Electricity Transmission Strategy Research Based on Wind-Coal-Battery-Hydrogen-CCUS Multi Energy Coupling and Bundling System

ZHONG Yilu; LIU Weixiong; ZHENG Yun; WANG Lu; YIN Jiamin; LI Zhen; ZHENG Kexin; XIAO Kai

doi:10.16516/j.gedi.issn2095-8676.2023.04.012

Volume 10 Issue 4

Jul. 2023

Turn off MathJax

Article Contents

Article Navigation > SOUTHERN ENERGY CONSTRUCTION > 2023 > 10(4): 122-130

ZHONG Yilu, LIU Weixiong, ZHENG Yun, WANG Lu, YIN Jiamin, LI Zhen, ZHENG Kexin, XIAO Kai. Electricity Transmission Strategy Research Based on Wind-Coal-Battery-Hydrogen-CCUS Multi Energy Coupling and Bundling System[J]. SOUTHERN ENERGY CONSTRUCTION, 2023, 10(4): 122-130. doi: 10.16516/j.gedi.issn2095-8676.2023.04.012

Citation:

ZHONG Yilu, LIU Weixiong, ZHENG Yun, WANG Lu, YIN Jiamin, LI Zhen, ZHENG Kexin, XIAO Kai. Electricity Transmission Strategy Research Based on Wind-Coal-Battery-Hydrogen-CCUS Multi Energy Coupling and Bundling System[J]. SOUTHERN ENERGY CONSTRUCTION, 2023, 10(4): 122-130. doi: 10.16516/j.gedi.issn2095-8676.2023.04.012

Electricity Transmission Strategy Research Based on Wind-Coal-Battery-Hydrogen-CCUS Multi Energy Coupling and Bundling System

doi: 10.16516/j.gedi.issn2095-8676.2023.04.012

China Energy Engineering Group Guangdong Electric Power Design Institute Co., Ltd., Guangzhou 510663, Guangdong, China

Received Date: 2023-05-07
Rev Recd Date: 2023-05-31

Available Online: 2023-07-25

Publish Date: 2023-07-10

Abstract

Introduction In order to guarantee urban power supply and offshore wind power utilization without building new power lines, the paper aims to establish a electricity transmission strategy based on wind-coal-battery- hydrogen -CCUS multi energy coupling and bundling system, which is analyzed theoretically and verified by simulation. Method To verify the effectiveness of the strategy, four experimental schemes (separate transmission of wind and coal power, bundled transmission of wind and coal power without operation coupling, bundled transmission of wind and coal power with operation coupling, and wind-coal-battery-hydrogen-CCUS coupled transmission) were set up, and based on the HOMER software environment and particle swarm optimization algorithm, the system operation simulation and index calculation of the test scheme are carried out. Result According to the simulation results, compared with normal separate transmission strategy, power transmission line capacity of system applying wind-coal bundled transmission strategy can be decreased by 2.2 GW, with an average utilization rate of 59%, i.e. 21%~23% higher. In the case that the wind power and coal power share the same transmission line without coordinated operation, the wind power curtailment is 164 GWh in total. System applying wind-coal-battery–hydrogen-CCUS bundled transmission strategy could avoid wind power curtailment and reduce carbon emission from unit power supply by about 30~33g/MWh. Conclusion In conclusion, the electricity transmission strategy established by this paper is supposed to be feasible and effective and contributing to planning and construction of offshore wind power project.
- clean energy,
- green electricity,
- wind power,
- multi-energy-combined,
- hydrogen,
- carbon capture utilization and storage (CCUS)

