超临界二氧化碳储能系统印刷线路板式换热器的传热-流阻解耦优化

袁淑霞; 辛蕊; 吴松; 杨坤; 李铮; 朱宗栋

doi:10.19666/j.rlfd.202506103

您当前的位置：

首页 >

文章列表页 >

超临界二氧化碳储能系统印刷线路板式换热器的传热-流阻解耦优化

更新时间：2026-03-24

- 超临界二氧化碳储能系统印刷线路板式换热器的传热-流阻解耦优化
- Thermal Power Generation Vol. 55, Issue 3, Pages: 138-149(2026)
- 作者机构：
  
  西安石油大学机械工程学院
- 作者简介：
- 基金信息：
- DOI：10.19666/j.rlfd.202506103
  CLC： TK172
- Published：2026
- 稿件说明：
移动端阅览
[1]袁淑霞,辛蕊,吴松,等.超临界二氧化碳储能系统印刷线路板式换热器的传热-流阻解耦优化[J].热力发电,2026,55(03):138-149.
[1]袁淑霞,辛蕊,吴松,等.超临界二氧化碳储能系统印刷线路板式换热器的传热-流阻解耦优化[J].热力发电,2026,55(03):138-149. DOI： 10.19666/j.rlfd.202506103.

DOI：10.19666/j.rlfd.202506103.

摘要

【目的】为提升二氧化碳储能系统换热器效率，以太阳盐和超临界二氧化碳(S-CO2)作为冷、热侧流体，研究其在印刷线路板式换热器(printed circuit heat exchanger

PCHE)中的流动传热性能。【方法】选取通道直径、转折角度、转折周期数为自变量，以总换热系数K、换热系数与压降比K/ΔP为响应值，采用数值模拟结合响应曲面法，分析自变量及交互作用的影响并优化参数。【结果】在通道直径1.0～2.0 mm、转折角度5～30°、转折周期数6～10的范围内，减小通道直径、增大转折角度及转折周期数可提升换热效率；通道直径对K和K/ΔP影响极显著，其与转折周期数的交互作用也显著；确定K最优参数(直径1.003 mm、转折角度29.71°、转折周期数9.935时，K高达1 313W/(m2·K))、K/ΔP最优参数(直径2.0 mm、转折角度9.407°、转折周期数6时，K/ΔP达0.453 7W/(m2·K·Pa));PCHE尺寸较传统管壳式换热器缩小约1/10。【结论】该研究证实了在Z型PCHE中，通道直径、转折角度和转折周期数的改变会影响换热性能，而响应曲面法可有效地优化通道结构参数来提升换热性能。并且PCHE在二氧化碳储能系统中紧凑性优势显著。

Abstract

[Objective] To enhance the heat exchanger efficiency in a carbon dioxide energy storage system

a printed circuit heat exchanger(PCHE) was employed as the core heat transfer component

with binary nitrate molten salt(solar salt) serving as the cold-side fluid and supercritical carbon dioxide(S-CO2) as the hot-side fluid. This study aims to investigate the key factors influencing the internal heat transfer process in PCHE and optimize the dominant structural parameters governing its thermal performance

thereby addressing the performance bottlenecks of heat exchangers in such energy storage systems. [Methods] Three key structural parameters of the Zigzag PCHE

such as channel diameter

turning angle

and number of turning cycles

were selected as independent variables. The overall heat transfer coefficient K(a core indicator of heat transfer capacity) and the ratio of the overall heat transfer coefficient to pressure drop K/ΔP(a key metric for evaluating the trade-off between heat transfer and flow resistance) were designated as response variables. A three-factor

three-level response surface methodology(RSM) was established to quantitatively analyze the effects of the three structural parameters and their pairwise interactions on the response variables. Parameter optimization of the heat exchange channels was subsequently performed based on the analytical results. [Results] Within the specified parameter ranges(channel diameter: 1.0～2.0 mm

turning angle: 5°～30°

number of turning cycles: 6～10)

the results indicate that reducing the channel diameter

increasing the turning angle

or increasing the number of turning cycles can effectively improve the heat transfer efficiency of the Zigzag PCHE. Statistical analysis shows that the channel diameter has a highly significant impact on both K and K/ΔP

and the interaction between the channel diameter and the number of turning cycles also significantly influences these two response variables. The optimal parameter set for achieving the maximum K value(1 313 W/(m2·K)) was determined to be a channel diameter of 1.003 mm

a turning angle of 29.71°

and 9.935 turning cycles. Furthermore

the optimal combination for the comprehensive performance factor K/ΔP was found to be a channel diameter of 2.0 mm

a turning angle of 9.407°

and 6 turning cycles

yielding a K/ΔP value of 0.453 7 W/(m2·K·Pa) and a corresponding K value of 801.7 W/(m2·K). A comparative analysis reveals that the optimized PCHE volume is reduced by approximately one-tenth compared to conventional shell-and-tube heat exchangers. [Conclusion] This study confirms that variations in the channel diameter

turning angle

and number of turning cycles significantly affect the thermal performance of zigzag PCHEs. The response surface methodology proves effective in optimizing the channel structural parameters to enhance heat transfer performance. Moreover

PCHEs demonstrate remarkable compactness advantages in CO2 energy storage systems

making them well-suited for space-constrained operational environments. The findings provide reliable theoretical and data-driven support for the rational selection and engineering design of heat exchangers in related fields.

