零碳视角下电气化码头源网荷储协同优化研究

doi:10.3969/j.issn.2097-0706.2022.12.010

综合智慧能源 ›› 2022, Vol. 44 ›› Issue (12): 68-74.doi: 10.3969/j.issn.2097-0706.2022.12.010

零碳视角下电气化码头源网荷储协同优化研究

敦文斌¹(), 陈业²(), 王大伟¹(), 马晓慧³^,^*()

1.天津港电力有限公司，天津 300450
2.天津港（集团）有限公司，天津 300450
3.天津大学电气自动化与信息工程学院，天津 300110

收稿日期:2022-09-26 修回日期:2022-11-20 出版日期:2022-12-25 发布日期:2023-02-01
通讯作者: *马晓慧（1989），女，讲师，工程师，硕士，从事新能源与智能微电网方面的研究，mxh0927@126.com。
作者简介:敦文斌（1970），男，高级工程师，硕士，从事港口电力市场开发、电力工程建设、电力试验管理等工作，d13702196826@163.com；
陈业（1983）男，高级工程师，硕士，从事电力建设、运行管理、设备管理等工作，13821606803@163.com；
王大伟（1982），男，高级工程师，硕士，从事能电力建设、新能源管理等工作，120590985@qq.com；
基金资助:
天津港科技项目(2022C1154)

Study on source-grid-load-storage cooperative optimization of an electrified quay from the perspective of zero carbon

DUN Wenbin¹(), CHEN Ye²(), WANG Dawei¹(), MA Xiaohui³^,^*()

1. Tianjin Port Power Company Limited， Tianjin 300450，China
2. Tianjin Port （Group） Company Limited， Tianjin 300450， China
3. School of Electrical and Information Engineering，Tianjin University ，Tianjin 300110， China

Received:2022-09-26 Revised:2022-11-20 Online:2022-12-25 Published:2023-02-01
Contact: MA Xiaohui

摘要/Abstract

摘要：

港口运输系统的深度电气化与智能微电网的多元融合，是当前“双碳”背景下交通能源互联互通的趋势。以电气化码头为背景，建立以购电费用最小为目标，考虑功率平衡约束、购售电约束、风光出力约束、储能出力约束、可转移负荷约束等条件的源网荷储协同优化调度模型；以天津港C段码头为例，通过选取源荷近似、源远大于荷、源远小于荷的3类典型日，设置仅调控储能、仅调控负荷和储荷协同调控方案验证运行效果。仿真结果表明：3种方案均能实现码头源网荷储的时序调控并起到降费增收的目标，其中储能占主导，在源荷近似场景下协同调控方案较原始费用下降了15.34%，效果最佳。最后对降碳减排结果进行讨论，并提出码头“零碳排放”，受源荷时序特性、分时电价、购售电量、核算边界等多因素影响，不与购电费用最小化呈严格的正相关性。

关键词: 电气化码头, 零碳, 源网荷储协同, 碳排放, 时序仿真, 智能微电网, “双碳”目标

Abstract:

On the way to achieve "dual carbon" target，deep electrification of port transportation systems and multi-element integration of smart microgrids are the results of transportation and energy interconnection. A source-grid-load-storage cooperative optimization model of an electrified quay aiming at minimizing the purchase cost of electricity is constructed. The model takes power balance constraint， power purchase-sale constraint， wind-PV power output constraint， energy storage output constraint and transferable load constraint into consideration. Taking the Section C quay of Tianjin Port as the example， three typical days with the source approximately equals to load， larger than load and smaller than load are selected for the case study. And the operation performances under three regulation schemes， regulating energy storage only， regulating transferable load only and cooperatively regulating storage and load， are verified. The simulation results show that the three schemes can realize the source-grid-load-storage timing regulation， reduce the cost and increase the revenue of the quay. Energy storage plays the dominant role in operation regulation. In the scenario that the source approximately equals to load， the cooperative regulating scheme can cut the original cost by 15.34%，showing the best performance. Finally， the results of carbon emission reduction are discussed. It is concluded that "zero carbon emissions" of a quay is affected by multiple factors， such as time-series characteristics of source and load， time-of-use price， quantity of purchased and sold and accounting boundary， but it is not strictly positively correlated with the minimization of power purchase cost.

Key words: electrified quay, zero carbon emissions, source-grid-load-storage collaboration, carbon emissions, timing simulation, smart micro-gird, "dual carbon" target

中图分类号:

TM74：TK89：U65

敦文斌, 陈业, 王大伟, 马晓慧. 零碳视角下电气化码头源网荷储协同优化研究[J]. 综合智慧能源, 2022, 44(12): 68-74.

DUN Wenbin, CHEN Ye, WANG Dawei, MA Xiaohui. Study on source-grid-load-storage cooperative optimization of an electrified quay from the perspective of zero carbon[J]. Integrated Intelligent Energy, 2022, 44(12): 68-74.

