Simulation of ridge-buckle control model in coiling process of strip steel
GUAN Jian-long1,HE An-rui1,SUN Wen-quan1,GUO Rui2
1. Metallurgy Engineering Research Institute, University of Science and Technology Beijing, Beijing 100083,China 2. Sheet-Metal Workshop, Capital Aerospace Machinery Company, Beijing 100076, China)
Abstract:In order to research the ridge-buckle control method in coiling process of strip steel with local high point, the study obtained the stress field distribution of ridge-buckle based on the hypothesis about stress function and the S. Timoshenko least work principle, and established the buckling critical coiling tension setting model and buckling elastic limit model that both can be calculated online using the theory of Galerkin virtual displacement. The simulation of stress field distribution and factors on critical coiling tension show that uneven distribution of strip steel tension caused by radial accumulation of local high points is the main cause of strip ridge-buckle; critical coiling tension decreases with the increase of the thickness of strip, height of local high points and coiling radius, respectively. The influence of strip width is small. The?computational accuracy and feasibility of this model is confirmed by the comparison of actual production control method and ANSYS finite element method results.
管健龙,何安瑞,孙文权,郭 睿. 带钢卷取过程起筋控制的建模与仿真[J]. 钢铁, 2015, 50(11): 63-68.
GUAN Jian-long,HE An-rui,SUN Wen-quan,GUO Rui. Simulation of ridge-buckle control model in coiling process of strip steel. Iron and Steel, 2015, 50(11): 63-68.
Melfo W M, Dippenaar R J, Carter C D, et al. Ridge-buckle defect in thin-rolled steel strip[J]. Iron Steel Technology. 2006, 87(3): 54.
[1]
Melfo W M, Dippenaar R J, Carter C D, et al. Ridge-buckle defect in thin-rolled steel strip[J]. Iron Steel Technology. 2006, 87(3): 54.
[2]
靳月华.冷轧带钢起筋问题研究[D].北京:北京科技大学硕士学位论文, 2007.
[2]
靳月华.冷轧带钢起筋问题研究[D].北京:北京科技大学硕士学位论文, 2007.
[3]
Zhu H T, Tieu A K, Dippenaar R J, et al.A mathematic model for the prediction of ridge deformation in cold rolling[J]. Steel Research. 2008, 79 (11): 424.
[3]
Zhu H T, Tieu A K, Dippenaar R J, et al.A mathematic model for the prediction of ridge deformation in cold rolling[J]. Steel Research. 2008, 79 (11): 424.
[4]
Jung Y J , Lee G T, Kang C G, et al. Coupled thermal deformation analysis considering strip tension and with/without strip crown in coiling process of cold rolled strip[J]. Journal of Materials Processing Technology. 2012, 130 (4): 195.
[4]
Jung Y J , Lee G T, Kang C G, et al. Coupled thermal deformation analysis considering strip tension and with/without strip crown in coiling process of cold rolled strip[J]. Journal of Materials Processing Technology. 2012, 130 (4): 195.
WANG Yong-qin. Modeling of Stress Distribution During Strip Coiling Process[J]. Journal of Iron and Steel Research, International. 2012, 19 (8): 6.
[7]
WANG Yong-qin. Modeling of Stress Distribution During Strip Coiling Process[J]. Journal of Iron and Steel Research, International. 2012, 19 (8): 6.
[8]
Zhu H T. Effect of hot coil profile containing ridges on ridge-buckle defects of cold rolled thin strip[J]. International Journal of Material Forming. 2010, 24 (3): 21.
[8]
Zhu H T. Effect of hot coil profile containing ridges on ridge-buckle defects of cold rolled thin strip[J]. International Journal of Material Forming. 2010, 24 (3): 21.
[9]
QIN Jian, ZHANG Qing-dong, HUANG Ke-fu, et al. Nonlinear Spline Finite Element Method for Ribbing of Cold-Rolled Coils[J]. Journal of Iron and Steel Research, International. 2012, 19 (1): 36.
[9]
QIN Jian, ZHANG Qing-dong, HUANG Ke-fu, et al. Nonlinear Spline Finite Element Method for Ribbing of Cold-Rolled Coils[J]. Journal of Iron and Steel Research, International. 2012, 19 (1): 36.
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