为提高海上换流平台的设计和建造效率、简化设计界面、提高平台可维护性,以某型正在设计的导管架式海上换流平台为例,从平台功能需求角度出发进行平台的模块划分,以平台工艺流程为导向进行模块分布设计,综合考虑模块功能原理、平台运维需求和平台重量分布的因素,对海上换流平台进行模块化总布置设计。设计结果可以很好地满足预期要求,为相关平台的设计提供参考。
In order to improve design and construction efficiency of offshore converter platforms, simplify design interfaces, and improve platform maintainability, taking a certain type of jacket type offshore converter platform under design as an example, modular division of the platform is carried out from a functional perspective, module distribution design is guided by the technological process, and the influence of multiple factors is comprehensively considered to carry out modular design of the offshore converter platform. The design results can well meet the expected requirements and provide reference for the design of related platforms.
2024,46(24): 129-133 收稿日期:2024-4-26
DOI:10.3404/j.issn.1672-7649.2024.24.022
分类号:TM721
基金项目:国家重点研发计划资助项目(2021YFB2400600)
作者简介:年继业(1988-),男,硕士,高级工程师,研究方向为海工平台总布置设计及外舾装设计
参考文献:
[1] 王诗超, 刘嘉畅, 刘展志, 等. 海上风电产业现状及未来发展分析[J]. 南方能源建设, 2023, 10(4): 103–112.
WANG S C, LIU J C, LIU Z Z, et al. Analysis of the current situation and future development of offshore wind power industry[J]. Southern Energy Construction, 2023, 10(4): 103–112.
[2] 朱孟喆. 海上风电水解制氢经济性分析和展望[J]. 风能, 2024(1): 80-83.
ZHU M Z. Economic analysis and prospects of hydrogen production through offshore wind power hydrolysis[J]. Wind Energy, 2024(1): 80-83.
[3] 孙峰. 我国绿色船舶发展展望[J]. 船海工程, 2019, 48(3): 1-4+9.
SUN F. Outlook on the development of green ships in china[J]. Ship & Ocean Engineering, 2019, 48(3): 1-4+9.
[4] 董飞飞, 陈海焱, 张天龙, 等. 深远海域海上风电发展分析与建议[J]. 中国工程咨询, 2024(2): 63-66.
DONG F F, CHEN H Y, ZHANG T L, et al. Analysis and suggestions on the development of offshore wind power in deep sea areas[J]. China Engineering Consultants, 2024(2): 63-66.
[5] 李俊贤, 吴敏辉, 周于雷. 深远海风电运维技术与模式研究[J]. 水电与新能源, 2023, 37(12): 43-46.
LI J X, WU M H, ZHOU Y L. Research on deep sea wind power operation and maintenance technology and mode[J]. Hydropower and New Energy, 2023, 37(12): 43-46.
[6] 丰力, 张莲梅, 韦家佳, 等. 基于全生命周期经济评估的海上风电发展与思考[J/OL]. 中国电力: 1–14[2024-01-10].
FENG L, ZHANG L M, WEI J J, et al. Development and reflection on offshore wind power based on full life cycle economic assessment[J/OL]. Electric Power: 1–14[2024-01-10].
[7] 常怡然. 海上风电场直流送出关键技术研究[D]. 上海: 上海交通大学, 2021.
[8] 石明, 童帆, 魏务卿, 等. 海上风力发电交直流输电技术发展趋势探讨[J]. 电力勘测设计, 2023(10): 83-88.
SHI M, DONG F, WEI W Q, et al. Discussion on the development trends of offshore wind power generation ac/dc transmission technology[J]. Electric Power Survey & Design, 2023(10): 83-88.
[9] 吴倩, 薄鑫, 吴杨勇, 等. 远海岸海上风电输电方式技术经济分析[J]. 电工电气, 2024(1): 1-9+15.
WU Q, BO X, WU Y Y, et al. Technical and economic analysis of offshore wind power transmission methods on the far coast[J]. Electrotechnics Electric, 2024(1): 1-9+15.
[10] 孔志达, 孙仕达, 卢毓欣. 高压直流换流站电气设计标准化及优化研究[J]. 电网与清洁能源, 2023, 39(11): 20-27.
KONG Z D, SUN S D, LU Y X, et al. Research on standardization and optimization of electrical design for DC converter stations[J]. Power System and Clean Energy, 2023, 39(11): 20-27.
[11] 何俊生, 周伯明, 沙正海. 海上换流站的建造效率分析[J]. 电子技术, 2023, 52(2): 182-183.
HE J S, ZHOU B M, SHA Z H. Analysis of construction efficiency of offshore converter stations[J]. Electronic Technology, 2023, 52(2): 182-183.
[12] 蔡希鹏, 邹常跃, 彭发喜, 等. 超大规模海上风电海陆一体直流输电技术探讨[J/OL]. 电网技术: 1–7[2024-04-15].
CAI Xipeng, ZOU Changyue, PENG Faxi, et al. Exploration of ultra large scale offshore wind power integrated DC transmission technology between land and sea[J/OL]. Power System Technology: 1–7[2024-04-15].
[13] 周敏, 陈志伟, 蔡璐璇, 等. 海上风电柔性直流输电技术研究[J]. 上海电气技术, 2023, 16(4): 21-23.
ZHOU M, CHEN Z W, CAI L X, et al. Research on flexible DC transmission technology for offshore wind power[J]. Journal of Shanghai Electric Technology, 2023, 16(4): 21-23.
[14] 王绍东. 基于柔性直流的海上风电送出系统设计与研究[J]. 微型电脑应用, 2023, 39(9): 229-232.
WANG S D. Design and research of offshore wind power transmission system based on flexible DC[J]. Microcomputer Applications, 2023, 39(9): 229-232.
