Automotive Science and Engineering
Iran University of Science & Technology
Thu, Nov 21, 2024
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Volume 14, Issue 2 (6-2024)
ASE 2024, 14(2): 4388-4406 |
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Azarm A, Esfahanian M, Hamidi Rad H. Design of a brake kinetic energy recovery system using flywheel for a passenger car. ASE 2024; 14 (2) :4388-4406
URL: http://www.iust.ac.ir/ijae/article-1-671-en.html
URL: http://www.iust.ac.ir/ijae/article-1-671-en.html
Department of Mechanical Engineering, Isfahan University of Technology, Isfahan, Iran
Abstract: (675 Views)
The objective of developing kinetic energy recovery systems for vehicles is to repurpose energy otherwise dissipated during braking. Brake energy recovery and storage are achieved through two broad methods: electrical and mechanical, contingent on the energy storage type and the traction system's operational approach. Utilizing a rotating flywheel emerges as a practical, cost-effective, safe, and environmentally friendly means of storing energy, offering an extended service life. This study, synthesizing insights from various theories, aims to devise a prototype brake energy recovery system compatible with Samand car, employing the flywheel tank. Additionally, considerations for the power transmission system and clutch involve designing their type and dimensions, taking many factors into account for the selection. The initial design undergoes simulation and evaluation using MATLAB_SIMULINK and the ADVISOR plugin. The investigation delves into the influence of various design parameters on the efficiency of the system. Subsequently, attempts are undertaken to clarify the factors contributing to varied outcomes. The simulation results indicate a notable decrease in fuel consumption and emissions for a Samand car during urban driving cycles characterized by frequent braking. This improvement is realized through the utilization of a steel flywheel with an incomplete cone geometry and a specified radius. Suggestions are put forth for refining the controller to potentially enhance reductions in fuel consumption and pollution.
Keywords: Regenerative braking, Kinetic energy recovering system, Mechanical hybrid, Flywheel Power transmission
Type of Study: Research |
Subject:
Vehicle dynamics, transmission
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