Title: Simulation and experimental investigation of hydro-pneumatic energy harvesting suspension system
Authors: Magdy Naeem Awad; M.E. El-Arabi; Saber A. Rabbo; Mohamed I.B. Sokar
Addresses: Department of Mechanical Engineering Mechatronics Engineering, Arab Academy for Science, Technology and Maritime Transport, Smart Village Campus, Giza, Egypt; Mechatronics Engineering Department, Canadian International College, 5th Settlement, Cairo, Egypt ' Department of Design and Production Engineering, Faculty of Engineering, Cairo University, Cairo, Egypt ' Department of Mechanical Engineering, Faculty of Engineering at Shoubra, Benha University, Egypt ' Department of Mechanical Engineering, Mechatronics Engineering, Faculty of Engineering at Shoubra, Benha University, Egypt
Abstract: This article describes a promising hydro-pneumatic regenerative suspension system (HPEHS) that converts the linear oscillation of the suspension system into rotational motion via a hydraulic rectifier to maintain a unidirectional rotational motion of a hydraulic motor connected to an electric generator to generate electricity. The simulation model using the block diagram-oriented environment of MATLAB-Simulink has been created based on the governing equations to investigate the behaviour of the system and validate it. The effect of the sprung mass and the accumulator on the system performance and harvested power of the HPEHS system was investigated. It is found that the motor speed and harvested power increase with increasing sprung mass while the displacement of the sprung mass reduces. The existence of the accumulator in the system minimises the fluctuation in system pressure causing more stability to the suspension system. The average power of the regenerative suspension system is approximately 7.5 W.
Keywords: energy harvesting; hydro-pneumatic regenerative suspension; hydraulic rectifier.
DOI: 10.1504/IJVNV.2023.130244
International Journal of Vehicle Noise and Vibration, 2023 Vol.19 No.1/2, pp.32 - 54
Received: 30 Aug 2022
Accepted: 02 Nov 2022
Published online: 10 Apr 2023 *