Failure Analysis of a High-Pressure Natural Gas Heat Exchanger and its Modified Design

Numerical Simulations in Engineering and Science Pub Date : 2017-12-20 DOI:10.5772/INTECHOPEN.71202

Leiyong Jiang, Yinghua Han, M. Capurro, M. Benner

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Abstract

The beauty of numerical simulations is its ability to reveal the physics or nature of practi- cal engineering problems in detail, and then, to identify adequate solutions. In this chapter, an excellent example is demonstrated. The rupture of a heavy-duty, high-pressure natural gas heat exchanger is numerically investigated, and the importance of gravity effect is identified, which is often considered as a trivial factor. For the original design, the natural convection in the flow field of the heat exchanger is comparable with the forced convection at the designed operating conditions. These two convections are per - pendicular and compete with each other, the flow field is highly unsteady, and high-temperature natural gas is trapped in the upper portion of the vessel, which causes the damage of the exchanger. By vertically mounting the exchanger assembly and locating the outlet pipe on top of the exchanger, the flow parameters become rather uniform at each vertical cross section and the wall temperature of the heat exchanger remains more or less the same as the heated natural gas. The proposed design has been successfully used up to now.

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高压天然气换热器失效分析及改进设计

数值模拟的美妙之处在于它能够详细地揭示实际工程问题的物理或本质，然后找出适当的解决方案。在本章中，展示了一个很好的例子。对重型高压天然气换热器的破裂进行了数值研究，确定了重力效应的重要性，而重力效应通常被认为是一个微不足道的因素。对于原设计，换热器流场中的自然对流与设计工况下的强制对流相当。这两种对流相互垂直且相互竞争，流场极不稳定，高温天然气被困在容器上部，造成换热器的损坏。通过垂直安装换热器组件并将出水管置于换热器顶部，在每个垂直截面处的流动参数变得相当均匀，换热器的壁温与被加热的天然气大致相同。所提出的设计方案已成功应用至今。

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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Numerical Simulations in Engineering and Science

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