氢同位素低温蒸馏基质热交换器原型的设计、制造和测试

IF 0.9 4区 工程技术 Q3 NUCLEAR SCIENCE & TECHNOLOGY Fusion Science and Technology Pub Date : 2023-10-24 DOI:10.1080/15361055.2023.2259238
Claudia Bogdan, Sebastian Brad, Horia Necula, Oleksandr Sirosh, Catalin Brill, Mihai Vijulie, Alin Lazar, Aleksandr Grafov
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引用次数: 0

摘要

摘要要提高制冷、液化和低温分离循环的效率,需要具备以下性能:热交换器必须具有高紧凑性的高效率;必须保证进出气流温差小,以提高效率;必须有一个大的传热面,相对于换热器的体积,以尽量减少热损失;必须有较高的传热速率,以减小传热面积;必须有较小的压降,以降低压缩成本;而且必须以最少的维护实现高可靠性。所设计的矩阵式换热器完全满足上述性能要求。本文介绍了incc - dtci ICSI Ramnicu Valcea低温实验室团队开发的研究项目的结果,其中包括实现的程序阶段和在窄范围内表征mhe型热交换器的初步结果,以获得用于低温目的的热交换器的适当解决方案。例如,在氢同位素精馏塔入口处冷却气体混合物,并在低压(通常为0.5至2.0巴)和流动下运行。在几个实验活动中,采用不同的装配和测试技术对矩阵换热器(MHE)原型进行了测试,以获得换热器沿线温度和压降的数值数据,并验证ANSYS Fluent数值模拟结果。结果表明,对于设计和测试的MHE原型,在确定的参数下,压力损失在几毫巴内(最大记录压降为80毫巴),尺寸小(高64毫米),可达重量(可达2000克),可以获得高达近230 K的温度下降。关键词:低温蒸馏氢同位素热传递矩阵热交换器披露声明作者没有报告潜在的利益冲突。这项工作是通过“核”计划(合同编号9N/2019)进行的,该计划是在研究、创新和数字化部(项目编号PN 19 11 01 04)的支持下制定的——“创新的CECE工艺解决方案,用于促进低浓度氚液体废物的新型去污技术和氘的回收。”
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Design, Fabrication, and Test of a Prototype of Matrix Heat Exchanger for Cryogenic Distillation of Hydrogen Isotopes
AbstractThe following properties are needed to increase the efficiency of refrigeration, liquefaction, and cryogenic separation cycles: Heat exchangers must have high effectiveness doubled by high compactness; small temperature differences between incoming and outgoing flows must be ensured to increase efficiency; there must be a large heat transfer surface, relative to the volume of the heat exchanger, to minimize heat loss; there must be a high heat transfer rate to reduce the transfer area; there must be a small pressure drop to reduce compression costs; and there must be high reliability with minimal maintenance. All these properties are entirely fulfilled by the designed matrix heat exchangers (MHEs). This paper presents the results of the research program developed by the team of the Cryogenic Laboratory from INC-DTCI ICSI Ramnicu Valcea, which included procedural stages of the realization and preliminary results of the characterization of the MHE-type heat exchanger in a narrow range of values to achieve a proper solution for a heat exchanger to be used for cryogenic purposes, such as cooling the gas mixture at the entrance of a distillation column of hydrogen isotopes and running at low pressure (typically regimes of 0.5 to 2.0 bars) and flows. Within several experimental campaigns, different assembly and testing techniques of the matrix heat exchanger (MHE) prototype were performed to achieve numerical data for the temperature and pressure drops along the heat exchanger and to verify ANSYS Fluent numerical simulation results. The results showed that for the designed and tested MHE prototype, a temperature drop of up to almost 230 K can be obtained at the established parameters correlated with pressure losses within a few millibars (the maximum recorded pressure drop is 80 mbars), small dimensions (64 mm high), and accessible weight (up to 2000 g).Keywords: Cryogenic distillationhydrogen isotopesheat transfermatrix heat exchangers Disclosure StatementNo potential conflict of interest was reported by the author(s).Additional informationFundingThis work was carried out through the “Nucleu” Program [contract number 9N/2019], developed with the support of the Ministry of Research, Innovation and Digitalization [project number PN 19 11 01 04]—“Innovative CECE Process Solution for Promoting a New Decontamination Technology of Liquid Waste Poorly Concentrated in Tritium and for Recovery of Deuterium.”
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来源期刊
Fusion Science and Technology
Fusion Science and Technology 工程技术-核科学技术
CiteScore
2.00
自引率
11.10%
发文量
60
审稿时长
3 months
期刊介绍: Fusion Science and Technology, a research journal of the American Nuclear Society, publishes original research and review papers on fusion plasma physics and plasma engineering, fusion nuclear technology and materials science, fusion plasma enabling science technology, fusion applications, and fusion design and systems studies.
期刊最新文献
Precision Polishing of Ablator Capsules via in situ Process Monitoring and Machine Learning–Based Optimization Technique of Reactor Experiments of Tin-Lithium Alloy Interaction with Hydrogen Isotopes Under Neutron Irradiation Conditions Development and Insulation Performance Evaluation of Experimental Sample for a Direct Current High-Voltage Transmission Line Tritium Release During Different Decommissioning Techniques Numerical Calculations of Liquid-Metal Magnetohydrodynamic Flows in Rectangular Ducts with Sudden Contractions
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