摘要 During the thin strip coiling process, it is necessary to use a sleeve with a mandrel to prevent excessive deformation of the strip. Stress distribution in the sleeve and in the strip is an important factor that determines the quality of the coil. However, owing to the accumulation of high pressure, it is dif.cult to determine the stress distribution through experimentation. Thus, stress analysis of the strip coiling process was conducted. Finite element analysis was used to investigate the effects of the weight of the strip and the mandrel on the stress distribution and stress concentration near the starting point of the coil. The radial stress was predicted for a coil with a stacked thickness of 384 mm, which corresponds to a strip length of 1486 m, using the stress analysis model developed in a preceding research. A method was presented to reduce the weight and radial stress of a strip coil. It was found that the deformation of the sleeve can be reduced by decreasing the gap between the mandrel segments. The thickness of the sleeve can be reduced from 120 to 106 mm using the stress analysis results. Furthermore, coiling tension can be reduced by 44% compared to the existing value considering the interlayer slip of the strip coil.
Abstract:During the thin strip coiling process, it is necessary to use a sleeve with a mandrel to prevent excessive deformation of the strip. Stress distribution in the sleeve and in the strip is an important factor that determines the quality of the coil. However, owing to the accumulation of high pressure, it is dif.cult to determine the stress distribution through experimentation. Thus, stress analysis of the strip coiling process was conducted. Finite element analysis was used to investigate the effects of the weight of the strip and the mandrel on the stress distribution and stress concentration near the starting point of the coil. The radial stress was predicted for a coil with a stacked thickness of 384 mm, which corresponds to a strip length of 1486 m, using the stress analysis model developed in a preceding research. A method was presented to reduce the weight and radial stress of a strip coil. It was found that the deformation of the sleeve can be reduced by decreasing the gap between the mandrel segments. The thickness of the sleeve can be reduced from 120 to 106 mm using the stress analysis results. Furthermore, coiling tension can be reduced by 44% compared to the existing value considering the interlayer slip of the strip coil.
KYU-TAE -PARK,HYUNCHUL. Effects of design parameters and tension on behavior of a coil using finite element analysis[J]. Journal of Iron and Steel Research International, 2018, 25(9): 883-891.
[1]
B Anderssen, N Fowkes, R Hickson and M McGuinness.Analysis of coil slumping[J].Twenty sixth MISG, Wollongong, 2009, -(-):90-108
[2]
JS Lee, KH Shin, HK Kang and SS Park.An analysis of tension at rewinding process considering mechanical property change in roll to roll system[J].Proc. Korean Society Of Precision Engineering, 2010,-(-) :257-258
[3]
SJ Burns,RR Meehan and JC Lambropoulos.Strain-based formulas for stresses in profiled center-wound rolls[J].Tappi Journal, 1999, 82(7):159-167
[4]
RC Benson.A nonlinear wound roll model allowing for large deformation[J].ASME J. Appl. Mech, 1995, 62(-):853-859
[5]
N Zabaras and S Liu. A theory for small deformation analysis of growing bodies with an application to the winding of magnetic tape packs[J].Acta mechanica, 1995, 111(1):95-110
[6]
Z Hakiel. Nonlinear model for wound roll stress[J].Tappi Journal, 1987, 70(5):113-117
[7]
HC Altmann. Formulas for computing stresses in center-wound rolls[J].Tappi Journal, 1968, 51(4):176-179
[8]
XL Yu, Q Yang and ZY Jiang.Analysis of plate bending in coilbox by finite element method[J].Key Engineering Materials, 2010, 443(-):146-151
[9]
RB Sims and JA Place.The stresses in the reels of cold reduction mills[J].British Journal of Applied Physics, 1953, 4(7):213-216.
[10]
J Case. The Strength of Materials(Second Edition)[J]. Edward Arnold & Co. London, 2014,-(-):437-455.
[11]
I Doghri. Mechanics of Deformable solids: Linear and Nonliear Analytical and Computational Aspects[J]. Springer e-book, 2000,-(-): 206-209.
[12]
S Yanagi, S Hattori and Y Maeda. Coil deformation and flatness change through strip coiling process[J]. Proc. 7th International Conference on Steel Rolling, 1998, -(-):150-155.
[13]
S Yanagi, S Hattori and Y Maeda. Analysis model for deformation of coil of thin strip under coiling process[J]. J. JSTP, 1998, 39(444):51-55.
[14]
WW Park, DK Kim, YT Lim, HC Kwon, DK Choi and MS Chun. Stress analysis for strip coiling process based on elastic model[J]. Proc. KSPE, 2012, -(-):273-276.
[15]
WW Park, DK Kim, YT Im, HC Kwon and MS Chun. Effects of processing parameters on elastic deformation of the coil during the thin-strip coiling process[J]. Metals and Materials International, 2014, 20(4):719-726.
[16]
YH Park, KT Park, SY Won, WK Hong and HC Park. Stress analysis model of strip winding system including a sleeve for a coil of thin stainless steel[J]. Journal of Iron and Steel Research,2017, 24(1):1-7.
[17]
J Lubliner. Plasticity Theory[J]. Dover Publications. INC. Newyork, 2005, -(-):80-85.
[18]
KT Park, YH Park, KS Kim, SY Won, WK Hong, MS Chun and HC Park. Identification of mechanism and development of finite element analysis model for cold rolled strip coiling process[J]. Proc. of KSME Autumn Conference, 2015, -(-):1416-1420.
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