Cryogenics2022,Vol.12415.DOI:10.1016/j.cryogenics.2022.103492

Thermal performance evaluation and analysis of helium heat exchanger for cryogenic propellant launch vehicle

Han, Sangyeop Cho, Kiejoo Oh, Seunghyub Ko, Jeonghwan Baek, Seungwhan Lee, Jisung Kim, Kyung-Seok Shin, Dongsun Lim, Hayoung Kim, Junghan Kim, Jonggyu Kim, Munki Lim, Byoungjik Kim, Chae-hyoung
Cryogenics2022,Vol.12415.DOI:10.1016/j.cryogenics.2022.103492
  • NSTL
  • Elsevier

Thermal performance evaluation and analysis of helium heat exchanger for cryogenic propellant launch vehicle

Han, Sangyeop 1Cho, Kiejoo 1Oh, Seunghyub 1Ko, Jeonghwan 1Baek, Seungwhan 1Lee, Jisung 1Kim, Kyung-Seok 1Shin, Dongsun 1Lim, Hayoung 1Kim, Junghan 1Kim, Jonggyu 1Kim, Munki 1Lim, Byoungjik 1Kim, Chae-hyoung1
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作者信息

  • 1. Korea Aerosp Res Inst
  • 折叠

Abstract

A launch vehicle that operates using cryogenic liquid propellants will require a pressurization process for a propellant tank. Usually, helium stored at cryogenic temperatures passes through the engine, is heated, and pressurizes the tank. Low-temperature helium is heated in a heat exchanger using high-temperature combustion gas from an engine. For the accurate performance prediction and weight optimization of the launch vehicle, the performance of the heat exchanger should be evaluated before launching. This study presents an evaluation method for predicting the performance of a heat exchanger in a launch vehicle. The heat exchanger performance was measured at a constant helium flow rate under actual engine operating conditions. A numerical analysis model for predicting the heat exchanger performance was developed and compared to the test results. The tests were conducted at different inlet temperatures. The test results and analysis confirmed that the effectiveness increased with the inlet temperature. Further analyses revealed that a change in the heat transfer coefficient, as well as the inlet temperature, changed the effectiveness by 6%. To accurately predict the performance of the launch vehicle, it was necessary to accurately predict the change in the heat transfer coefficient with temperature. A design method for the heat exchanger of a launch vehicle was also discussed. The heat-transfer area and weight should be optimized under the required conditions.

Key words

Heat exchanger/Cryogenic/Launch vehicle/Liquid propellant/Effectiveness/MICROCHANNEL/LAMINAR/PIPE

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出版年

2022
Cryogenics

Cryogenics

EISCI
ISSN:0011-2275
被引量2
参考文献量46
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