Ratcheting deformation in association with bulk texture evolution in HSLA steel is studied in this investigation. The cyclicdeformation behaviors and damage modes of the specimens are obtained at room temperature, employing asymmetric stresscontrolledtests under various combinations of mean stress and stress amplitudes. Bulk texture measurements of the specimensare done adopting an X-ray diffraction analysis. The results exhibit an increase in strain accumulation from 0.23 to 30.61%associated with a sharp reduction in ratcheting life from 3320 to 880 cycles by the increment in mean stress/stress amplitude.
A continuous cyclic softening until the final failure is observed for all the ratcheting tests. It is noticed that variation of meanstress is more detrimental than stress amplitude in controlling strain accumulation while the effect of stress amplitude is morepronounced than mean stress for the reduction of ratcheting life. The fracture surface morphology indicates typical striationformation in the crack propagation region along with overload failure. The bulk texture studies indicate that there is a transitionbetween ‘ϒ’ fiber and ‘ζ’ fiber during all loading conditions. The texture intensity is increased from 5.71 to 11.68 withprogressive ratcheting strain accumulation. Here also, influence of stress amplitude is more significant than the mean stress.

1 R. Kreethi, 679 : 66-, 2017

2 N. Kamikawa, 5 : 163-, 2004

3 Y. M. Liu, 743 : 314-, 2019

4 R. Jamaati, 93 : 150-, 2014

5 N. Kamikawa, 55 : 5873-, 2007

6 C. L. Xie, 126 : 339-, 2004

7 Y. W. Chung, 186 : 121-, 1994

8 P. G. Marsh, 33 : 825-, 1995

9 K. S. Chan, 222 : 1-, 1997

10 K. Kannan, 39 : 743-, 1998

11 P. L. Charpentier, 79 : 54-, 2015

12 M. Talebi, 144 : 253-, 2018

13 V. Aleksic, 104 : 1094-, 2019

14 G. Janardhan, 793 : 139796-, 2020

15 O. Fatoba, 94 : 147-, 2018

16 G. Z. Kang, 472 : 258-, 2008

17 G. Kang, 435–436 : 396-, 2006

18 S. Sinha, 28 : 1690-, 2006

19 L. Sahu, 23 : 4122-, 2014

20 K. Dutta, 575 : 127-, 2013

21 Y. C. Lin, 24 : 1820-, 2015

22 K. Kolasangiani, 144 : 24-, 2018

23 Q. Gao, 40 : 105-, 2003

24 S. K. Paul, 401 : 17-, 2010

25 Z. Xia, 18 : 335-, 1996

26 S. P. Bhat, 314 : 90-, 2001

27 C. Gaudina, 52 : 3097-, 2004

28 K. Dutta, 527 : 7571-, 2010

29 M. Holscher, 62 : 567-, 1991

30 P. S. De, 27 : 3688-, 2018

31 D. Raabe, 157-162 : 597-, 1994

32 C. L. Xie, 340 : 130-, 2003

33 Y. S. Liu, 50 : 1849-, 2002

34 J. Asensioa, 47 : 119-, 2001

35 W. B. Hutchinson, 29 : 25-, 1984

36 R. K. Ray, 39 : 129-, 1994

37 P. Van Houtte, 31 : 109-, 1999

38 R. Jamaati, 106 : 411-, 2015

39 A. Ghosh, 109 : 186-, 2016

40 A. Ghosh, 125 : 35-, 2019

41 Y. Dong, 65 : 62-, 2012

42 R. Kreethi, 98 : 2637-, 2018

43 G. Kang, 527 : 5952-, 2010

44 T. Ungar, 276 : 278-, 2000

45 R. Kreethi, 68 : 229-, 2015

46 K. Hussain, 11 : 2-, 1993

47 P. P. Sarkar, 29 : 2936-, 2020

48 G. Chen, 80 : 364-, 2015

49 B. C. De Cooman, 142 : 283-, 2018

50 R. Jamaati, 607 : 173-, 2014

51 Krishna Dutta, "On the Characteristic Features of Dislocations during Ratcheting–Creep Interaction" Springer Science and Business Media LLC 30 (30): 7376-7385, 2021

52 Qin Dong ; Ping Yang ; Geng Xu, "Low cycle fatigue and ratcheting failure behavior of AH32 steel under uniaxial cyclic loading" 대한조선학회 11 (11): 671-678, 2019

53 H. Mohrbacher, "Green and Sustainable Manufacturing of Advanced Material" Elsevier 135-163, 2015

54 S. Suresh, "Fatigue of Materials" Cambridge University Press 1998

55 R. Rana, "Automotive Steels: Design, Metallurgy, Processing and Applications" Woodhead Publishing 2017