Your browser does not support JavaScript!
http://iet.metastore.ingenta.com
1887

access icon free Multi-objective optimisation of electro–hydraulic braking system based on MOEA/D algorithm

  • Author(s): Chunyan Wang 1, 2 ; Wanzhong Zhao 1, 2 ; Wenkui Li 1 ; Leiyan Yu 3
    • View affiliations
  • Source: Volume 13, Issue 1, January 2019, p. 183 – 193
    DOI:  10.1049/iet-its.2018.5090 , Print ISSN 1751-956X, Online ISSN 1751-9578
© The Institution of Engineering and Technology
Received 30/03/2018, Accepted 10/08/2018, Revised 21/07/2018, Published 07/09/2018

The electro–hydraulic composite braking system of the electric vehicle can effectively collect the wasted energy by the regenerative braking to improve the endurance mileage. In this study, according to the characteristic of the electro–hydraulic composite braking system, the energy flow processes are analysed, which includes the energy recovery generated by motor regenerative braking and energy consumption of the hydraulic braking system, such as hydraulic pump, brake line and brake valve. Based on this, the brake sense, energy recovery and loss are proposed as the evaluation index, and their quantitative formula are derived. Taking the brake sense and energy as the optimisation objectives, and ECE regulations as the constraints, the parameters of electro–hydraulic composite braking system are optimised-based on a multi-objective evolutionary algorithm based on decomposition (MOEA/D). The simulation results show that the electro–hydraulic composite braking system optimised by the MOEA/D algorithm can decrease the energy loss and make the driver obtain a better brake sense, which improves the comprehensive performance of the system. The research of this study can provide a certain basis for the design and optimisation of electro–hydraulic composite braking system.

Inspec keywords: regenerative braking; brakes; valves; evolutionary computation; optimisation; electric vehicles; electric motors

Other keywords: brake sense; hydraulic pump; energy loss; multiobjective evolutionary algorithm-based-on-decomposition; endurance mileage; brake valve; ECE regulations; electro-hydraulic composite braking system; brake line; electric vehicle; evaluation index; motor regenerative braking; multiobjective optimisation; optimisation objectives; MOEA-D algorithm; energy recovery; energy flow processes; energy consumption

Subjects: Optimisation techniques; Optimisation; Fluid mechanics and aerodynamics (mechanical engineering); a.c. machines; Mechanical components; Transportation

