A study on the actual heat leak of a cryogenic vessel during storage

Zhengqing Li, Xiaojun Wang, Sheng-sheng Yang, Xianhu Han, Yuhong Cai
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Abstract

In the traditional method, as the loss product and gas are considered to be saturated, the heat leak of a cryogenic vessel is the latent heat of loss product. However, the temperature of loss product and gas exceeds the saturated temperature as measured in tests. Therefore, a portion of the heat leak is absorbed by the loss product when it diffuses into the gas phase of a cryogenic vessel in the storage process. In this study, the energy equations of the gas and liquid are established in cryogenic vessels during storage to investigate the actual heat leak of a cryogenic vessel in a storage process by considering the temperature distribution of the gas. Then, an experiment was conducted to demonstrate that the actual heat leak of a cryogenic vessel contains not only the latent heat but also the enthalpy change of the loss product, which is produced as it diffused into the gas phase. The results showed that the enthalpy change increased as the liquid level decreased and was critical for determining the actual heat leak in cryogenic vessels in the storage process, with a ratio of approximately 12% to the latent heat when the liquid level ratio is 85%.
关于低温容器在储存过程中实际热量泄漏的研究
在传统方法中,由于损耗品和气体被认为是饱和的,因此低温容器的漏热是损耗品的潜热。然而,根据测试测量,损耗品和气体的温度超过了饱和温度。因此,损耗品在储存过程中扩散到低温容器气相中时,会吸收一部分泄漏热量。本研究建立了低温容器在储存过程中气体和液体的能量方程,通过考虑气体的温度分布来研究低温容器在储存过程中的实际漏热量。然后,通过实验证明,低温容器的实际漏热量不仅包含潜热,还包含损失产物扩散到气相时产生的焓变。结果表明,焓变随着液位的降低而增加,是确定低温容器在储存过程中实际漏热量的关键,当液位比为 85% 时,焓变与潜热的比例约为 12%。
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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