Response of an urban bus flywheel battery to a rapid loss-of-vacuum event

R. Thompson, J. M. Kramer, R. Hayes
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引用次数: 7

Abstract

The University of Texas at Austin Center for Electromechanics (UT-CEM) has developed a 2 kW-hr flywheel battery for energy management on a hybrid electric urban bus. The battery recovers braking energy and stores excess energy generated by the prime mover (e.g., internal combustion engine). The flywheel rotor, fabricated from high-strength composites, spins at 40,000 rpm at full charge (∼900 m/s tip speed), and is housed in a vacuum enclosure to minimize windage drag. Also integrated into the enclosure is a composite containment system that has been prooftested to provide additional safety. Ensuring flywheel safety is a major issue that must be addressed in using flywheels for transportation applications. A large leak caused by a service failure of the vacuum system could damage the flywheel before the energy dump system has time to act. A rapid loss-of-vacuum test on a rotor similar to that planned for the urban bus flywheel was conducted. Instrumentation, during the flywheel spin test recorded increasing flywheel surface temperature (>316°C or 600°F) following an intentional and abrupt loss of vacuum. No severe damage was noted on the surface of the flywheel, which was later retested to a higher speed to assess structural integrity. This paper provides an analysis of the data from that test and discusses the experimental results as they pertain to safety of the bus flywheel.
城市客车飞轮电池对快速失真空事件的响应
德克萨斯大学奥斯汀分校机电中心(UT-CEM)开发了一种2千瓦时的飞轮电池,用于混合动力城市公交车的能源管理。电池回收制动能量并存储由原动机(如内燃机)产生的多余能量。飞轮转子由高强度复合材料制成,在充满电的情况下以40000 rpm (~ 900 m/s尖端速度)旋转,并安装在真空外壳中以最小化风阻。还集成到外壳是一个复合密封系统,已经过验证,以提供额外的安全性。确保飞轮的安全是在运输中使用飞轮时必须解决的一个主要问题。由于真空系统的故障引起的大泄漏可能会在能量转储系统有时间行动之前损坏飞轮。在旋翼上进行了与计划用于城市公交车飞轮的旋翼类似的快速失真空试验。在飞轮旋转测试期间,仪器记录了在故意和突然失去真空后飞轮表面温度升高(>316°C或600°F)。飞轮表面未发现严重损坏,随后以更高的速度重新测试以评估结构完整性。本文对试验数据进行了分析,并对试验结果与客车飞轮安全性的关系进行了讨论。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Advanced Materials
Journal of Advanced Materials 工程技术-材料科学:综合
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