	Mochizuki M, Hayashi M, Hattori T. Residual stress analysis by simplified inherent strain at welded pipe junctures in a pressure vessel. Journal of Pressure Vessel Technology, 1999, 121(4): 353-357

[22]	Xu J, Zhang Z L, Østby E, Nyhus B, Sun D B. Effects of crack depth and specimen size on ductile crack growth of SENT and SENB specimens for fracture mechanics evaluation of pipeline steel. International Journal of Pressure Vessels and Piping, 2009, 86(12): 787-797

[23]	Xu J, Zhang Z L, Østby E, Nyhus B, Sun D B. Constraint effect on the ductile crack growth resistance of circumferentially cracked pipes. Engineering Fracture Mechanics, 2010, 77(4): 671-684