电工技术学报  2023, Vol. 38 Issue (13): 3619-3629    DOI: 10.19595/j.cnki.1000-6753.tces.220708
高电压与放电 |
海上风电送出J型管段海底电缆载流量计算模型研究
李根1, 杜志叶1, 肖湃1, 郝兆扬1, 崔戎舰2
1.武汉大学电气与自动化学院 武汉 430072;
2.中国电力工程顾问集团中南电力设计院有限公司 武汉 430071
Study on Calculation Model of Submarine Cable Ampacity in J-Tube Section of Offshore Wind Power Transmission
Li Gen1, Du Zhiye1, Xiao Pai1, Hao Zhaoyang1, Cui Rongjian2
1. School of Electrical Engineering and Automation Wuhan University Wuhan 430072 China;
2. Central Southern China Electric Power Design Institute Co. Ltd of China Power Engineering Consulting Group Wuhan 430071 China
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摘要 海上风电场送出线路从升压站穿出首先需经过散热环境较差的J型管段,目前针对该区段海底电缆载流量的计算主要采用数值模拟法,而三维流体仿真计算非常耗时,因此难以推广使用。该文基于基本热分析方法提出了J型管段海底电缆径向-轴向传热解析模型,考虑温度沿轴向分布的差异,实现J型管段海底电缆载流量的快速计算。在计及导体电阻率随温度变化情况下,利用数值仿真软件建立海底电缆J型管系统三维热-流耦合数值模型,并与径向-轴向传热解析模型进行了对比计算。最后基于两种方法分析了J型管外径、太阳辐射强度和环境温度对J型管段海底电缆缆芯最高温度的影响规律。结果表明,J型管段海底电缆缆芯最高温度与太阳辐射强度和环境温度存在明显的线性关系,而J型管外径与海水温度对J型管段海底电缆缆芯最高温度影响较小,且解析法与数值仿真计算结果误差在5%以内。该文所提出针对J型管段海底电缆载流量计算的解析法高效准确,具有较好的工程应用价值。
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李根
杜志叶
肖湃
郝兆扬
崔戎舰
关键词 海底电缆J型管解析法数值模拟载流量    
Abstract:The transmission line of offshore wind farm generally passes through the J-tube section with poor heat dissipation conditions,which is divided into three sections: platform section, tube air section and tube water section. The tube air section is often the weak point of ampacity of the submarine cable due to the closed air interlayer between the J-tube and the cable. There is no standard formula for calculating the ampacity of submarine cables in this laying section, which mainly depends on the numerical simulation. However, 3-D fluid simulation is time-consuming. This paper proposes an analytical model of radial-axial heat transfer of submarine cables in J-tube section, which takes into account the axial temperature distribution difference of submarine cable conductors and realizes the rapid calculation of ampacity of submarine cables in J-tube section.
Firstly, the radial thermal path model of the submarine cable in J-tube section is built according to the thermoelectric analogy method. The Nusselt number correlation formula is used to calculate the convection heat transfer coefficient between the submarine cable surface and the inner surface of J-tube. And the radiation heat transfer between the submarine cable surface and the inner surface of J-tube is considered. Secondly, the axial heat transfer of submarine cable conductor in J-tube section is approximated by the heat transfer model of medium cross-section straight rib, and the axial heat transfer model is built on the basis of its radial model. Finally, with the radial-axial thermal path model of the J-section submarine cable, the conductor temperature distribution of the J-tube submarine cable under the given current load can be quickly calculated by the dichotomy method.
Taking high voltage DC submarine cable as an example, a comparative calculation is carried out with the analytical model and the 3-D numerical model. The results show that when the length of tube air section is 5 m, the error between the maximum temperature of the conductor calculated by the axial heat transfer model and that calculated by the numerical method is 3.0%; the error is 1.6% when the length of tube air section is 10m; the error is only 1.1% when the length of tube air section is 15 m. The numerical simulation results show that the maximum temperature change is less than 0.4℃ when the outer diameter of J-tube increases by 50 mm, while the analytical model results show that the temperature change is smaller. The maximum temperature of the conductor increases linearly with the increase of solar radiation intensity. And the trend and law of the calculation results of the analytical method and the numerical method are basically consistent. With the increase of the radiation intensity, the error of the calculation results of the analytical method is slightly increased compared with the numerical method, and the maximum error is 2.8%. In addition, the maximum temperature of the conductor increases approximately linearly with the increase of ambient air temperature. The external ambient air temperature increases by 5℃, and the maximum temperature of the conductor also increases by about 5℃. The maximum conductor temperature calculated by the analytical method at different air temperatures is basically consistent with the numerical simulation method, with an error of about 1%.
The following conclusions can be drawn from the comparative calculation and analysis: (1) When the length of tube air section is greater than 10m, the maximum temperature of the axial temperature distribution of the cable conductor has formed an obvious stable section. (2) With the increase of the outer diameter of J-tube, the maximum temperature of the conductor decreases slightly; besides, the reduction of the seawater temperature directly affects the temperature of the conductor in tube water section, but has little effect on the maximum temperature of the conductor in tube air section. (3) The maximum temperature of the conductor in J-tube section increases linearly with the increase of solar radiation intensity and ambient air temperature. However, when the solar radiation intensity increases, the increasing trend of the maximum temperature of the conductor decreases slightly with the increase of air temperature.
Key wordsSubmarine cable    J-tube    analytical method    numerical simulation    ampacity   
收稿日期: 2022-05-04     
PACS: TM247  
基金资助:国家自然科学基金资助项目(51977152)
通讯作者: 杜志叶 男,1974年生,教授,博士生导师,研究方向为智能电气设备、特高压直流输电关键技术、电磁多物理场耦合计算技术。E-mail:Duzhiye@126.com   
作者简介: 李 根 男,1990年生,博士研究生,研究方向为电磁装备多物理场数值计算。E-mail:912lg@163.com
引用本文:   
李根, 杜志叶, 肖湃, 郝兆扬, 崔戎舰. 海上风电送出J型管段海底电缆载流量计算模型研究[J]. 电工技术学报, 2023, 38(13): 3619-3629. Li Gen, Du Zhiye, Xiao Pai, Hao Zhaoyang, Cui Rongjian. Study on Calculation Model of Submarine Cable Ampacity in J-Tube Section of Offshore Wind Power Transmission. Transactions of China Electrotechnical Society, 2023, 38(13): 3619-3629.
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https://dgjsxb.ces-transaction.com/CN/10.19595/j.cnki.1000-6753.tces.220708          https://dgjsxb.ces-transaction.com/CN/Y2023/V38/I13/3619