References

[1]	王枫, 周斌, 张辉. “双碳”背景下源网荷储协调互动助力新型电力系统建设 [J]. 中国资源综合利用, 2022, 40(5): 188-191,201. DOI: 10.3969/j.issn.1008-9500.2022.05.054. WANG F, ZHOU B, ZHANG H. Generation-grid-load-storage coordination and interaction assists construction of new power system under the background of "double carbon" [J]. China resources comprehensive utilization, 2022, 40(5): 188-191,201. DOI: 10.3969/j.issn.1008-9500.2022.05.054.
[2]	毛晓波, 薛溟枫. 基于泛在电力物联网的多能互补综合能源服务平台建设及应用 [J]. 内蒙古电力技术, 2020, 38(1): 31-34. DOI: 10.3969/j.issn.1008-6218.2020.01.013. MAO X B, XUE M F. Construction and application of multi-energy complementary integrated energy service platform based on ubiquitous power internet of things [J]. Inner mongolia electric power, 2020, 38(1): 31-34. DOI: 10.3969/j.issn.1008-6218.2020.01.013.
[3]	张少强, 陈露, 刘子易, 等. 大型燃煤锅炉深度调峰关键问题探讨 [J]. 南方能源建设, 2022, 9(3): 16-28. DOI: 10.16516/j.gedi.issn2095-8676.2022.03.003. ZHANG S Q, CHEN L, LIU Z Y, et al. Discussion on key problems of depth peak adjustment for large coal-fired boilers [J]. Southern energy construction, 2022, 9(3): 16-28. DOI: 10.16516/j.gedi.issn2095-8676.2022.03.003.
[4]	陈璨, 樊小伟, 张文浩, 等. 促进分布式光伏消纳的两阶段源网荷储互动优化运行策略 [J]. 电网技术, 2022, 46(10): 3786-3796. DOI: 10.13335/j.1000-3673.pst.2022.1354. CHEN C, FAN X W, ZHANG W H, et al. Two-staged generation-grid-load-energy storage interactive optimization operation strategy for promotion of distributed photovoltaic consumption [J]. Power system technology, 2022, 46(10): 3786-3796. DOI: 10.13335/j.1000-3673.pst.2022.1354.
[5]	王枫, 周斌, 郑云飞, 等. 基于碳中和的源网荷储协调调度优化模型研究 [J]. 能源与环保, 2022, 44(10): 149-158. DOI: 10.19389/j.cnki.1003-0506.2022.10.024. WANG F, ZHOU B, ZHENG Y F, et al. Research on load storage coordination scheduling optimization model of source network based on carbon neutralization [J]. China energy and environ-mental protection, 2022, 44(10): 149-158. DOI: 10.19389/j.cnki.1003-0506.2022.10.024.
[6]	陈鸿琳, 刘新苗, 余浩, 等. 基于近似动态规划的海上风电制氢微网实时能量管理策略 [J]. 电力建设, 2022, 43(12): 94-102. DOI: 10.12204/j.issn.1000-7229.2022.12.010. CHEN H L, LIU X M, YU H, et al. Real-time energy management strategy based on approximate dynamic programming for offshore wind power-to-hydrogen microgrid [J]. Electric power construction, 2022, 43(12): 94-102. DOI: 10.12204/j.issn.1000-7229.2022.12.010.
[7]	罗金满, 刘丽媛, 刘飘, 等. 考虑源网荷储协调的主动配电网优化调度方法研究 [J]. 电力系统保护与控制, 2022, 50(1): 167-173. DOI: 10.19783/j.cnki.pspc.210348. LUO J M, LIU L Y, LIU P, et al. An optimal scheduling method for active distribution network considering source network load storage coordination [J]. Power system protection and control, 2022, 50(1): 167-173. DOI: 10.19783/j.cnki.pspc.210348.
[8]	罗曦, 黄磊, 金颖, 等. 可再生能源接入下源网荷储策略与模型研究 [J]. 能源与节能, 2022(5): 15-18. DOI: 10.3969/j.issn.2095-0802.2022.05.004. LUO X, HUANG L, JIN Y, et al. Research on strategy and model of source grid load storage under access of renewable energy [J]. Energy and energy conservation, 2022(5): 15-18. DOI: 10.3969/j.issn.2095-0802.2022.05.004.