References

    1. 1)
      • 10. Kim, D.H., Kim, H.S.: ‘Vehicle stability control with regenerative braking and electronic brake force distribution for a four-wheel drive hybrid electric vehicle’, Proc. IMechE D, Automob. Eng., 2006, 220, pp. 683693.
    2. 2)
      • 5. Li, L., Zhang, Y., Yang, C., et al: ‘Model predictive control-based efficient energy recovery control strategy for regenerative braking system of hybrid electric bus’, Energy Convers. Manage., 2016, 111, pp. 115.
    3. 3)
      • 1. Ren, G., Ma, G., Cong, N.: ‘Review of electrical energy storage system for vehicular applications’, Renew. Sust. Energy Rev., 2015, 41, (C), pp. 225236.
    4. 4)
      • 14. Cai, J.W., Chu, L., Wei, W.R., et al: ‘Analysis of influence factors on braking energy recovery of pure electric vehicle’, Appl. Mech. Mater., 2014, 494–495, pp. 214218.
    5. 5)
      • 7. Chen, L., Zhang, J., Li, Y., et al: ‘Mechanism analysis and evaluation methodology of regenerative braking contribution to energy efficiency improvement of electrified vehicles’, Energy Convers. Manage., 2015, 92, pp. 469482.
    6. 6)
      • 18. Liu, Y, Sun Z, C, Ji W, B.: ‘Brake pedal feeling and its influencing factors for electro–hydraulic brake system’, Jilin Daxue Xuebao, 2015, 45, (4), pp. 10491055.
    7. 7)
      • 22. Qin, Y., Zhao, F., Wang, Z., et al: ‘Comprehensive analysis for influence of controllable damper time delay on semi-active suspension control strategies’, J. Vib. Acoust., 2017, 139, (3), 031006, pp. 112.
    8. 8)
      • 8. Bin Peeie, M.H., Ogino, H., Yamamoto, Y.: ‘Skid control of small electric vehicles with in-wheel motors (effect of ABS and regenerative brake timing control on emergency braking)’, Appl. Mech. Mater., 2015, 789–790, pp. 927931.
    9. 9)
      • 9. Xu, G., Xu, K., Zheng, C., et al: ‘Fully electrified regenerative braking control for deep energy recovery and maintaining safety of electric vehicle’, IEEE Trans. Veh. Technol., 2016, 65, (3), pp. 11861198.
    10. 10)
      • 19. Zhang, Q., Li, H.: ‘MOEA/D: a multiobjective evolutionary algorithm based on decomposition’, IEEE Trans. Evol. Comput., 2007, 11, (6), pp. 712731.
    11. 11)
      • 6. Boisvert, M., Mammosser, D., Micheau, P.: ‘Comparison of two strategies for optimal regenerative braking, with their sensitivity to variations in mass, slope and road condition’. IFAC Symp. Advances in Automotive Control, Tokyo, Japan, September 2013, pp. 626630.
    12. 12)
      • 13. Zheng, T., He, Y.C.: ‘Simulation of hydraulic excavators slewing system based on hydraulic accumulator’. Int. Conf. Fluid Power and Mechatronics, Harbin, China, August 2015, pp. 10631066.
    13. 13)
      • 12. Oleksowicz, S.A., Burnham, K.J., Barber, P.: ‘Investigation of regenerative and anti-lock braking interaction’, Int. J. Automot. Technol., 2013, 14, pp. 641650.
    14. 14)
      • 3. Li, L., Li, X., Wang, X., et al: ‘Transient switching control strategy from regenerative braking to anti-lock braking with a semi-brake-by-wire system’, Veh. Syst. Dyn., 2016, 54, (2), pp. 127.
    15. 15)
      • 2. Wang, B., Huang, X., Wang, J., et al: ‘A robust wheel slip ratio control design combining hydraulic and regenerative braking systems for in-wheel-motors-driven electric vehicles’, J. Franklin Inst., 2014, 352, (2), pp. 577602.
    16. 16)
      • 21. Qin, Y., He, C., Shao, X., et al: ‘Vibration mitigation for in-wheel switched reluctance motor driven electric vehicle with dynamic vibration absorbing structures’, J. Sound Vib., 2018, 419, pp. 249267.
    17. 17)
      • 4. Kumar, C.N., Subramanian, S.C.: ‘Cooperative control of regenerative braking and friction braking for a hybrid electric vehicle’, Proc. Inst. Mech. Eng. D, J. Automob. Eng., 2016, 230, (1), pp. 103116.
    18. 18)
      • 11. Oleksowicz, S.A., Burnham, K.J., Southgate, A.: ‘Regenerative braking strategies, vehicle safety and stability control systems: critical use-case proposals’, Veh. Syst. Dyn., 2013, 51, pp. 684699.
    19. 19)
      • 16. Ji, F., Zhou, X., Zhu, W.: ‘Pedal simulator and braking feel evaluation in brake by wire system’, Beijing Hangkong Hangtian Daxue Xuebao/J. Beijing Univ. Aeronaut. Astronaut., 2015, 41, (6), pp. 989994.
    20. 20)
      • 20. Li, H., Zhang, Q.: ‘Multiobjective optimization problems with complicated pareto sets, MOEA/D and NSGA-II’, IEEE Trans. Evol. Comput., 2009, 13, (2), pp. 284302.
    21. 21)
      • 15. Meng, D., Zhang, L., Yu, Z.: ‘A dynamic model for brake pedal feel analysis in passenger cars’, Proc. Proc. Inst. Mech. Eng. D, J. Automob. Eng., 2016, 230, (7), pp. 955968.
    22. 22)
      • 17. Meng, D.J., Zhang, L.J., Fang, M.X., et al: ‘Master cylinder dynamic model for brake pedal feeling and its key factors’, Jilin Daxue Xuebao, 2015, 45, (5), pp. 13881394.
http://iet.metastore.ingenta.com/content/journals/10.1049/iet-its.2018.5090
Loading

Related content

content/journals/10.1049/iet-its.2018.5090
pub_keyword,iet_inspecKeyword,pub_concept
6
6
Loading
Print this page
This is a required field
Please enter a valid email address