应用ASME规范和有限元分析技术对典型立式压力容器进行设计与分析

Q2 Engineering Designs Pub Date : 2023-06-16 DOI:10.3390/designs7030078
Kristaq Hazizi, Mohammad Ghaleeh
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引用次数: 0

摘要

本研究旨在解决与储存危险液体的压力容器的设计和制造相关的危险,特别关注全球对液化石油气(LPG)需求的增加。建造更多的液化石油气设施需要安装更安全的压力容器,以减轻爆炸和泄漏等风险。本项目的主要目标是根据美国机械工程师协会(ASME)规范设计一个能够安全储存10 m3加压液化石油气的立式压力容器。为了确保压力容器的安全,研究人员使用Autodesk Inventor Professional 2023进行几何建模,并使用Inventor Nastran进行有限元分析(FEA),以研究位移、挠度和von Mises应力。该容器为圆柱形,具有两个椭圆形封头、两个喷嘴、一个人孔和四个支柱。使用Autodesk Inventor Nastran进行的有限元分析使研究人员能够确定需要进行结构修改以减少血管内应力的区域。结果表明,位移与罐段壳体厚度呈反比关系。此外,随着壳体厚度的增加,安全系数呈线性增加。研究人员仔细考虑了允许的压力,并确定了保持可接受的最大应力所需的壁厚。研究结果表明,压力容器的设计是安全的,不会发生故障。在这些部件中,人孔承受的应力最高,其次是壳体,而封头、喷嘴和支腿承受的应力较低。研究人员还对整个模型进行了理论计算,并确保结果在可接受的范围内,进一步验证了他们的设计方法。该研究强调了按照ASME规范设计压力容器的重要性,以确保安全并防止与不当设计和制造相关的危险。Autodesk Inventor Professional和Inventor Nastran的结合被证明是模拟和评估压力容器性能的有效方法。通过分析,研究人员发现,为了减少应力,有必要改变压力容器的结构。他们观察到位移和储罐截面壳体厚度之间呈反比关系,而安全系数随壳体厚度线性增加。应力分布分析表明,人孔和壳体承受的应力最高,而封头、喷嘴和支腿支撑的应力较低。采用有限元方法,识别了压力容器内的潜在应力点,从而进行了必要的修改,以提高其安全性。
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Design and Analysis of a Typical Vertical Pressure Vessel Using ASME Code and FEA Technique
This study aims to address the hazards associated with the design and manufacture of pressure vessels used for storing dangerous liquids, specifically focusing on the increased demand for liquefied petroleum gas (LPG) worldwide. The construction of more LPG facilities necessitates the implementation of safer pressure vessels to mitigate risks such as explosions and leakage. The primary objective of this project is to design a vertical pressure vessel, in accordance with the American Society of Mechanical Engineers (ASME) code, capable of safely storing 10 m3 of pressurised LPG. To ensure the safety of the pressure vessel, the researchers employed Autodesk Inventor Professional 2023 for geometric modelling and utilised Inventor Nastran for finite element analysis (FEA) to investigate displacements, deflections, and von Mises stresses. The vessel is cylindrical in shape and features two elliptical heads, two nozzles, a manway, and four leg supports. The FEA analysis conducted using Autodesk Inventor Nastran enabled the researchers to identify areas where structural modifications were necessary to reduce stress within the vessel. The results revealed an inverse relationship between the displacement and the tank section shell thickness. Additionally, the factor of safety exhibited a linear increase as the shell thickness increased. The researchers carefully considered permissible pressures and determined the required wall thickness to maintain acceptable maximum stresses. The findings indicate that the design of the pressure vessel is safe from failure. Among the components, the manway experiences the highest stresses, followed by the shell, while the heads, nozzles, and leg supports experience lower stresses. The researchers also conducted theoretical calculations for the entire model and ensured that the results fell within acceptable limits, further validating their design approach. The research emphasised the importance of designing pressure vessels in compliance with ASME codes to ensure safety and prevent hazards associated with improper design and manufacturing. The combination of Autodesk Inventor Professional and Inventor Nastran proved to be an effective approach for simulating and evaluating the performance of the pressure vessel. Through the analysis, the researchers found that changes to the pressure vessel structure were necessary to reduce stress. They observed an inverse relationship between displacement and tank section shell thickness, while the factor of safety increased linearly with shell thickness. Stress distribution analysis revealed that the manway and shell experienced the highest stresses, while the heads, nozzles, and leg support exhibited lower stresses. Employing the finite element method, potential stress points within the pressure vessel were identified, enabling necessary modifications to enhance its safety.
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来源期刊
Designs
Designs Engineering-Engineering (miscellaneous)
CiteScore
3.90
自引率
0.00%
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0
审稿时长
11 weeks
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