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International Journal of Material Forming

Erschienen in:

16.05.2021 | Original Research

Research on iterative compensation method for springback control based on implicit equation

verfasst von: Zhenkai Mu, Rui Ma, Jun Zhao, Gaochao Yu, Honglei Sun

Erschienen in: International Journal of Material Forming | Ausgabe 5/2021

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Abstract

The parameter solving method for springback control mainly depends on theoretical models and numerical simulation. However, many assumptions are adopted in the theoretical model, which inevitably lead to prediction error in practical application. Therefore, for bending and straightening process, a difference iterative compensation method and secant iterative compensation method based on the implicit equation were proposed. In these methods, the deflection and curvature were taken as the control parameter of iterative compensation, and the convergence of deflection was also verified by theory. According to the proposed iterative compensation strategy, an automatic straightening equipment was developed. On this basis, the bending and straightening of shafts and stretch-bending experiments were carried out to demonstrate the efficiency and reliability of the proposed iterative compensation strategy. The results show that the iterative compensation methods can predict the next compensation value based on the springback value of each tests, so that the target value with the error of less than 2% can be obtained with 2–3 iterations. Moreover, the proposed methods are independent on the material properties and mechanical model, and has high convergence precision for the springback compensation problem.

Vorheriger Artikel Mechanical characterization of glass and jute fiber-based hybrid composites fabricated through compression molding technique

Nächster Artikel Homogenization of the interfacial bonding of compound-cast AA7075/6060 bilayer billets by co-extrusion

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Cui F (2002) Straightening theory and straightening machine. Metallurgical Industry Press, Beijing

Zhang Z, Yan Y, Yang H (2013) The straightening curature-radius model for the thin-walled tube and it’s validation. J Mech Eng 49(21):160–167CrossRef

Ma GS, Tian YQ, Wang HL (2013) Study of load-deflection model of pressure straightening process for thick-walled steel pipe. J Netshape Form Eng 5(01):8–11

Chen ZX, Cheng H, Yang K (2007) A method of the calculation of straightening stroke for automatic precise pressure straightening. J East China Jiao tong U 02:127–130

Li J, Zou HJ, Xiong GL, Wang XM (2005) Research on theoretical model of press straightening process and its experiment (in Chinese). J Mech Strength 27(5):636–639

Lu H, Ling H, Leopold J, Zhang X, Guo C (2009) Improvement on straightness of metal bar based on straightening stroke-deflection model. Sci China Ser E 52(7):1866–1873CrossRef

Zhao J, Song X, Cao H, Liu J (2014) Principle of multi-point bending one-off straightening process for longitudinally submerged arc welding pipes. J Mech Eng 50(2):92–97CrossRef

Zhao J, Cao H, Zhan P, Ma R (2012) Pure bending equivalent principle for over-bend straightening and its experimental verification. J Mech Eng 48(8):28–33CrossRef

Jiang S, He X, Yang D (2006) Straightening technology based on displacement control. J Comput Appl 30(9):2464–2466

10.

Li J, Xiong GL (2007) Study on calculation method of press straightening stroke based on straightening process model. Key Eng Mater 63

11.

Wang K, Wang B, Yang C (2011) Research on the multi-step straightening for the elevator guide rail. Proce Eng 16:459–466CrossRef

12.

Lu H, Xiong X (2016) Research on straightening process model based on iteration and self-learning. Ind Electron Appl

13.

Kim SC, Chung SC Synthesis of the multi-step straightness control system for shaft straightening processes. Mechatronics 12(1):139–156

14.

Yi JG, Wang ZH, Liu JT, Jiang HY (2007) Study on on-line intelligent measurement and control system of shaft parts' precision straightening machine. Int Con Electron Meas Ins IEEE 2:640–643

15.

Liu JT, Yi JG, Jiang HY, Xing YZ, Wang L (2007) Study of control and measurement system for precision straightening machine. Int Symp Test Meas 1-75:261–5264

16.

Zheng H, Han ZR, Chen J, Wang GD (2010) Experimental investigation on shaft straightening based on laser cladding, in Chinese. J Northeastern U 31(12):1729–1732

17.

Świć A, Draczew A, Gola A (2016) Technology of heat treating-straightening of long shafts with low rigidity. Adv Sci Tech 10(31):207–214

18.

Wang C, Yu G, Wang W, Zhao J (2018) Deflection detection and curve fitting in three-roll continuous straightening process for LSAW pipes. J Mater Process Technol 255:150–160CrossRef

19.

Cheng HS, Cao J, Xia ZC (2007) An accelerated springback compensation method. Int J Mech Sci 49(3):267–279CrossRef

20.

Zhang QF, Cai ZY, Zhang Y (2013) Springback compensation method for doubly curved plate in multi-point forming. Mater Design 47:377–385CrossRef

21.

Weiher J, Rietman B, Kose K (2004) Controlling springback with compensation strategies. AIP Con ProcCrossRef

22.

Karafillis AP, Boyce MC (1992) Tooling design in sheet metal forming using springback calculations. Int J Mech Sci 34(2):113–131CrossRef

23.

Karafillis AP, Boyce MC (1996) Tooling and binder design for sheet metal forming processes compensating springback error. Int J Mach Tool Manu 36(4):503–526CrossRef

24.

Wei G, Wagoner RH (2004) Die design method for sheet springback. Int J Mech Sci 46(7):1097–1113CrossRef

25.

Lingbeek R, Huétink J, Ohnimus S, Petzoldt M, Weiher J (2005) The development of a finite elements based springback compensation tool for sheet metal products. J Mater Process Tech 169(1):115–125CrossRef

26.

Nie X, Cheng A, Shen D, Zhong Z (2009) Springback calculation and compensation system based on rail member panel. J Mech Eng 45(7):194–198CrossRef

27.

Yang X, Ruan F (2011) A die design method for springback compensation based on displacement adjustment. Int J Mech Sci 53(5):399–406CrossRef

28.

Yang X, Ruan F (2012) Compensation direction for die-face adjustment based on springback compensation. J Jilin U (Eng Tech) 42(1):103–108

29.

Cafuta G, Mole N, Štok B (2012) An enhanced displacement adjustment method: Springback and thinning compensation. Mater Design 40(3):476–487CrossRef

30.

Liao J, Xue X, Zhou C, Barlat F, Gracio JJ (2013) A springback compensation strategy and applications to bending cases[J]. Steel Res Int 84(5):463–472CrossRef

31.

Sun S, Liu Y, Li G (2013) The development of high strength steel stamping springback geometry compensation system based on CATIA. J Netshape Form Eng 5(2):1–5

32.

Zhang Z, Wu J, Zang S, Wang M, Guo R, Guo S (2015) A new iterative method for springback control based on theory analysis and displacement adjustment. Int J Mech Sci 105:330–339CrossRef

33.

Zhang Z, Ma R, Wang C, Zhao J (2019) Research on springback control in stretch bending based on iterative compensation method. Math Probl Eng

Titel: Research on iterative compensation method for springback control based on implicit equation
verfasst von: Zhenkai Mu
Rui Ma
Jun Zhao
Gaochao Yu
Honglei Sun
Publikationsdatum: 16.05.2021
Verlag: Springer Paris
Erschienen in: International Journal of Material Forming / Ausgabe 5/2021
Print ISSN: 1960-6206
Elektronische ISSN: 1960-6214
DOI: https://doi.org/10.1007/s12289-021-01625-9

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