关键词

Keywords

references

程进辉.传蓄热熔盐的热物性研究[D].上海:中国科学院研究生院(上海应用物理研究所), 2014:1.CHENG Jinhui. Research on the thermophysical properties of stored heat molten salt[D]. Shanghai:Shanghai Institute of Applied Physics, Chinese Academy of Sciences, 2014:1.

崔海亭,袁修干,侯欣宾.高温熔盐相变蓄热材料[J].太阳能, 2003(1):27-28.CUI Haiting, YUAN Xiugan, HOU Xinbin. High temperature molten salt phase change heat storage materials[J]. Solar Energy, 2003(1):27-28.

CHU W, LI X, MA T, et al. Experimental investigation on SCO2-water heat transfer characteristics in a printed circuit heat exchanger with straight channels[J].International Journal of Heat and Mass Transfer, 2017,113:184-194.

NGO T L, KATO Y, NIKITIN K, et al. Heat transfer and pressure drop correlations of microchannel heat exchangers with S-shaped and zigzag fins for carbon dioxide cycles[J]. Experimental Thermal and Fluid Science, 2007, 32(2):560-570.

KIM D E, KIM M H, CHA J E, et al. Numerical investigation on thermal-hydraulic performance of new printed circuit heat exchanger model[J]. Nuclear Engineering and Design, 2008, 238:3269-3276.

ISHIZUKA T, KATO Y, MUTO Y, et al. Thermalhydraulic characteristics of a printed circuit heat exchanger in a supercritical CO2 loop[C]. The 11th International Topical Meeting on Nuclear Reactor Thermal-Hydraulics(NURETH-11). Gyeongju, Korea, 2005.

MESHRAM A, JAISWAL A K, KHIVSARA S D, et al.Modeling and analysis of a printed circuit heat exchanger for supercritical CO2 power cycle applications[J]. Applied Thermal Engineering, 2016, 109:861-870.

FU Q, DING J, LAO J, et al. Thermal-hydraulic performance of printed circuit heat exchanger with supercritical carbon dioxide airfoil fin passage and molten salt straight passage[J]. Applied Energy, 2019, 247:594-604.

SHI H Y, LI M J, WANG W Q, et al. Heat transfer and friction of molten salt and supercritical CO2 flowing in an airfoil channel of a printed circuit heat exchanger[J].International Journal of Heat and Mass Transfer, 2020,150:119006.

WANG W Q, QIU Y, HE Y L, et al. Experimental study on the heat transfer performance of a molten-salt printed circuit heat exchanger with airfoil fins for concentrating solar power[J]. International Journal of Heat and Mass Transfer, 2019, 135:837-846.

张虎忠.超临界CO2印刷电路板换热器性能研究[D].北京:中国科学院大学(中国科学院工程热物理研究所), 2020:1.ZHANG Huzhong. Research on the performance of supercritical CO2 printed circuit board heat exchanger[D].Beijing:University of Chinese Academy of Sciences(Institute of Engineering Thermophysics, Chinese Academy of Sciences), 2020:1.

BAIK Y J, JEON S, KIM B, et al. Heat transfer performance of wavy-channeled PCHEs and the effects of waviness factors[J]. International Journal of Heat and Mass Transfer, 2017, 114:809-815.

ZHOU Y, YIN D, GUO X. Flow and heat transfer performance of molten salt and CO2-based mixtures in printed circuit heat exchangers[J]. Applied Thermal Engineering, 2023, 224:120104.

李占英,王江峰,娄聚伟,等.印刷电路板换热器在超临界二氧化碳布雷顿循环系统中的动态特性研究[J].西安交通大学学报, 2024, 58(12):34-44.LI Zhanying, WANG Jiangfeng, LOU Juwei, et al.Research on the dynamic characteristics of printed circuit board heat exchangers in supercritical carbon dioxide Brayton cycle system[J]. Journal of Xi’an Jiaotong University, 2024, 58(12):34-44.

GUO J F, HUAI X L. Performance analysis of printed circuit heat exchanger for supercritical carbon dioxide[J].ASME Journal of Heat and Mass Transfer, 2017, 139(6):061801.

