极地研究

极地研究 ›› 2025, Vol. 37 ›› Issue (4): 814-820.DOI: 10.13679/j.jdyj.20240015

• 研究论文 • 上一篇    下一篇

极区船舶电伴热扶手管涂覆层对低温换热性能的影

邓龙祥1,黄嵘2,王东胜3,蒋颖畅3,常雪婷3,张文宜4   

  1. 1上海海事大学物流工程学院, 上海 201306;
    2中国极地研究中心(中国极地研究所), 上海 200136;
    3上海海事大学海洋科学与工程学院, 上海 201306;
    4上海思璞船舶科技有限公司, 上海 201104
  • 收稿日期:2024-01-31 修回日期:2024-11-07 出版日期:2025-12-30 发布日期:2026-01-12
  • 通讯作者: 黄嵘
  • 基金资助:
    国家重点研发计划、船舶结构安全全国重点实验室2025年度开放基金项目和上海深海材料工程技术中心资助项目资助

The influence of coating layer on the heat transfer of electric heat tracing handrail pipes on polar ships at low temperature

DENG Longxiang1, HUANG Rong2, WANG Dongsheng3, JIANG Yingchang3, CHANG Xueting3, ZHANG Wenyi4   

  1. 1School of Logistics Engineering, Shanghai Maritime University, Shanghai 201306, China;
    2Polar Research Institute of China, Shanghai 200136, China;
     3School of Ocean Science and Engineering, Shanghai Maritime University, Shanghai 201306, China;
    4Shanghai Sipu Shipbuilding Technology Company, Shanghai 201104, China
  • Received:2024-01-31 Revised:2024-11-07 Online:2025-12-30 Published:2026-01-12
  • Contact: Huang Rong
  • Supported by:

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摘要:

船舶在极区航行时, 甲板设备和管道的结冰会对船体的结构强度、稳定性和动力系统等造成影响, 而电伴热防冰技术是解决该问题的有效手段之一。本文开展的极区船舶扶手管涂覆层及其对电伴热影响实验结果表明: (1)涂层可提升扶手管表面升温速率, 同时降低扶手管传热系数; (2)40~10 ℃环境范围内, 扶手管表面升温差异不显著, 同一温度, 风速从5 m·s–1上升至7 m·s–1, 其表面升温幅度下降约24%, 此外, 有涂层扶手管的表面升温较无涂层圆管普遍提高30%左右; (3)涂层会改变扶手管表面的对流换热系数, 在相近的环境条件下, 有涂层的扶手管表面温度较无涂层管提升1~2 ℃, 这一升温效应直接增强了其防冰效果。


关键词: 船舶, 扶手管涂覆层, 对流换热性能, 极区

Abstract:

The icing of equipment and pipelines on ships affects the structural strength, stability, and power systems of the vessels when navigating in the polar regions. Anti-icing technology based on electric heating is effective for addressing the icing of equipment and facilities on the upper decks. This study analyzes the relationship between the coating layer and the convective heat transfer coefficient of the round pipe and the thermal balance performance of the electric trace heating handrail pipe. The research findings indicate that: (1) the temperature increase of the surface of a coated pipe is higher than that in an uncoated pipe and heat stored in the wall is also higher. The coating layer can increase the thermal resistance for heat radiation from the pipe and reduce the convective heat transfer coefficient of the round pipe. (2) Within the environmental range of 40 to 10 , the difference in surface temperature rise of handrail pipes is not significant. At the same temperature, when the wind speed increases from 5 m·s1 to 7 m·s1, the magnitude of its surface temperature rise decreases by approximately 24%. Additionally, the surface temperature rise of coated handrail pipes is generally about 30% higher than that of uncoated round pipes. (3) The coating layer has a certain insulation effect; it changes the convective heat transfer coefficient of the pipe surface. Under similar environmental conditions, the surface temperature of the coated handrail is 1~2 ℃ higher than that of the an uncoated, thereby improving the anti-icing effect.


Key words: marine vessels, handrail pipe coating, convective heat transfer performance,  polar regions