[9]	周国鹏, 赵春阳, 康俊杰, 等. 面向源网荷储一体化的能源服务典型发展模式 [J]. 广东电力, 2022, 35(7): 23-31. DOI: 10.3969/j.issn.1007-290X.2022.007.003. ZHOU G P, ZHAO C Y, KANG J J, et al. Typical energy service development patterns oriented to source-network-load-storage integration [J]. Guangdong electric power, 2022, 35(7): 23-31. DOI: 10.3969/j.issn.1007-290X.2022.007.003.
[10]	殷仁豪. “双碳”背景下新能源基地规划发展趋势 [J]. 上海节能, 2022(3): 265-271. DOI: 10.13770/j.cnki.issn2095-705x.2022.03.004. YIN R H. Planning development trend of new energy base under "dual carbon" background [J]. Shanghai energy conservation, 2022(3): 265-271. DOI: 10.13770/j.cnki.issn2095-705x.2022.03.004.
[11]	李湃, 王伟胜, 黄越辉, 等. 大规模新能源基地经特高压直流送出系统中长期运行方式优化方法 [J]. 电网技术, 2023, 47(1): 31-40. DOI: 10.13335/j.1000-3673.pst.2022.1335. LI P, WANG W S, HUANG Y H, et al. Method on optimization of medium and long term operation modes of large-scale renewable energy power base through UHVDC system [J]. Power system technology, 2023, 47(1): 31-40. DOI: 10.13335/j.1000-3673.pst.2022.1335.
[12]	杨庆舟, 马平平, 吕素姣. 基于DDF-DEA三阶段模型国家能源开发效率研究−以国家划分的20个大型综合能源基地为例 [J]. 工业技术经济, 2020, 39(3): 143-153. DOI: 10.3969/j.issn.1004-910X.2020.03.017. YANG Q Z, MA P P, LV S J. Research on development efficiency of national energy base based on DDF-DEA three-stage model: take twenty large comprehensive energy bases divided by the state as an example [J]. Journal of industrial technological economics, 2020, 39(3): 143-153. DOI: 10.3969/j.issn.1004-910X.2020.03.017.
[13]	李凯, 康世崴, 闫方, 等. 基于风光火储的多能互补新能源基地规划分析 [J]. 山东电力技术, 2020, 47(10): 17-21,35. DOI: 10.3969/j.issn.1007-9904.2020.10.004. LI K, KANG S W, YAN F, et al. Planning analysis of new energy base based on wind-photovoltaic-thermal-energy storage multi-energy complementary [J]. Shandong electric power, 2020, 47(10): 17-21,35. DOI: 10.3969/j.issn.1007-9904.2020.10.004.
[14]	沈广进, 辛焕海, 刘昕宇, 等. 大型新能源基地中调相机同步失稳机理与影响因素分析 [J]. 电力系统自动化, 2022, 46(20): 100-108. DOI: 10.7500/AEPS20220321004. SHEN G J, XIN H H, LIU X Y, et al. Analysis on synchronization instability mechanism and influence factors for condenser in large-scale renewable energy base [J]. Automation of electric power systems, 2022, 46(20): 100-108. DOI: 10.7500/AEPS20220321004.
[15]	胡贵良. 金沙江上游川藏段可再生能源基地能源利用模式探索 [J]. 华电技术, 2019, 41(11): 62-65,84. DOI: 10.3969/j.issn.1674-1951.2019.11.015. HU G L. Exploration on utilization models for renewable energy of Sichuan-Tibet section in the Jinsha river upper reaches [J]. Integrated intelligent energy, 2019, 41(11): 62-65,84. DOI: 10.3969/j.issn.1674-1951.2019.11.015.
[16]	孟沛彧, 王志冰, 迟永宁, 等. 适应多能源基地远距离输送电能的混合四端直流输电系统控制策略研究 [J]. 电工技术学报, 2020, 35(增刊2): 523-534. DOI: 10.19595/j.cnki.1000-6753.tces.191684. MENG P Y, WANG Z B, CHI Y N, et al. Control strategy of hybrid four-terminal HVDC transmission system dedicated for long-distance power delivery from multiple energy bases [J]. Transactions of China electrotechnical society, 2020, 35(Suppl. 2): 523-534. DOI: 10.19595/j.cnki.1000-6753.tces.191684.
