基于储热装置的特种车辆热管理系统
Thermal Management System with Heat Storage Device for Special Vehicles
- 兵工学报 2026年
- 作者机构:
1. 北京理工大学机械与车辆学院,北京,100081
2. 中国北方车辆研究所先进越野系统技术全国重点实验室,北京,100072
- 作者简介:
- 基金信息:
DOI:10.12382/bgxb.2025.1072
中图分类号: TK02收稿:2025-12-05,
网络首发:2026-04-08,
- 稿件说明:
移动端阅览
秦晨予,孙晓霞,沈丽丽,等. 基于储热装置的特种车辆热管理系统[J/OL]. 兵工学报, 2026(2026-04-08). https://doi.org/10.12382/bgxb.2025.1072.
QIN C Y, SUN X X, SHEN L L, et al. Thermal management system with heat storage device for special vehicles[J/OL]. Acta Armamentarii, 2026(2026-04-08). https://doi.org/10.12382/bgxb.2025.1072. (in Chinese)
秦晨予,孙晓霞,沈丽丽,等. 基于储热装置的特种车辆热管理系统[J/OL]. 兵工学报, 2026(2026-04-08). https://doi.org/10.12382/bgxb.2025.1072. DOI:
QIN C Y, SUN X X, SHEN L L, et al. Thermal management system with heat storage device for special vehicles[J/OL]. Acta Armamentarii, 2026(2026-04-08). https://doi.org/10.12382/bgxb.2025.1072. (in Chinese) DOI:
摘要
针对特种车辆在电气化、智能化发展背景下面临的高热流密度、高频动态产热等热管理难题,提出一种基于储热装置的热管理系统。该系统集成相变材料储热模块与基于电磁驱动的液态金属热开关,通过开关控制实现储热模块与冷却循环之间的热交换。研究建立系统一维仿真模型,分析散热与低温冷起动工况下系统的热响应特性。研究结果表明:启用储热装置可以有效降低散热工况下的低温循环出口水温与风扇能耗,并在冷起动工况下为电力机械循环提供超过30℃的温升,显著提升车辆冷起动性能;通过优化储热模块结构与热开关厚度,可以进一步提升储释热速率与装置保温性能。所得成果对提升特种车辆机动性能及储热装置结构设计具有指导意义。
Abstract
Thedevelopmentofelectrification and intelligentizationofspecial vehicles presentsthesignificant thermal management challenges
including high heat flux density and high-frequency dynamic thermal loads. To address these issues
thispaperproposes a novel thermal management systemwitha phase change material (PCM)-based heat storage device. This systemisequipped witha PCM storage moduleandan electromagnetically actuated liquid metal-based thermal switch
which enablestheprecise on/off control of the heat exchange between the module and the vehicle’s cooling circuit. A 1D simulation modelis established to investigate thethermal responseof the systemundertheconditions ofhigh-load heat dissipation and low-temperature coldstartup. Simulatedresults demonstrate that theheat storage device notably lowers the coolant outlet temperature of low-temperature loop and reducesthepower consumptionoffanduring cooling. In cold-start conditions
the device rapidly elevates the temperature of the electric-mechanical circuit by more than 30 ℃
markedly enhancingthe coolstartup performanceof vehicle. Additionally
The heat transfer rates during charging/discharging and the device's thermal insulation capabilitycanbefurther improvedbyoptimizing the geometry ofheatstorage module and thethicknessofthermal switch. The findingsoffer critical guidance for optimizing the design of heat storage devices and improving the overall mobility and operational readiness of special vehicles.
关键词
Keywords
references
DAN D, ZHAO Y H, WEI M S, et al. Review of thermal management technology for electric vehicles[J]. Energies, 2023, 16(12): 4693.
孙晓霞, 牛丹华, 杨立宁, 等. 混合动力装甲车辆热管理技术综述[J]. 电子技术, 2021, 50(1): 62-67.
SUN X X, NIU D H, YANG L N, et al. Review of thermal management technology of hybrid electric armored vehicle[J]. Electronic Technology, 2021, 50(1): 62-67. (in Chinese)
董庆丽, 何军. 混合动力装甲车辆的热管理技术初探[J]. 机械工程与自动化, 2008(1): 199-200.
DONG Q L, HE J. Research of thermal management technology on hybrid power armored vehicles[J]. Mechanical Engineering & Automation, 2008(1): 199-200. (in Chinese)
王发成, 王义春, 张承宁, 等. 电传动履带车冷却系统动态传热状态空间模型[J]. 兵工学报, 2012, 33(7): 769-775.
WANG F C, WANG Y C, ZHANG C N, et al. State-space model for dynamic heat transfer in the cooling system of an electric-drive tracked vehicle[J]. Acta Armamentarii, 2012, 33(7): 769-775. (in Chinese)
王义春,杨英俊,谷中丽. 混合动力车辆冷却系统优化设计[J]. 北京理工大学学报, 2004, 24(1): 44-47, 60.
WANG Y C , YANG Y J, GU Z L. Optimized design of the cooling system for a hybrid electric vehicle[J]. Transactions of Beijing Institute of Technology, 2004, 24(1): 44-47, 60. (in Chinese)
岳玉嵩, 吴玉峰, 杨乃锋, 等. 某装甲车辆加温系统热量匹配分析[J]. 机械工程师, 2019(11): 134-136.
YUE Y S, WU Y F, YANG N F, et al. Thermal matching analysis of an armored vehicle heating system[J]. Mechanical Engineer, 2019(11): 134-136. (in Chinese)
SHARMA A, TYAGI V V, CHEN C R, et al. Review on thermal energy storage with phase change materials and applications[J]. Renewable and Sustainable Energy Reviews, 2009, 13(2): 318-345.
