航天推进技术研究院主办
[1]徐东君,廉洁,南向谊,等.复合印刷电路板式预冷器的热力设计与优化[J].火箭推进,2022,48(06):59-68.
XU Dongjun,LIAN Jie,NAN Xiangyi,et al.Thermal design and optimization of hybrid printed circuit precooler[J].Journal of Rocket Propulsion,2022,48(06):59-68.
点击复制
XU Dongjun,LIAN Jie,NAN Xiangyi,et al.Thermal design and optimization of hybrid printed circuit precooler[J].Journal of Rocket Propulsion,2022,48(06):59-68.
复合印刷电路板式预冷器的热力设计与优化
《火箭推进》[ISSN:1672-9374/CN:CN 61-1436/V]
卷:
48
期数:
2022年06期
页码:
59-68
栏目:
目次
出版日期:
2022-12-25
- Title:
- Thermal design and optimization of hybrid printed circuit precooler
- 文章编号:
- 1672-9374(2022)06-0059-10
- 分类号:
- V236
- 文献标志码:
- A
- 摘要:
- 空气预冷器作为预冷组合循环发动机的关键部件之一,能够在极短的时间内对来流的高温空气进行冷却,预冷器的性能对预冷组合循环发动机的运行性能具有重要影响。因此,研制耐高温高压、高效紧凑且轻质的预冷器对预冷组合循环发动机的工程应用具有重要意义。针对一种复合印刷电路板预冷器,在5 Ma飞行工况和换热功率为422 MW时对其展开热力设计,并结合遗传算法对复合印刷电路板换热器进行结构优化。计算结果表明,优化后的复合印刷电路板换热器的体积功率比传统印刷电路板换热器的体积功率提高了93,比毛细管预冷器的体积功率提高了243。
- Abstract:
- As one of the key components in the precooling combined engine,the air precooler can cool the incoming high-temperature air at a very short time. The performance of the precooler has significant effect on the operating performance of the precooling engine. Therefore,the development of high temperature and high pressure resistant,efficient,compact and lightweight precooler is of great significance for the engineering application of the precooled engine. In this paper,a hybrid printed circuit heat exchanger is proposed. Under the operating condition at Mach 5 and the heat transfer rate of 422 MW,the thermal design is carried out,and the structure of the hybrid printed circuit heat exchanger is optimized combined with Genetic Algorithm. The calculation results show thatthe volume power of the optimized hybrid printed circuit heat exchanger is increased by 93 compared with that of the conventional printed circuit heat exchanger,and is increased by 243% compared with capillary tube precooler.
参考文献/References:
[1] 朱岩,马元,张蒙正. 预冷空气涡轮火箭发动机氦循环系统的参数特性[J]. 航空动力学报,2018,33(8):2016-2024.
[2] 张蒙正,刘典多,马海波,等. PATR发动机关键技术与性能提升途径初探[J]. 推进技术,2018,39(9):1921-1927.
[3] WEBBER H,BOND A,HEMPSELL M. Sensitivity of pre-cooled air-breathing engine performance to heat exchanger design parameters[C]//57th International Astronautical Congress. Reston,Virigina:AIAA,2006.
[4] 董芃呈,唐海龙,陈敏. 高超声速预冷发动机总体性能研究[J]. 航空动力,2020(3):23-26.
[5] LI X,LE P R,DEWSON S J. Heat exchangers for the next generation of nuclear reactors[C]//Proceedings of ICAPP. Reno,Nevada:[s.n.],2006.
[6] BOWDERY T. LNG applications of diffusion bonded heat exchangers[C]//6th Topical Conference on Natural Gas Utilization.Orlando:[s.n.],2006.
[7] PIDAPARTI S R,ANDERSON M H,RANJAN D. Experimental investigation of thermal-hydraulic performance of discontinuous fin printed circuit heat exchangers for supercritical CO2 power cycles[J]. Experimental Thermal and Fluid Science,2019,106:119-129.
[8] SHIN J H,YOON S H. Thermal and hydraulic performance of a printed circuit heat exchanger using two-phase nitrogen[J]. Applied Thermal Engineering,2020,168:114802.
[9] MARCHIONNI M,CHAI L,BIANCHI G,et al. Numerical modelling and transient analysis of a printed circuit heat exchanger used as recuperator for supercritical CO2 heat to power conversion systems[J]. Applied Thermal Engineering,2019,161:114190.
[10] KIM I H,NO H C,LEE J I,et al. Thermal hydraulic performance analysis of the printed circuit heat exchanger using a helium test facility and CFD simulations[J]. Nuclear Engineering and Design,2009,239(11):2399-2408.
[11] BAEK S,KIM J H,JEONG S,et al. Development of highly effective cryogenic printed circuit heat exchanger(PCHE)with low axial conduction[J]. Cryogenics,2012,52(7/8/9):366-374.
[12] SAEED M,BERROUK A S,SIDDIQUI M S,et al. Numerical investigation of thermal and hydraulic characteristics of sCO2-water printed circuit heat exchangers with zigzag channels[J]. Energy Conversion and Management,2020,224:113375.
[13] ANEESH A M,SHARMA A,SRIVASTAVA A,et al. Effects of wavy channel configurations on thermal-hydraulic characteristics of printed circuit heat exchanger(PCHE)[J]. International Journal of Heat and Mass Transfer,2018,118:304-315.
[14] CUI X Y,GUO J F,HUAI X L,et al. Numerical study on novel airfoil fins for printed circuit heat exchanger using supercritical CO2[J]. International Journal of Heat and Mass Transfer,2018,121:354-366.
[15] 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.
[16] ANEESH A M,SHARMA A,SRIVASTAVA A,et al. Effects of wavy channel configurations on thermal-hydraulic characteristics of printed circuit heat exchanger(PCHE)[J]. International Journal of Heat and Mass Transfer,2018,118:304-315.
[17] SAEED M,KIM M H. Thermal and hydraulic performance of sCO2 PCHE with different fin configurations[J]. Applied Thermal Engineering,2017,127:975-985.
[18] YANG Y,LI H Z,YAO M Y,et al. Investigation on the effects of narrowed channel cross-sections on the heat transfer performance of a wavy-channeled PCHE[J]. International Journal of Heat and Mass Transfer,2019,135:33-43.
[19] BOND A,VARVILL R,SCOTT J,et al. SKYLON:A realistic single stage spaceplane[J]. Space Technology,2003,45:158-161.
[20] HEMPSELL M,BOND A,VARVILLl R,et al. Progress on the SKYLON and SABRE development programme[C]// 62nd International Astronautical Congress. Cape Town,South Africa:[s.n.],2011.
[21] ADAMS T M,ABDEL-KHALIK S I,JETER S M,et al. An experimental investigation of single-phase forced convection in microchannels[J]. International Journal of Heat and Mass Transfer,1998,41(6/7):851-857.
[22] 钱颂文. 换热器设计手册[M]. 北京:化学工业出版社,2002.
备注/Memo
收稿日期:2021- 08-20 修回日期:2021- 09-11
基金项目:国家自然科学基金(52022080)
作者简介:徐东君(1997—),男,博士研究生,研究领域为高温高压传热与强化。
通信作者:马挺(1985—),男,博士,教授,研究领域为高温高压传热与强化。
更新日期/Last Update:
1900-01-01