[17]	张适宜, 周明, 黄瀚燕, 等. 新能源基地多端柔性直流汇集系统运行灵活性研究 [J]. 电网技术, 2020, 44(10): 3846-3856. DOI: 10.13335/j.1000-3673.pst.2019.1405. ZHANG S Y, ZHOU M, HUANG H Y, et al. Operational flexibility optimization of renewables generation multi-terminal flexible DC collector system [J]. Power system technology, 2020, 44(10): 3846-3856. DOI: 10.13335/j.1000-3673.pst.2019.1405.
[18]	朱春萍, 王艳, 沙志成. 新能源基地多能互补电力外送和消纳方案的研究 [J]. 电气应用, 2019, 38(10): 60-65. ZHU C P, WANG Y, SHA Z C. Study on the scheme of multi-energy complementary power transmission in new energy base [J]. Electrotechnical application, 2019, 38(10): 60-65.
[19]	习工伟, 赵兵, 郑帅飞, 等. 新能源基地经特高压交流送出系统输电能力与提升措施 [J]. 电力建设, 2022, 43(7): 131-138. DOI: 10.12204/j.issn.1000-7229.2022.07.015. XI G W, ZHAO B, ZHENG S F, et al. Transmission capacity and improvement measures of the UHVAC sending system from new energy base [J]. Electric power construction, 2022, 43(7): 131-138. DOI: 10.12204/j.issn.1000-7229.2022.07.015.
[20]	罗魁, 郭剑波, 马士聪, 等. 海上风电并网可靠性分析及提升关键技术综述 [J]. 电网技术, 2022, 46(10): 3691-3702. DOI: 10.13335/j.1000-3673.pst.2022.1496. LUO K, GUO J B, MA S C, et al. Review of key technologies of reliability analysis and improvement for offshore wind power grid integration [J]. Power system technology, 2022, 46(10): 3691-3702. DOI: 10.13335/j.1000-3673.pst.2022.1496.
[21]	张洒洒, 杨伦庆, 刘强, 等. 广东省海上风电制氢产业发展研究 [J]. 中国资源综合利用, 2022, 40(12): 185-188. DOI: 10.3969/j.issn.1008-9500.2022.12.051. ZHANG S S, YANG L Q, LIU Q, et al. Research on the development of offshore wind power hydrogen production industry in Guangdong province [J]. China resources comprehensive utilization, 2022, 40(12): 185-188. DOI: 10.3969/j.issn.1008-9500.2022.12.051.
[22]	董军, 彭诗程, 包阿茹汗, 等. 新型电力系统火电综合价值分析与评估 [J]. 重庆理工大学学报(自然科学版), 2022, 36(12): 259-268. DOI: 10.3969/j.issn.1674-8425(z).2022.12.033. DONG J, PENG S C, BAO A R H, et al. Analysis and evaluation of comprehensive value of thermal power in the new power system [J]. Journal of Chongqing University of Technology (natural science edition), 2022, 36(12): 259-268. DOI: 10.3969/j.issn.1674-8425(z).2022.12.033.
[23]	祝青, 沈晨姝, 李木子, 等. 大型集中式风电储能系统的配置及收益模式研究 [J]. 电工技术, 2022(17): 4-8. DOI: 10.19768/j.cnki.dgjs.2022.17.002. ZHU Q, SHEN C S, LI M Z, et al. Research on configuration and revenue model of large centralized wind energy storage system [J]. Electric engineering, 2022(17): 4-8. DOI: 10.19768/j.cnki.dgjs.2022.17.002.
[24]	贾子奕, 刘卓, 张力小, 等. 中国碳捕集、利用与封存技术发展与展望 [J]. 中国环境管理, 2022, 14(6): 81-87. DOI: 10.16868/j.cnki.1674-6252.2022.06.081. JIA Z Y, LIU Z, ZHANG L X, et al. Development and prospect of carbon capture, utilization and storage technology in China [J]. Chinese journal of environmental management, 2022, 14(6): 81-87. DOI: 10.16868/j.cnki.1674-6252.2022.06.081.

