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Structure Optimization of Wheel Force Transducer Based on Natural Frequency and Comprehensive Sensitivity

Zeitschrift:: Chinese Journal of Mechanical Engineering > Ausgabe 4/2017

Autoren:: Xiao-Long Zhang, Ti Wu, Yan Shao, Jian Song

Abstract

The current research of wheel force transducer (WFT) mainly focuses on test signal processing and decoupling methods based on signal itself, while the WFT structure optimization research related to decreasing the mass and increase the natural frequency and comprehensive sensitivity is not enough. In order to improve the WFT test accuracy, a structure optimization method based on natural frequency and comprehensive sensitivity indicators is put forward. The WFT with 8-beam elastic body is used for the finite element modeling (FEM), in which the following variations are taken into consideration: the connection type of elastic body with modified rim, the number of connection holes, and the respects of strain beam including the shape, the cross sectional area and the length, etc.. The test results shows that the natural frequency of the connecting block type is increased by 65.5% compared with the connecting seat type of elastic body & modified rim, and the main channel sensitivity is improved as well. The results show that the connecting block type will achieve the best comprehensive performance when the number of connecting holes between the elastic body and the modified rim is 20. And the thinner and longer strain beam with smaller cross section area is preferable within the scope of elastic body mechanical strength. This research proposes a novel structure optimization method for WFT which contributes to improve the measurement performance of WFT.

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AT Van Zanten, R Erhardt, G Pfaff, et al. Control aspects of the Bosch-VDC. International Symposium on Advanced Vehicle Control, Aachen, Germany, June 24–28, 1996: 576–607.

Jie Chen, Jian Song, Liang Li, et al. A novel pre-control method of vehicle dynamics stability based on critical stable velocity during transient steering maneuvering. Chinese Journal of Mechanical Engineering, 2016, 29(3): 475–485.

Jian-Qiu Li, Zi-You Song, Yin-Tao Wei, et al. Influence of tire dynamics on slip ratio estimation of independent driving wheel system. Chinese Journal of Mechanical Engineering, 2014, 27(6): 1203–1210.

Li Liu, Shu-Ming Shi, Shui-Wen Shen, et al. Vehicle planar motion stability study for tyres working in extremely nonlinear region. Chinese Journal of Mechanical Engineering, 2010, 23(2): 185–194.

Jian Wu, Ya-Hui Liu, Feng-Bo Wang, et al. Vehicle active steering control research based on two-DOF robust internal model control. Chinese Journal of Mechanical Engineering, 2016, 29(4): 739–746.

S C Ergen, A Sangiovanni-Vincentelli, X Sun, et al. The tire as an intelligent sensor. IEEE Transactions on Computer-aided Design of Integrated Circuits and Systems, 2009, 28(7): 941–955.

M Salaani. Analytical tire forces and moments model with validated data. SAE Technical Paper 2007-01-0816, 2007.

Xiao-Long Zhang, Neng-Lian Feng, Wei-Gong Zhang. Experimental research on the ABS performance based on the wheel forces measured by roadway test. China Mechanical Engineering, 2008, 19(6): 751–755. (in Chinese).

Liang Li, Jian Song, Hui-Yi Wang, et al. Fast estimation and compensation of the tire force in real time control for vehicle dynamic stability control system. Int. J. of Vehicle Design, 2008, 46(3–4): 208–229.

10.

Liang Li, Hong-Zhi Li, Xiao-Long Zhang, et al. Real-time tire parameters observer for vehicle dynamics stability control. Chinese Journal of Mechanical Engineering, 2010, 23(5): 620–626.

11.

Li-Hang Feng, Guo-Yu Lin, Wei-Gong Zhang, et al. Design and optimization of a self-decoupled six-axis wheel force transducer for a heavy truck. Proceedings of the Institution of Mechanical Engineers Part D: J. Automobile Engineering, 2015, 229(12): 1585–1610.

12.

W Weiblen, T Hofmann. Evaluation of different designs of wheel force transducers. SAE Technical Paper 980262, 1998.

