Energy harvesting potential assessment and systematic design for energy-regenerative shock absorbers on railway freight wagons

IF 2.4 3区 材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
Liwei Dong, Heli Zhang, Jie Yu, Guobiao Hu
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Abstract

A large amount of vibration energy is dissipated in the secondary suspension systems of railway freight wagons, which can be harvested as renewable power supplies to serve more smart devices for onboard applications. This paper explores the vibration energy harvesting potential of freight wagons and deals with the systematic design issues of energy-regenerative shock absorbers (ERSAs). By considering the ERSA force interaction and realistic track irregularity, a vehicle-track coupled model is established to predict a more accurate vibration response. The parameter sensibility analysis reveals that the operation speed, vehicle load, and track irregularity are the most critical factors that can significantly affect the power generation performance. In addition, vibration energy harvesting potential assessment is conducted on American, German, and Chinese track spectrums and several field-measured freight lines, indicating an average power potential ranging from 33 to 960 W per absorber with a full-loaded freight wagon running at 90 km/h. Finally, a systematic design approach for ERSAs is proposed based on the prior feasibility assessment, a hybrid Grey Wolf Optimization and Particle Swarm Optimization (GWO-PSO) algorithm, and the vehicle-ERSA coupled model. The digital twin of an ERSA has been established and validated by a series of experimental tests. Taking the average power as the objective and setting the suspension vibration velocity, maximum generator rotation velocity, and maximum ERSA force as constraints, the optimized ERSA exhibits an output power of 63 W and 20.22% shock absorption on the secondary suspension. Meanwhile, the GWO-PSO has demonstrated an enhanced exploration ability than the conventional GWO in dealing with the constrained optimization problem of the ERSA design.
铁路货车蓄能式减振器能量收集潜力评价与系统设计
铁路货车的二次悬挂系统耗散了大量的振动能量,这些能量可以作为可再生电源收集,为车载应用的更多智能设备提供服务。探讨了货车的振动能量收集潜力,探讨了蓄能式减振器的系统设计问题。考虑ERSA力相互作用和实际轨道不均匀性,建立了车辆-轨道耦合模型,以更准确地预测车辆的振动响应。参数敏感性分析表明,运行速度、车辆负荷和轨道不平顺度是影响发电性能的最关键因素。此外,对美国、德国和中国的轨道频谱和几条实地测量的货运线路进行了振动能量收集潜力评估,表明在满载货车以90公里/小时运行时,每个吸收器的平均功率潜力在33至960瓦之间。最后,提出了一种基于先验可行性评估、混合灰狼优化和粒子群优化(GWO-PSO)算法以及车辆- ersa耦合模型的ersa系统设计方法。建立了ERSA的数字孪生模型,并进行了一系列实验验证。以平均功率为目标,以悬架振动速度、发电机最大转速和最大ERSA力为约束条件,优化后的ERSA输出功率为63 W,二级悬架减震20.22%。同时,在处理ERSA设计的约束优化问题时,GWO- pso比传统GWO具有更强的探测能力。
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来源期刊
Journal of Intelligent Material Systems and Structures
Journal of Intelligent Material Systems and Structures 工程技术-材料科学:综合
CiteScore
5.40
自引率
11.10%
发文量
126
审稿时长
4.7 months
期刊介绍: The Journal of Intelligent Materials Systems and Structures is an international peer-reviewed journal that publishes the highest quality original research reporting the results of experimental or theoretical work on any aspect of intelligent materials systems and/or structures research also called smart structure, smart materials, active materials, adaptive structures and adaptive materials.
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