Numerical Simulation and Experiment Research on Radioisotope Thermoelectric Generator
-
摘要: 温差同位素电源是一种将放射性同位素衰变产生的热能转换为电能的装置,涉及热-电物理场强耦合,如何准确仿真分析是一大难点。本文基于一款90Sr温差同位素电源样机,首先建立了样机整机热-电物理场直接耦合的数字仿真模型,结合试验数据对模型参数进行优化,然后通过模拟试验验证了电源样机稳态和动态运行下模型仿真的准确性。最后利用模型开展了电源样机整机热-电物理场分析,以及外接不同负载时的输出功率研究。结果表明,在给定工况下,样机系统漏热占比26%,电路电能损耗占比10%;在最佳匹配负载下,整机最大输出功率可达96 mW,热电转换效率2%。Abstract: Radioisotope thermoelectric generator is a device that converts the thermal energy produced by the decay of radioactive isotopes into electric energy. It involves the strong coupling of thermal-electric physical fields and is difficult to simulate accurately. In this paper, based on a 90Sr Radioisotope thermoelectric generator prototype, firstly, the digital simulation model of the direct coupling of thermal-electric physical fields of the prototype is established, and the model parameters are optimized by combining the experimental data. Then, the accuracy of the model simulation under the steady and dynamic operation of the prototype is verified by simulation tests. Finally, the thermal-electric field analysis of the whole prototype and the output power research with different load resistance are carried out by using the model. The results show that the heat leakage of the prototype system accounts for 26% and the electric energy loss of the circuit is 10% under given operating conditions. Under the best matching load resistance, the maximum output power of the whole prototype can reach 96 mW, and the thermoelectric conversion efficiency is 2%.
-
图 2 热电器件、热源和样机外壳温度仿真与实测对比
Figure 2. Temperature Comparison Between Simulation and Measurement of Thermoelectric Device, Heat Source and Prototype Shell
图 3 整机输出功率与电压仿真与实测对比
Figure 3. Output Power and Voltage Comparison between Simulation and Measurement
图 4 热电器件冷、热端温度随时间变化
Figure 4. Variation of Temperature at the Cold and Hot End of Thermoelectric Device with Time
图 6 整机及热电器件温度分布
Figure 6. Temperature Distribution of Prototype and Thermoelectric Device
表 1 电源样机典型运行工况
Table 1. Typical Operating Conditions of RTG Prototype
工况 热源功率/W 外部环境 外部环境温度/℃ 1 3.3 空气 18.0 2 3.3 水 4.0 3 4.9 水 4.0 4 4.9 水 10.0 5 4.9 水 18.0 
下载: 导出CSV
-
[1] LANGE R G, CARROLL W P. Review of recent advances of radioisotope power systems[J]. Energy Conversion and Management, 2008, 49(3): 393-401. doi: 10.1016/j.enconman.2007.10.028 [2] ZHOU Y, ZHANG S X, LI G P. A review of radioisotope batteries[J]. Chinese Science Bulletin, 2017, 62(17): 1831-1845. doi: 10.1360/N972016-00793 [3] 王廷兰. 深空探测用同位素电源的研究进展[J]. 电源技术,2015, 39(7): 1576-1579. doi: 10.3969/j.issn.1002-087X.2015.07.073 [4] 侯旭峰. 百毫瓦同位素温差电池技术研究[D]. 天津: 天津大学,2014. [5] 彭磊,侯旭峰,阎勇,等. 嫦娥四号着陆器同位素温差电池设计与验证[J]. 电源技术,2020, 44(4): 607-612. doi: 10.3969/j.issn.1002-087X.2020.04.033 [6] 王雪健. 同位素温差电池的系统设计与结构优化[D]. 兰州: 兰州大学,2021. [7] 张原熙. Sr-90同位素电池系统相关研究[D]. 兰州: 兰州大学,2012. [8] 杜广瀚,李玉鹏,李根,等. 90Sr同位素温差电源结构设计与性能分析[J]. 核动力工程,2023, 44(3): 104-111. [9] 杨立群,贾楠楠,周剑,等. 90Sr同位素电池放射源的设计模拟与辐射优化[J]. 同位素,2024, 37(1): 49-54. doi: 10.7538/tws.2023.youxian.027 -
计量
- 文章访问数: 42
- HTML全文浏览量: 9
- PDF下载量: 14
- 被引次数: 0
