Thermal characteristics of epoxy as a bonding material in a low temperature vessel

IF 1.1 4区 工程技术 Q4 Engineering
Myung Su Kim, S. Jeong, Gi Seong Lee, Yeon Suk Choi
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Abstract

One of the main sources of heat leakage in a low temperature vessel is the thermal conduction of the vessel wall between room temperature and the low temperature. The material of the vessel is generally stainless-steel, and it is fabricated by welding. To reduce the amount of the thermal conduction, materials having low thermal conductivity are chosen. Glass fiber reinforced plastic (GFRP) is one of the adequate candidate materials because it has low thermal conductivity and high mechanical strength. We use GFRP pipe instead of stainless-steel pipe, as a neck in a liquid nitrogen vessel (or Dewar). Epoxy, as a bonding material, is inserted between the GFRP neck and the main body of the vessel. Therefore, the thermal characteristics, especially the thermal expansion, are very important because the vessel is cooled and warmed periodically. The experimental results of thermal expansion between room temperature and the low temperature are presented in the paper. Leakage in a vacuum environment is incurred because of different linear thermal expansion coefficients of various materials. The leakage is investigated using a vacuum-level checking method during the thermal cycle. In addition, the amount of boil-off in a low temperature vessel is discussed in terms of the thermal characteristics of the neck’s material.
环氧树脂作为粘结材料在低温容器中的热特性
低温容器漏热的主要来源之一是容器壁在室温和低温之间的热传导。容器的材料一般为不锈钢,采用焊接制造。为了减少热传导量,选择导热系数低的材料。玻璃纤维增强塑料(GFRP)具有导热系数低、机械强度高的特点,是较好的候选材料之一。我们使用玻璃钢管代替不锈钢管作为液氮容器(或杜瓦瓶)的颈部。环氧树脂作为粘接材料,插入GFRP颈与容器主体之间。因此,热特性,特别是热膨胀,是非常重要的,因为容器是周期性的冷却和加热。本文给出了室温和低温间热膨胀的实验结果。真空环境下的泄漏是由于各种材料的线性热膨胀系数不同而引起的。在热循环过程中,采用真空水平检查方法对泄漏进行了研究。此外,根据颈部材料的热特性,讨论了低温容器中的沸腾量。
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来源期刊
High Temperatures-high Pressures
High Temperatures-high Pressures THERMODYNAMICS-MECHANICS
CiteScore
1.00
自引率
9.10%
发文量
6
期刊介绍: High Temperatures – High Pressures (HTHP) is an international journal publishing original peer-reviewed papers devoted to experimental and theoretical studies on thermophysical properties of matter, as well as experimental and modelling solutions for applications where control of thermophysical properties is critical, e.g. additive manufacturing. These studies deal with thermodynamic, thermal, and mechanical behaviour of materials, including transport and radiative properties. The journal provides a platform for disseminating knowledge of thermophysical properties, their measurement, their applications, equipment and techniques. HTHP covers the thermophysical properties of gases, liquids, and solids at all temperatures and under all physical conditions, with special emphasis on matter and applications under extreme conditions, e.g. high temperatures and high pressures. Additionally, HTHP publishes authoritative reviews of advances in thermophysics research, critical compilations of existing data, new technology, and industrial applications, plus book reviews.
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