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Damping force and energy recovery analysis of regenerative hydraulic electric suspension system under road excitation: modelling and numerical simulation

College of Aerospace Science and Engineering, National University of Defense Technology, Changsha 410072, China

Special Issues: Modelling and control of renewable electrical energy systems

The regenerative hydraulic electric suspension (RHES) is a new type of energy regeneration damper system based on the principle of vibration energy harvesting. This system can recover the vibration energy of suspension dissipated in the form of thermal energy when vehicle travels on the road. In previous studies about RHES system, the vehicle suspension displacement is defined as varieties of periodic waves, such as sinusoidal and so on. The energy harvesting performance of damper system can be explained and evaluated to some extent, but the influence of the actual excitation condition of the road is not fully considered when studying the RHES. This paper builds models of road profiles, quarter car and power regeneration based on the proposed RHES system. Furthermore, the change laws of performance with the varies of road class, motor displacement, accumulator capacity and electrical load are summarized and the corresponding optimization suggestions are proposed, which realize the prediction and evaluation of RHES system performance under the excitation of different road profiles. Simulation suggests that this system can recover 100–400 W of power under road excitation. The findings of system analysis indicate that the component design can satisfy the damping characteristics and power performance required for specific application. The results also show that adjusting the electrical load and accumulator capacity is highly beneficial for controlling suspension behaviours, improving system reliability and increasing power regeneration.
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References

1. R. Wang, Z. Chen, H. Xu, et al., Modelling and validation of a regenerative shock absorber system, 2014 20th International Conference on Automation and Computing, IEEE, (2014), 32–37.

2. A. Browne and J. Hamburg, On road measurement of the energy dissipated in automotive shock absorbers, Symposium on Simulation and Control of Ground Vehicles and Transportation Systems, Anaheim CA, USA, (1986), 167–186.

3. L. Segel and X. Lu, Vehicular resistance to motion as influenced by road roughness and highway alignment, Australian Road Res., 12 (1982), 211–222.

4. P. Hsu, Power recovery property of electrical active suspension systems, Proceedings of the 31st Intersociety Energy Conversion Engineering Conference, IEEE, (1996), 1899–1904.

5. F. Yu and Y. C. Zhang, Technology of regenerative vehicle active suspensions, Trans. Chin. Soc. Agric. Mach., 41 (2010), 1–6.

6. F. Yu, M. Cao and X. Zheng, Research on the feasibility of vehicle active suspension with energy regeneration, J. Vib. Shock, 24 (2005), 27–30.

7. H. Zhang, X. Guo and Z. Fang, Potential energy harvesting analysis and test on energy-regenerative suspension system, J. Vib. Meas. Diagn., 35 (2015), 225–230.

8. F. Khoshnoud, Y. Zhang, R. Shimura, et al., Energy regeneration from suspension dynamic modes and self-powered actuation, IEEE-ASME Trans. Mechatron., 20 (2015), 2513–2524.

9. P. Zhang, Design of electromagnetic shock absorbers for energy harvesting for energy harvesting from vehicle suspensions, Doctoral dissertation, The Graduate School, Stony Brook University: Stony Brook, NY. (2010).

10. S. Zhu, W. Shen and Y. Xu, Linear electromagnetic devices for vibration damping and energy harvesting: Modeling and testing, Eng. Struct., 34 (2012), 198–212.

11. B. Kim, D. Lee and S. Kwon, Vehicle dynamic analysis for the ball-screw type energy harvesting damper system, International Conference on Advanced Engineering Theory and Applications. Springer, Cham, (2016), 853–862.

12. Y. Liu, L. Xu and L. Zuo, Design, modeling, lab, and field tests of a mechanical motion rectifier based energy harvester using a Ball-Screw mechanism, IEEE-ASME Trans. Mechatron., 22 (2017), 1933–1943.

13. C. Chen, Y. Chan, L. Zou, et al., Self-powered magnetorheological dampers for motorcycle suspensions, P. I. Mech. Eng. D-J. Aut., 232 (2018), 921–935.

14. S. Guo, Y. Liu, L. Xu, et al., Performance evaluation and parameter sensitivity of energy-harvesting shock absorbers on different vehicles, Veh. Syst. Dyn., 54 (2016), 918–942.

15. Z. Fang, X. Guo, L. Xu, et al., Experimental study of damping and energy regeneration characteristics of a hydraulic electromagnetic shock absorber, Adv. Mech. Eng., 5 (2013),943528.

16. R. Galluzzi, A. Tonoli, N. Amati, et al., Regenerative shock absorbers and the role of the motion rectifier, SAE Technical Paper, (2016).