通讯作者: 陈斌, bchen63@163.com

1.
沈阳化工大学材料科学与工程学院沈阳 110142

Figures(7) / Tables(6)

Get Citation

PDF

XML

Article Metrics

Article views(178) PDF downloads(74) Cited by()

HTML

0. 引言

“2030碳达峰、2060碳中和”目标加速推动国内能源结构优化调整与经济社会系统性变革，打造自主可控、安全可靠、低碳可持续的能源供给体系，是保障产业安全和国家安全的战略选择^[1-3]。在双碳目标的指导下，清洁化、低碳化是新时期能源结构调整的主要方向，未来光伏发电、风力发电等非化石能源发展迅猛，新能源占比逐渐提高，而风、光等新能源出力存在的间歇性、波动性、不可控性等特点给新能源大规模消纳及系统安全稳定运行带来了挑战^[4-6]。源网荷储一体化和多能互补发展是电力行业坚持系统观念的内在要求，是实现电力系统高质量发展的客观需要，是提升可再生能源开发消纳水平、非化石能源消费比重及能源供给保障的必然选择^[7-9]。结合大规模海上风电建设打造多能互补基地，耦合非可控新能源与支撑性电源，协同能源供给设施与可控的能源存储及转化设施，在优化地区电源布局、提高地区电力供应能力、提升电网运行安全性的同时，还能大力促进可再生能源电力的开发和消纳，助力能源转型和绿色发展，推动新能源及相关下游产业集聚发展^[10-12]。

殷仁豪^[10]梳理能源基地相关政策、发展定位及实施路径，总结能源基地发展趋势，并对能源基地相关产业规划提出思考。李湃等^[11]提出了一种基于时序生产模拟的大规模新能源基地经特高压直流送出系统中长期运行优化方法，并以包含风电、光伏、光热、火电、储能的大型能源基地为例对优化方法进行仿真验证。杨庆舟等^[12]运用DDF-DEA三阶段评价模型对多能并存的20个大型能源基地进行经济、环境指标分析，划分出4种能源基地类型并提出开发建议。李凯等^[13]以赤峰大规模新能源外送示范基地为例，综合考虑风电、光伏、存量火电及抽水蓄能电站运行特性，在不增加电网调峰压力的前提下研究风光火储等电源配比方案。沈广进等^[14]分析新能源基地送出系统调相机功角特性、失稳机理与关键影响因素，为提高大型能源基地调相机同步稳定裕度的协调控制策略提供理论基础并以仿真算例加以验证。胡贵良^[15]依托金沙江上游川藏段水电梯级，对可再生能源基地的能源利用模式进行探索，提出水风光互补协同开发思路。孟沛彧等^[16]提出一种适用于多个大规模可再生能源基地远距离输电的混合四端直流输电系统，并在PSCAD/EMTDC中搭建仿真模型验证系统运行特性。张适宜等^[17]以提升新能源基地的消纳水平和并网友好性，构建一种基于模块化多电平换流器的多端柔性直流汇集系统，并提出可同时实现风、光、储等多资源优化调度的协调控制策略。朱春萍等^[18]针对内蒙古大型风光清洁能源基地研究特高压输电通道实现风、光、火打捆外送方案，探索清洁能源集约化、跨区域、大规模输送路径。习工伟等^[19]依托千万级新能源基地，使用PSASP单间机电暂态仿真模型分析基地特高压交流送出特性。综合上述文献研究成果可知，“火电+可再生能源+储能”耦合建设、打捆外送模式从安全稳定运行角度具有一定可行性，且在规模配比适宜时可优化外送电特性、减少弃风弃光现象。但目前存在以下几点尚待研究：（1）现有研究多数聚焦陆上风电与其他设施打捆送出场景，而对于近年规模增长更快、开发潜力更大但波动性更强、调节难度更大的海上风电打捆送出场景研究较少；（2）现有研究多数仅通过储能设施实现电力错峰送出，在季节性调峰需求大的情况下难以进一步提升送出特性优化效果；（3）现有研究未考虑除提升可再生能源消纳水平以外的减碳手段，减碳水平尚有提升空间。

文章以在通道建设空间受限的情况下保障能源供给、大规模送出或本地消纳间歇性绿电并进一步挖掘减碳潜力为目标，研究分析基于海上风电登陆、送出场景的“风火储氢碳”复合型能源基地耦合建设与打捆送出方案，在“风+火+储”耦合建设的基础之上，引入电解水制氢与CCUS（Carbon Capture，Utilization and Storage，碳捕集、封存及再利用）增加余电本地消纳能力、缓解通道压力、减少火电运行碳排放并实现系统与下游产业发展衔接，最终提出1种风火打捆、多元耦合的绿电送出及系统运行模式，并依托HOMER软件环境及粒子群算法对试验方案进行系统仿真与指标测算分析。

