Frame Structure Design of 40-Foot High Pressure and Large Capacity Hydrogen Storage Tube Bundle Container for Road Transportation

Mengjie Liu, Zhiping Chen, Zhi Cheng, Haiyang Ou
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Abstract

As a kind of clean energy with good prospect, the demand of trans-regional transportation of hydrogen is increasing rapidly. However, due to the difficulty and high cost of pipeline transportation, tube bundle containers are more used to transport hydrogen. As the fixing device of tube bundle container, the frame structure should not only ensure that the gas cylinder can be fixed, but also meet the requirements of stiffness and strength. In order to improve the efficiency of hydrogen transportation, a new frame structure of 40-foot high pressure and large capacity tube bundle container for road transportation was designed. There are two groups of tube bundles at the front and rear of the tube bundle container, carrying 18 hydrogen storage bottles. The total hydrogen storage capacity is more than 1000kg and the pressure is 52MPa. The design process is as follows: firstly, the stress analysis of the original frame structure under four inertia force conditions was carried out, and it was found that the structure was difficult to meet the strength requirements for road transportation. Then, the beam distribution of tube bundle container frame structure was preliminarily determined by using the method of topology optimization and the geometric model of the optimized frame structure was remodeled according to the topology optimization results. Finally, the static analysis of the frame structure under various driving inertia force loads was carried out by ANSYS Workbench finite element analysis software. The results show that the designed tube bundle container frame structure meets the requirements of strength. This work provides a reference for the design and safety evaluation of similar tube bundle container frame structure products.
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公路运输40英尺高压大容量储氢管束集装箱框架结构设计
氢作为一种极具发展前景的清洁能源,其跨区域运输的需求正在迅速增长。然而,由于管道运输难度大、成本高,更多的是采用管束容器来运输氢气。框架结构作为管束容器的固定装置,既要保证气瓶能够固定,又要满足刚度和强度的要求。为提高氢气运输效率,设计了一种新型公路运输40英尺高压大容量管束集装箱框架结构。管束容器前后有两组管束,分别装载18个储氢瓶。总储氢容量大于1000kg,压力52MPa。设计过程如下:首先对原框架结构进行了四种惯性力条件下的应力分析,发现该结构难以满足道路运输的强度要求。然后,采用拓扑优化方法初步确定管束容器框架结构的梁分布,并根据拓扑优化结果对优化后的框架结构几何模型进行重构。最后,利用ANSYS Workbench有限元分析软件对框架结构在各种驱动惯性力载荷下进行静力分析。结果表明,所设计的管束集装箱框架结构满足强度要求。为类似管束集装箱框架结构产品的设计和安全评价提供参考。
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