17. A. Gupta, J. Jendrzejczyk, T. Mulcahy, et al., Design of electromagnetic shock absorbers, Int. J. Mech. Mater. Des., 3 (2006), 285–291.

18. X. Tang, T. Lin and L. Zuo, Design and optimization of a tubular linear electromagnetic vibration energy harvester, IEEE-ASME Trans. Mechatron., 19 (2014), 615–622.

19. A. Cammarano, A. Gonzalez, S. Neild, et al., Strategies for Coupled Vibration Suppression and Energy Harvesting, Dynamics of Civil Structures, Springer, Cham, 4 (2014), 27–33.

20. Z. Li, L. Zuo, G. Luhrs, et al., Electromagnetic energy-harvesting shock absorbers: design, modeling, and road tests, IEEE Trans. Veh. Technol., 62 (2013), 1065–1074.

21. P. Zheng, R. Wang, J. Gao, A comprehensive review on regenerative shock absorber systems, J. Vib. Eng. Technol., (2019), 1–22.

22. M. A. A. Abdelkareem, L. Xu, M. K. A. Ali, et al., Vibration energy harvesting in automotive suspension system: A detailed review, Appl. Energy, 229 (2018), 672–699.

23. Z. Fang, X. Guo, L. Xu, et al., Researching on valve system of hydraulic electromagnetic energy-regenerative shock absorber, Appl. Mech. Mater., (2012), 911–914.

24. Z. Fang, X. Guo, L. Xu, et al., An optimal algorithm for energy recovery of hydraulic electromagnetic energy-regenerative shock absorber, Appl. Math. Inform. Sci., 7 (2013), 2207.

25. Z. Fang, X. Guo and L. Zuo, Theory and experiment of damping characteristics of hydraulic electromagnetic energy-regenerative shock absorber, J. Jilin University (Engineering and Technology Edition), 44 (2014), 939–945.

26. C. Li, R. Zhu, M. Liang, et al., Integration of shock absorption and energy harvesting using a hydraulic rectifier, J. Sound Vibr., 333 (2014), 3904–3916.

27. R. Wang, F. Gu, R. Cattley, et al., Modelling, testing and analysis of a regenerative hydraulic shock absorber system, Energies, 9 (2016), 386.

28. K. Ahmad and M. Alam, Design and simulated analysis of regenerative suspension system with hydraulic cylinder, motor and dynamo, SAE Technical Paper, (2017).

29. H. Zhang, X. Guo, S. Hu, et al., Simulation analysis on hydraulic-electrical energy regenerative semi-active suspension control characteristic and energy recovery validation test, Trans. Chin. Soc. Agric. Mach., 33 (2017), 64–71.

30. P. Zheng, R. Wang, J. Gao, et al., Parameter optimisation of power regeneration on the hydraulic electric regenerative shock absorber system, Shock Vib., (2019).

31. J. Zou, X. Guo, M. Abdelkareem, et al., Modelling and ride analysis of a hydraulic interconnected suspension based on the hydraulic energy regenerative shock absorbers, Mech. Syst. Signal Proc., 127 (2019), 345–369.

32. M. Abdelkareem, L. Xu, M. Ali, et al., Analysis of the prospective vibrational energy harvesting of heavy-duty truck suspensions: A simulation approach, Energy, 173 (2019), 332–351.

33. C. Boes, Hydraulische Achsantriebe im digitalen Regelkreis, PhD Thesis, Verlag Nicht ermittelbar, (1995).

34. W. Backe and H. Murrenhoff, Fundamentals of hydraulic oil lecture notes: Institute for Fluid Power Drives and Controls. RWTH Aachen University: Aachen, Germany, (1994).

35. B. Armstrong, P. Dupont and C. De, A survey of models, analysis tools and compensation methods for the control of machines with friction, Automatica, 30 (1994), 1083–1138.

36. S. Hamzehlouia, A. Izadian, A. Pusha, et al., Controls of hydraulic wind power transfer. Annual Conference of the IEEE Industrial Electronics Society, IEEE, (2011). 2475–2480.

37. D. Rajabhandharaks, Control of hydrostatic transmission wind turbine, Master of Science, SAN JOSÉ STATE UNIVERSITY, San Jose, California, United States, (2014).

38. M. Eremia and M. Shahidehpour, Handbook of electrical power system dynamics: modeling, stability, and control, John Wiley & Sons, 92 (2013).

© 2019 the Author(s), licensee AIMS Press. This is an open access article distributed under the terms of the Creative Commons Attribution Licese (http://creativecommons.org/licenses/by/4.0)

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