姚业成,张媛媛,纪峰,等. Zigzag PCHE内熔盐/S-CO2流动与换热特性研究[J].工程热物理学报,2024, 45(4):1083-1089.YAO Yecheng, ZHANG Yuanyuan, JI Feng, et al.Research on the flow and heat transfer characteristics of molten salt/S-CO2 in Zigzag PCHE[J]. Chinese Journal of Engineering Thermophysics, 2024, 45(4):1083-1089.

纪宇轩.超临界二氧化碳布雷顿循环印刷电路板式换热器特性的模拟与试验研究[D].杭州:浙江大学,2022:1.JI Yuxuan. Simulation and experimental study on the characteristics of supercritical carbon dioxide Brayton cycle printed circuit board-type heat exchanger[D].Hangzhou:Zhejiang University, 2022:1.

LEE S M, KIM K Y. Comparative study on performance of a zigzag printed circuit heat exchanger with various channel shapes and configurations[J]. Heat and Mass Transfer, 2013, 49(7):1021-1028.

XU X, WANG Q, LI L, et al. Thermal-hydraulic performance of different discontinuous fins used in a printed circuit heat exchanger for supercritical CO2[J].Numerical Heat Transfer, Part A:Applications, 2015, 68:1067-1086.

WANG W, QIU Y, HE Y, et al. Experimental study on the heat transfer performance of a molten-salt printed circuit heat exchanger with airfoil fins for concentrating solar power[J]. International Journal of Heat and Mass Transfer,2019, 135:837-846.

YAO F, BI Q C, DONG X Y. Convective heat transfer of high temperature molten salt flowing across tube bundles of steam generator in a solar thermal plant[J]. Applied Thermal Engineering, 2018, 114:858-865.

丁梦婷,陈玉爽,傅远.高温熔盐印刷电路板式换热器的热工水力特性研究[J].核技术, 2024, 47(4):128-138.DING Mengting, CHEN Yushuang, FU Yuan. Research on the thermal-hydraulic characteristics of hightemperature molten salt printed circuit board-type heat exchangers[J]. Nuclear Technology, 2024, 47(4):128-138.

韩俊杰,李瑶,谭富庭,等. Z字型碳化硅印刷电路板换热器性能优化分析[J].能源化工, 2023, 44(6):73-80.HAN Junjie, LI Yao, TAN Futing, et al. Performance optimization analysis of Z-shaped silicon carbide printed circuit board heat exchanger[J]. Energy Chemistry, 2023,44(6):73-80.

孙金梦,涂宗财,王辉,等.鱼蛋白胶芒果糕的制备工艺优化及品质分析[J].食品工业科技, 2022, 43(20):189-195.SUN Jinmeng, TU Zongcai, WANG Hui, et al.Optimization of preparation process and quality analysis of fish protein gel mango cake[J]. Food Industry Science and Technology, 2022, 43(20):189-195.

中国科学院工程热物理研究所.百千瓦级PCHE缩比样机设计报告[R].北京:中国科学院工程热物理研究所, 2019:1.Institute of Engineering Thermophysics, Chinese Academy of Sciences. Design report for a 100-kilowatt PCHE reduced-scale prototype[R]. Beijing:Institute of Engineering Thermophysics, Chinese Academy of Sciences, 2019:1.

周宇.超临界二氧化碳布雷顿循环印刷电路板式换热器特性的模拟与试验研究[D].杭州:浙江大学,2022:1.ZHOU Yu. Research on characteristics of printed circuit heat exchanger for supercritical carbon dioxide Brayton cycle[D]. Hangzhou:Zhejiang University, 2022:1.

韩俊杰.碳化硅印刷电路板换热器流动换热性能研究[D].青岛:青岛科技大学, 2023:1.HAN Junjie. Research on flow and heat transfer performance of silicon carbide printed circuit heat exchanger[D]. Qingdao:Qingdao University of Science and Technology, 2023:1.

Views

下载量

CSCD

Alert me when the article has been cited

提交

Tools

Publicity Resources

Advances in freeze protection of molten salt piping system in parabolic trough CSP plants

Influence of structural and operating condition parameters on performance of printed circuit heat exchanger

Optimization of electrochemical test conditions for transformer oil T501 based on response surface method

Dynamic modeling and parametric analysis of resistance molten salt heater

Related Author

ZHAO Liang

XIAO Bin

ZHOU Zhi

NIU Dongsheng

LAI Yanhua

HAN Jitian

ZHAO Hongxia

XU Tingting

Related Institution

School of Energy and Power Engineering, Xi'an Jiaotong University

China Power Construction Northwest Survey and Design Institute Co., Ltd

School of Energy and Power Engineering, Shandong University

Inner Mongolia Electric Power Research Institute

Xi'an Xire Energy saving Technology Co., Ltd

AI问答

⁰