13.

W Weiblen, H Kockelmann, H Burkard, et al. Evaluation of different designs of wheel force transducers (Part II). SAE Technical Paper 1999-01-1037, 1999.

14.

G S KIM. The design of a six-component force/moment sensor and evaluation of its uncertainty. Measurement Science and Technology, 2001, 12 (9), 1445–1455.

15.

M Herrmann, M Temkin, L Black, et al. The mechanical properties of wheel force sensors and their impact on to the data collected – a detailed consideration of specific tests. SAE Technical Paper 2006-01-0734, 2006.

16.

M Herrmann, D Barz, W Evers, et al. An evaluation of the mechanical properties of wheel force sensors and their impact on to the data collected during different driving manoeuvres. SAE Technical Paper 2005-01-0857, 2005.

17.

Xiao-Long Zhang, Neng-Lian Feng, Wei-Gong Zhang, et al. Research on static decoupling methods for self-developed multi-component wheel force transducer. Transactions of the Chinese Society for Agricultural Machinery, 2008, 39(4):18–23. (in Chinese).

18.

Guo-Yu Lin, Han Pang, Wei-Gong Zhang, et al. A self-decoupled three-axis force sensor for measuring the wheel force. Proceedings of the Institution of Mechanical Engineers, Part D: J. Automobile Engineering, 2014, 228(3): 319–334.

19.

Guo-Yu Lin, Dong Wang, Wei-Gong Zhang, et al. Research on the online initial value calibration method for the wheel force transducer. IEEE Sensor Journal, 2015, 15(2): 1043–1054.

20.

Yu Wang, Wei-Gong Zhang, Hai Wang. Application of wavelet method with nonlinear threshold control in vehicle wheel force signal denoising. Proceedings of the 4th International Conference on Intelligent Computation Technology and Automation (ICICTA 2011), Shenzhen, China, March 28–29, 2011: 957–960.

21.

Dong Wang, Guo-Yu Lin, Wei-Gong Zhang, et al. Design of real-time filter for the wheel force transducer. Sensor Review, 2015, 35(2): 174–182.

22.

Dong Wang, Guo-Yu Lin, Wei-Gong Zhang, et al. Angle error compensation in wheel force transducer. Measurement, 2016, 77: 203–212.

23.

Dong Wang, Guo-Yu Lin, Wei-Gong Zhang, et al. The new method of initial calibration with the wheel force transducer. Sensor Review, 2014, 34(1): 98–109.

24.

Li-Hang Feng, Guo-Yu Lin, Wei-Gong Zhang, et al. The inertial effect of acceleration fields on a self-decoupled wheel force transducer. Latin American Journal of Solids and Structures, 2015, 12(8): 1448–1461.

25.

Xiao-Long Zhang, Liang Li, Shan Jiang, et al. Effect of wheel force transducer’s mass on measurement precision and whole vehicle stability. Chinese Journal of Mechanical Engineering, 2012, 48(22): 121–126. (in Chinese).

26.

H B Pacejka. Tyre and vehicle dynamics (Second Edition). Oxford: Butterworth-Heinemann, 2006.

27.

Wei-Gong Zhang. The Study of automobile road experiment system based on multi-component wheel Force Transducer. Nanjing: Southeast University, 2001. (in Chinese).

28.

Michigan Scientific Corporation. Wheel force transducer, 6-axis model LW12.8. [2013-12-10]. http://www.michsci.com/pdf/LW12_8.pdf.

Titel: Structure Optimization of Wheel Force Transducer Based on Natural Frequency and Comprehensive Sensitivity
Autoren:: Xiao-Long Zhang
Ti Wu
Yan Shao
Jian Song
Publikationsdatum: 16.05.2017
DOI: https://doi.org/10.1007/s10033-017-0149-6
Verlag: Chinese Mechanical Engineering Society
Zeitschrift: Chinese Journal of Mechanical Engineering
Ausgabe 4/2017
Print ISSN: 1000-9345
Elektronische ISSN: 2192-8258

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