Regularization of mathematical model for chip flow angle catastrophe

doi:10.1007/s40436-021-00369-8

Advances in Manufacturing ›› 2021, Vol. 9 ›› Issue (4): 568-579.doi: 10.1007/s40436-021-00369-8

• ARTICLES • Previous Articles

Regularization of mathematical model for chip flow angle catastrophe

Shao-Nan Zhang¹, Dong-Dong Cheng¹, Liang-Shan Xiong¹

School of Mechanical Science and Engineering, Huazhong University of Science and Technology, Wuhan 430074, People's Republic of China

Received:2021-01-10 Revised:2021-05-18 Published:2021-11-12
Contact: Liang-Shan Xiong E-mail:liangsx@hust.edu.cn
Supported by:
This study was financially supported by the National Natural Science Foundation of China (Grant No. 51675203). The authors gratefully acknowledge the assistance provided by ZiJiang Que, Wei Ding, Bao-Yi Zhu, Ming-Xian Xu, Xu Mu and Jin Hu.

Abstract

Abstract: The chip flow angle (CFA) catastrophe in double-edged cutting results in a significant reduction in the cutting force, which can benefit the applications. However, established potential functions (i.e., cutting power calculation functions) of mathematical models for the CFA catastrophe are presented in the form of transcendental functions with two control parameters and one state parameter, which are extremely complex. A method is proposed herein to realize the regularization of the potential functions and establish mathematical models in a standard form and with complete content for the CFA catastrophe. Using this method, the potential function of the CFA catastrophe is expanded into a k-order Taylor polynomial at each midpoint of N end-to-end equally partitioned intervals of the state parameter using the Taylor function provided in MATLAB. The potential function after piecewise Taylor expansion is transformed into the same form as the potential function of the standard cusp catastrophe model by truncating the first five terms of the Taylor polynomial and eliminating the third-order term of the state parameter with elementary transformation. Hence, the regularization of potential function is realized. Subsequently, the regularization of equilibrium surface and bifurcation set can be realized based on the conclusions of the catastrophe theory. Regularization errors of the potential function, equilibrium surface, and bifurcation set are defined to evaluate the effectiveness of this regularization method. The problem of calculating regularization errors is regarded as an optimization problem. The "simulannealbnd" function provided in MATLAB is used to solve the problem. Applying the proposed method, the regularization of a mathematical model for the CFA catastrophe established by the predecessor is completed; a mathematical model (i.e., standard cusp catastrophe model) in a standard form and with complete content for the CFA catastrophe is established; and the corresponding regularization errors are analyzed. The regularization errors of the potential function, equilibrium surface, and bifurcation set curves are 5.485 5 9 10^-4%, 0.320 6%, and 4.653 9%, respectively. Based on the equilibrium surface and the bifurcation set curves constructed using the regularized mathematical model for the CFA catastrophe, the mechanism of the CFA catastrophe and the specific approach to render the cutting system operable in a low-energy consumption state by controlling the historical change path of the control point are analyzed. This study will promote the rational use of the CFA catastrophe.

The full text can be downloaded at https://link.springer.com/article/10.1007/s40436-021-00369-8

Key words: Chip flow angle (CFA) catastrophe, Mathematical model, Regularization, Potential function, Catastrophe theory, Cusp catastrophe model

Shao-Nan Zhang, Dong-Dong Cheng, Liang-Shan Xiong. Regularization of mathematical model for chip flow angle catastrophe[J]. Advances in Manufacturing, 2021, 9(4): 568-579.

TrendMD

References

1. Shi H (2018) Metal cutting theory:new perspectives and new approaches. Springer International Publishing, Cham
2. Shi H, Wang X, Lu T (1998) Bifurcation and catastrophes in metal cutting processes. J Manuf Sci Eng-Trans ASME 120(4):817-820
3. Zhang W, Wang X (2001) An investigation on the nonlinear features in metal cutting process. China Mech Eng 12:1022-1024
4. Cui H, Wan X, Xiong L (2019) Modeling of the catastrophe of chip flow angle in the turning with double-edged tool with arbitrary rake angle based on catastrophe theory. Int J Adv Manuf Technol 104(5/8):2705-2714
5. Wang X, Shi H, Zhang W (2002) A study on the characteristics of vibration in non-linear cutting processes. Acta Armamentarii 23:98-101
6. Zhu B, Xiao Y, Wan X et al (2020) Theoretical modeling and experimental verification of chip flow angle catastrophe in double-edged cutting considering non-linear effects. Int J Mech Sci 172:105394. https://doi.org/10.1016/j.ijmecsci.2019.105394
7. Thom R (1972) Stabilité structurelle et Morphogénèse. Benjamin, New York
8. Saunders PT (1980) An introduction to catastrophe theory. Cambridge University Press, Cambridge, pp 17-26
9. Stewart I (1981) Applications of catastrophe theory to the physical sciences. Physica D 2(2):245-305
10. Deakin M (1980) Applied catastrophe theory in the social and biological sciences. B Math Biol 42(5):647-679
11. Klamecki BE (1982) Catastrophe theory models of chip formation. J Eng Ind 104:369-374
12. Saw L, Brooks B, Carpenter K et al (2004) Catastrophic phase inversion in region II of an ionomeric polymer-water system. J Colloid Interf Sci 279(1):235-243
13. Bao J, Yin Y, Lu Y et al (2013) A cusp catastrophe model for the friction catastrophe of mine brake material in continuous repeated brakings. P I Mech Eng, J Eng 227(10):1150-1156
14. Kounadis AN (2002) Dynamic buckling of simple two-bar frames using catastrophe theory. Int J Non-Linear Mech 37(7):1249-1259
15. Klamecki BE (1985) Experimental verification of a catastrophe theory model of metal cutting chip formation. J Eng Ind 107:77-80
16. Cubitt JM, Shaw B (1976) The geological implications of steadystate mechanisms in catastrophe theory. J Int Assoc Math Geol 8(6):657-662
17. Li Z, Zhang P, Pan T et al (2018) Hysteresis behaviors of compressor rotating stall with cusp catastrophic model. Chin J Aeronaut 31(5):1075-1084
18. Bogdan TV, Wales DJ (2004) New results for phase transitions from catastrophe theory. J Chem Phys 120(23):11090-11099
19. Abrahamyan A, Mikayelyan A, Sahakyan Q et al (2011) Using of catastrophe theory for processing of experimental results measured in low-temperature plasma. J Contemp Phys 46(4):172-176
20. Zeeman EC (1976) Catastrophe theory. Sci Am 234(4):65-83
21. Ye GG, Chen Y, Xue SF et al (2014) Critical cutting speed for onset of serrated chip flow in high speed machining. Int J Mach Tool Manuf 86:18-33
22. Oxley PLB (1989) The mechanics of machining:an analytical approach to assessing machinability. Halsted Press

[1]	Li Liu, Ao-Lei Yang, Xiao-Wei Tu, Wen-Ju Zhou, Min-Rui Fei, Jun Yue. Double regularization control based on level set evolution for tablet packaging image segmentation [J]. Advances in Manufacturing, 2015, 3(1): 73-83.
[2]	A. G. Kamble R. Venkata Rao. Experimental investigation on the effects of process parameters of GMAW and transient thermal analysis of AISI321 steel [J]. Advances in Manufacturing, 2013, 1(4): 362-377.

Regularization of mathematical model for chip flow angle catastrophe

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 2

Recommended Articles

Metrics

Comments