基于锥形楔形的电子楔形制动器机理:模型与实验验证

Sharil Izwan Haris, Fauzi Ahmad, Hishamuddin Jamaluddin, Mohd Hanif Che Hassan, Ahmad Kamal Mat Yamin, Amrik Singh Phuman Singh
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引用次数: 0

摘要

本文介绍了一种新型的电子楔形制动系统——基于锥形楔形的电子楔形制动系统。CW-EWB制动器由两个锥形楔组成,一个是母楔,一个是公楔,彼此堆叠在一起。CW-EWB的动力来自滚轮螺杆的直线运动,电机通过滚轮螺杆旋转,导致下楔与盘式制动器切向移动,在车轮旋转时产生制动扭矩。在本研究中,利用物理参数估计方法建立了产生制动扭矩的CW-EWB动态模型。为了保证模型的正常运行,提出了一种基于比例积分导数(PID)控制的转矩跟踪控制器。然后在配备多传感器和输入输出(IO)装置的制动试验台上对所得到的数学模型和控制方法进行了实验测试。从执行器电压、电流、楔形位置、车轮速度和制动力矩等方面分析了制动机构的性能。因此,对实验结果和模拟模型响应进行了比较。在可接受的误差水平上,模拟结果和实验数据之间有可比较的趋势。
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Mechanism of Cone Wedge Shape Based Electronic Wedge Brake: Model and Experimental Validation
This paper describes a new design of an electronic wedge brake (EWB) system called the Cone Wedge Shape Based Electronic Wedge Brake (CW-EWB). The CW-EWB brake is made up of two cone wedges, one female and one male, stacked on top of each other. The CW-EWB is powered by the linear movement of a roller screw caused by the rotation of an electric motor through the roller screw, which causes the lower wedge to move tangentially to the disc brake, creating braking torque as the wheel rotates. A dynamic model of the CW-EWB that creates braking torque was built in this study, utilising a physical parametric estimate method. A torque tracking controller based on the proportional integral derivative (PID) control scheme is presented to ensure the CW-EWB model performs properly. The resulting mathematical model and control method were then experimentally tested using a braking test rig outfitted with multiple sensors and input-output (IO) devices. The performance of the brake mechanism is analysed in terms of actuator voltage, current, wedge position, wheel speed, and brake torque. Consequently, comparisons are made between experimental outcomes and simulated model responses. There are comparable trends between simulation results and experimental data, with an acceptable level of error.
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来源期刊
CiteScore
2.40
自引率
10.00%
发文量
43
审稿时长
20 weeks
期刊介绍: The IJAME provides the forum for high-quality research communications and addresses all aspects of original experimental information based on theory and their applications. This journal welcomes all contributions from those who wish to report on new developments in automotive and mechanical engineering fields within the following scopes. -Engine/Emission Technology Automobile Body and Safety- Vehicle Dynamics- Automotive Electronics- Alternative Energy- Energy Conversion- Fuels and Lubricants - Combustion and Reacting Flows- New and Renewable Energy Technologies- Automotive Electrical Systems- Automotive Materials- Automotive Transmission- Automotive Pollution and Control- Vehicle Maintenance- Intelligent Vehicle/Transportation Systems- Fuel Cell, Hybrid, Electrical Vehicle and Other Fields of Automotive Engineering- Engineering Management /TQM- Heat and Mass Transfer- Fluid and Thermal Engineering- CAE/FEA/CAD/CFD- Engineering Mechanics- Modeling and Simulation- Metallurgy/ Materials Engineering- Applied Mechanics- Thermodynamics- Agricultural Machinery and Equipment- Mechatronics- Automatic Control- Multidisciplinary design and optimization - Fluid Mechanics and Dynamics- Thermal-Fluids Machinery- Experimental and Computational Mechanics - Measurement and Instrumentation- HVAC- Manufacturing Systems- Materials Processing- Noise and Vibration- Composite and Polymer Materials- Biomechanical Engineering- Fatigue and Fracture Mechanics- Machine Components design- Gas Turbine- Power Plant Engineering- Artificial Intelligent/Neural Network- Robotic Systems- Solar Energy- Powder Metallurgy and Metal Ceramics- Discrete Systems- Non-linear Analysis- Structural Analysis- Tribology- Engineering Materials- Mechanical Systems and Technology- Pneumatic and Hydraulic Systems - Failure Analysis- Any other related topics.
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