1. 系统组成与特点

1.1. 海上风电

海上风电相较于陆上风电，具有风资源密度高、输出相对稳定、单机发电量大等优势，是当前新能源发电领域的研究热点与重要发展方向之一^[20]。我国海上风电资源丰富，在“双碳”背景下海上风电将成为新能源大规模开发的核心模式之一，也是绿电制氢、海洋牧场等产业链的重要组成部分^[20-21]。

1.2. 火电

我国能源资源禀赋具有“多煤”特点，在“双碳”目标的指导下，火电定位开始由高速发展转向高质量发展^[20]。火电技术成熟且经济，在新型电力系统体系中，火电功能逐渐向保障供能、系统灵活性调节和战略性备用等方向偏重，同时，依托火电推动多能融合应用、扩展综合服务业务等也是新型电力系统低碳化转型的重要举措之一^[22]。

1.3. 电储能

电储能是新型电力系统的重要组成部分，能通过充放电改变电源或负荷的变化特性，对新能源出力不可控、不稳定、与负荷不匹配等问题具有一定缓解效果，是大电网调峰的重要手段之一，也是新能源电厂规划建设中的一大关键点^[23]。

1.4. 电制氢

电制氢是电解水制氢的简称，是近年来备受关注的无碳化产氢技术。将电制氢技术与新能源发电系统结合建设，不仅可以平滑新能源的不可控出力、消纳富余绿电，还可生产工业、交通等产业领域所需氢气，带动氢能产业发展^[5]。

1.5. CCUS

CCUS技术被认为是未来减少二氧化碳及其他温室气体排放、解决全球气候变暖等问题的重要手段，包含碳捕集、碳利用、碳封存3大阶段，指将二氧化碳从烟气中分离，经过压缩及运输后转化为产品或输送至指定地点封存的技术流程^[24]。

5. 结论

为在通道建设空间受限的情况下坚实负荷中心城市能源供给保障，并实现海上风电等间歇性绿电大规模送出与消纳，耦合海上风电、火电、电储能、制氢设施及碳捕集设施的建设与运行，通过合理安排火电检修时间、充分发挥火电机组调峰能力，并结合电解水制氢、CCUS等设施对富余电量的消纳作用与利用电化学储能站对可再生能源发电的调节作用，可在避免新建通道的情况下实现登陆海风全额送出，提升现有通道利用率，降低新建通道容量需求，减少系统至社会碳排放，并推动新能源产业集群形成。虽然在目前阶段，单位容量投资额较高且下游市场尚未成熟，电解水制氢及CCUS设施暂不具备经济优势，但对于全社会跨领域降碳以及推动低碳产业链形成闭环具有重要示范意义，随产业规模效应形成，电制氢及CCUS设施相较于火电、海上风电的容量配比提升后可更有效地实现供需平衡灵活调节以及单位供电碳排放削减；同时由于多元系统在调度控制方面的复杂性，基于人工智能、大数据等新一代技术应用的智慧管控平台建设或将成为多能耦合打捆送出模式的重点研究方向之一。

Reference (24)

试验方案编号	送出通道容量/GW
试验方案1	6.708
试验方案2	4.508
试验方案3	4.508
试验方案4	4.508

试验方案编号	通道利用率/%
试验方案1	59
试验方案2	82
试验方案3	82
试验方案4	80

试验方案编号	火电年发电小时数/h
试验方案1	7 302
试验方案2	7 302
试验方案3	7 255
试验方案4	7 256

试验方案编号	年弃风量/GWh
试验方案1	0
试验方案2	163.781
试验方案3	0
试验方案4	0

试验方案编号	单位供电碳排放/[g·(MWh)⁻¹]
试验方案1	457
试验方案2	460
试验方案3	457
试验方案4	427

Electricity Transmission Strategy Research Based on Wind-Coal-Battery-Hydrogen-CCUS Multi Energy Coupling and Bundling System

doi: 10.16516/j.gedi.issn2095-8676.2023.04.012