Evolution characteristics of residual stresses in medium-thick plate during thinning process
CUI Jin-xing1, HAN Shi-chao2, SUN Jian-liang1, PENG Yan1
(1. National Engineering Research Center for Equipment and Technology of Cold Strip Rolling, Yanshan University,Qinhuangdao 066004, Hebei, China; 2. Xugong Environmental Technology Co., Ltd., Xuzhou 221400, Jiangsu,China)
Abstract:The redistribution law of the transverse residual stress due to the thinning of the medium and heavy plate was studied to understand the deformation mechanism of the medium-thick plate in service. Based on the theory of the peeling method,the residual stress distribution model and the deflection deformation model in the thinning process of the medium-thick plate were established,and the plate thinning process was simulated by the finite element method. The results of the residual stress distribution and the deflection degree of the plate were compared with those of the finite element simulation,which verified the feasibility of the two methods. Furthermore,the effect of the stress distribution and the thickness reduction on the thinning process was further analyzed. The results showed that both analysis results could reflect the deformation characteristics of the plate thinning process,but the results of the finite element simulation method were more accurate,which changed the restraint state of plate with thinning process. The research results provide a theoretical basis for the rational production design and use of medium-thick plate.
崔金星, 韩世超, 孙建亮, 彭 艳. 中厚板减薄过程残余应力的演变行为[J]. 钢铁, 2019, 54(5): 39-46.
CUI Jin-xing1, HAN Shi-chao2, SUN Jian-liang1, PENG Yan1. Evolution characteristics of residual stresses in medium-thick plate during thinning process. Iron and Steel, 2019, 54(5): 39-46.
Milenin A, Kuziak R, Lech-Grega M, et al. Numerical modeling and experimental identification of residual stresses in hot-rolled strips[J]. Archives of Civil & Mechanical Engineering. 2016, 16(1): 125-134.
[7]
Milenin A, Kuziak R, Lech-Grega M, et al. Numerical modeling and experimental identification of residual stresses in hot-rolled strips[J]. Archives of Civil & Mechanical Engineering. 2016, 16(1): 125-134.
[8]
Witek S, Milenin A. Numerical analysis of temperature and residual stresses in hot-rolled steel strip during cooling in coils[J]. Archives of Civil & Mechanical Engineering. 2018, 18(2): 659-668.
[8]
Witek S, Milenin A. Numerical analysis of temperature and residual stresses in hot-rolled steel strip during cooling in coils[J]. Archives of Civil & Mechanical Engineering. 2018, 18(2): 659-668.
[9]
Morris J W, Hardy S J, Lees A W, et al. Formation of residual stresses owing to tension levelling of cold rolled strip[J]. Ironmaking & Steelmaking. 2013, 28(1): 44-52.
[9]
Morris J W, Hardy S J, Lees A W, et al. Formation of residual stresses owing to tension levelling of cold rolled strip[J]. Ironmaking & Steelmaking. 2013, 28(1): 44-52.
Guo H, Zuo D W, Yin F H, et al. Study on the Residual Stresses Distribution in Thick Pre-Stretched Aluminum Plate[J]. Key Engineering Materials. 2018, 764: 49-57.
[12]
Guo H, Zuo D W, Yin F H, et al. Study on the Residual Stresses Distribution in Thick Pre-Stretched Aluminum Plate[J]. Key Engineering Materials. 2018, 764: 49-57.
[13]
Liao K, Jing X X, Zhou Y, et al. Research of Micromechanism on Residual Stress in Aluminum Alloy Thick Plate[J]. Advanced Materials Research. 2011, 146-147: 233-237.
[13]
Liao K, Jing X X, Zhou Y, et al. Research of Micromechanism on Residual Stress in Aluminum Alloy Thick Plate[J]. Advanced Materials Research. 2011, 146-147: 233-237.
[14]
Dreier S, Denkena B. Determination of Residual Stresses in Plate Material by Layer Removal with Machine-integrated Measurement ☆[J]. Procedia Cirp. 2014, 24: 103-107.
[14]
Dreier S, Denkena B. Determination of Residual Stresses in Plate Material by Layer Removal with Machine-integrated Measurement ☆[J]. Procedia Cirp. 2014, 24: 103-107.