REVELLO E, DIXIT P, TURUNEN K, et al. Assessment of phase change materials for thermal energy storage in battery systems for heavy-duty vehicle applications[J]. Energy Conversion and Management, 2026, 349: 120816.
杨启容, 杨娟, 刘大维. 回收发动机余热的球内对称凝固过程参数分析[J]. 农业机械学报, 2006, 37(3): 27-30.
YANG Q R, YANG J, LIU D W. Parameter analysis of freezing in spheres for the recovering of waste heat of engine[J]. Transaction of the Chinese Society for Agricultural Machinery, 2006, 37(3): 27-30. (in Chinese)
高青, 王永珍, 王国华, 等. 基于车辆余热蓄能利用的作用特性分析[J]. 热科学与技术, 2008, 7(4): 314-319.
GAO Q, WANG Y Z, WANG G H, et al. Characteristics of thermal energy storage on automobile waste heat for vehicle heating[J]. Journal of Thermal Science and Technology, 2008, 7(4): 314-319. (in Chinese)
XIE P, JIN L, QIAO G, et al. Thermal energy storage for electric vehicles at low temperatures: concepts, systems, devices and materials[J]. Renewable and Sustainable Energy Reviews, 2022, 160: 112263.
杨玖林, 杨春光. 相变储能技术在冷藏车中的应用[J]. 交通节能与环保, 2018, 14(3): 8-10.
YANG J L, YANG C G. Application of phase change energy storage in refrigerated trucks[J]. Transport Energy Conservation & Environmental Protection, 2018, 14(3): 8-10. (in Chinese)
FANG Y, SHI Q, HUANG X R, et al. Erythritol-based phase change materials: supercooling enhancement and adaptive heat-triggered release for extreme environmental thermal applications[J]. Journal of Energy Storage, 2025, 140: 118982.
SONG K L, LIU Z P, YANG A S, et al. Shape-stabilized phase change materials of barium hydroxide octahydrate based on cu‐coated melamine foam[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2023, 678: 132465.
甘玉凤, 陈静然, 周志华, 等. 石蜡基复合相变材料及其在储能系统中的应用[J]. 化工进展, 2025, 44(增刊1): 277-287.
GAN Y F, CHEN J R, ZHOU Z H, et al. Research on paraffin-based composite phase change materials and applications in energy storage systems[J]. Chemical Industry and Engineering Progress, 2025, 44(S1): 277-287. (in Chinese)
BHARATHIRAJA R, RAMKUMAR T, SELVAKUMAR M, et al. Advancements in paraffin wax phase change materials: a comprehensive review of enhancement techniques and thermal storage applications[J]. Thermochimica Acta, 2025, 753: 180129.
CHOURE B K, ALAM T, KUMAR R. A review on heat transfer enhancement techniques for PCM based thermal energy storage system[J]. Journal of Energy Storage, 2023, 72: 108161.
AL-SALAMI H A, DHAIDAN N S, ABBAS H H, et al. Review of PCM charging in latent heat thermal energy storage systems with fins[J]. Thermal Science and Engineering Progress, 2024, 51: 102640.
XIE Y Y, LIU J J, MA W, et al. Review of the heat transfer enhancement for phase change heat storage devices[J]. Journal of Energy Storage, 2024, 86: 111336.
WANG X H, LU C N, RAO W. Liquid metal-based thermal interface materials with a high thermal conductivity for electronic cooling and bioheat-transfer applications[J]. Applied Thermal Engineering, 2021, 192: 116937.
SONG S H, SHEN W D, WANG J L, et al. Experimental study on laminar convective heat transfer of microencapsulated phase change material slurry using liquid metal with low melting point as carrying fluid[J]. International Journal of Heat and Mass Transfer, 2014, 73: 21-28.
GAO J Y, CHEN S, LIU T Y, et al. Additive manufacture of low melting point metal porous materials: capabilities, potential applications and challenges[J]. Materials Today, 2021, 49: 201-230.
SHEN Y O, PENG S N, YAN M Y, et al. Analytical study of heat transfer for liquid metals in a turbulent tube flow[J]. Nuclear Engineering and Design, 2021, 373: 111030.
YANG T Y, KWON B, WEISENSEE P B, et al. Millimeter-scale liquid metal droplet thermal switch[J]. Applied Physics Letters, 2018, 112(6): 063505.
CHEN H D, XIE Y Y, QIAO K M, et al. Thermomagnetic liquid metal switches with fast bidirectional response[J]. Nature Communications, 2025, 16(1): 2634.
ZHU P L, ZHANG J J, WEI B J, et al. Liquid metal enabled thermal switch for active thermal management[J]. International Journal of Heat and Mass Transfer, 2026, 254: 127654.
0
浏览量
0
下载量
0
CNKI被引量
- 网络PDF下载
- Meta-XML下载
- BibTeX下载
- Endnote下载
- RefMan 下载
- NoteExpress下载
- NoteFirst下载
关联资源
相关文章
相关作者
相关机构
- 地址:北京市海淀区车道沟10号中国兵工学会 邮编:100089
- 联系电话:010-68963060/68962718 传真:010-68963025 Email:bgxb@cos.org.cn
- 技术支持由北京北大方正电子有限公司提供 京ICP备05059581号-4
京公网安备11010802024360号 - 本系统建议在Chrome、 IE9+ 以上版本浏览器阅读本站内容,360浏览器请切换至极速模式
- Cookies帮助我们提供服务并提供个性化体验。使用本网站,即表示您同意我们使用Cookies
- 总访问量:100063 今日访问量:537