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参考文献 21

[1]	国家发展改革委,国家能源局,财政部,等. 关于印发“十四五”可再生能源发展规划的通知[EB/OL].(2021-10-21)[2022-11-09]. https://www.ndrc.gov.cn/xxgk/zcfb/ghwb/202206/t20220601_1326719.html?code=&state=123.
[2]	交通运输部,发展改革委,财政部,等. 关于建设世界一流港口的指导意见[EB/OL].(2019-11-13)[2022-11-09]. http://www.gov.cn/xinwen/2019-11/13/content_5451577.htm.
[3]	廖凯, 张润涛, 杨子安, 等. 交通能源融合大数据平台架构与应用[J]. 电力系统自动化, 2022, 46(12):20-35.
	LIAO Kai, ZHANG Runtao, YANG Zi'an, et al. Architecture and application of traffic-energy integrated big data platform[J]. Automation of Electric Power Systems, 2022, 46(12):20-35.
[4]	江里舟, 别朝红, 龙涛, 等. 能源交通一体化系统发展模式与运行关键技术[J]. 中国电机工程学报, 2022, 42(4):1285-1301.
	JIANG Lizhou, BIE Zhaohong, LONG Tao, et al. Development model and key technology of integrated energy and transportation system[J]. Proceedings of the CSEE, 2022, 42(4):1285-1301.
[5]	袁裕鹏, 袁成清, 徐洪磊, 等. 我国水路交通与能源融合发展路径探析[J]. 中国工程科学, 2022, 24(3):184-194.
	YUAN Yupeng, YUAN Chengqing, XU Honglei, et al. Pathway for integrated development of waterway transportation and energy in China[J]. Strategic Study of CAE, 2022, 24(3):184-194.
[6]	ALZAHRANI A, PETRI I, REZGUI Y, et al. Developing smart energy communities around fishery ports:Toward zero-carbon fishery ports[J]. Energies, 2020, 13(11): 2779. doi: 10.3390/en13112779
[7]	VICHOS E, SIFAKIS N, TSOUTSOS T. Challenges of integrating hydrogen energy storage systems into nearly zero-energy ports[J]. Energy, 2022, 241: 122878. doi: 10.1016/j.energy.2021.122878
[8]	张驰, 周骏, 赵镔, 等. 零碳园区电-氢混合储能系统多目标优化配置[J]. 电力建设, 2022, 43(8):1-12. doi: 10.12204/j.issn.1000-7229.2022.08.001
	ZHANG Chi, ZHOU Jun, ZHAO Bin, et al. Multi-objective optimal configuration of electricity-hydrogen hybrid energy storage system in zero-carbon park[J]. Electric Power Construction, 2022, 43(8):1-12. doi: 10.12204/j.issn.1000-7229.2022.08.001
[9]	李梓丘, 乔颖, 鲁宗相. 计及效率与寿命的海上风电-多堆氢能系统运行优化[J]. 综合智慧能源, 2022, 44(5):69-77. doi: 10.3969/j.issn.2097-0706.2022.05.008
	LI Ziqiu, QIAO Ying, LU Zongxiang. Operation optimization of offshore wind-multi-stack hydrogen system considering efficiency and lifetime[J]. Integrated Intelligent Energy, 2022, 44(5):69-77. doi: 10.3969/j.issn.2097-0706.2022.05.008
[10]	GÖSSLING S, MEYER-HABIGHORST C, HUMPE A. A global review of marine air pollution policies, their scope and effectiveness[J]. Ocean & Coastal Management, 2021, 212: 105824.
[11]	SONG J, SHAN Q, ZOU T, et al. Distributed energy management for zero-carbon port microgrid[J]. International Transactions on Electrical Energy Systems, 2022. DOI:10.1155/2022/2752802. doi: 10.1155/2022/2752802
[12]	方斯顿, 赵常宏, 丁肇豪, 等. 面向碳中和的港口综合能源系统(一):典型系统结构与关键问题[J/OL]. 中国电机工程学报:1-22.(2021-12-07)[2022-11-09]. https://doi.org/10.13334/j.0258-8013.pcsee.212120.
	FANG Sidun, ZHAO Changhong, DING Zhaohao, et al. Port integrated energy systems toward carbon neutrality(I):Typical topology and key problems[J/OL]. Proceedings of the CSEE:1-22.(2021-12-07)[2022-11-09]. https://doi.org/10.13334/j.0258-8013.pcsee.212120.
[13]	方斯顿, 赵常宏, 丁肇豪, 等. 面向碳中和的港口综合能源系统(二):能源-交通融合中的柔性资源与关键技术[J/OL]. 中国电机工程学报:1-20.(2021-12-20)[2022-11-09]. https://doi.org/10.13334/j.0258-8013.pcsee.2121.
	FANG Sidun, ZHAO Changhong, DING Zhaohao, et al. Port integrated energy systems toward carbon neutrality(II):Flexible resources and key technologies in energy-transportation integration[J/OL]. Proceedings of the CSEE:1-20.(2021-12-20)[2022-11-09]. https://doi.org/10.13334/j.0258-8013.pcsee.2121.
[14]	彭占磊, 杨之乐, 杨文强, 等. 电化学储能参与电力系统规划运行方法综述[J]. 综合智慧能源, 2022, 44(6):37-44. doi: 10.3969/j.issn.2097-0706.2022.06.004
	PENG Zhanlei, YANG Zhile, YANG Wenqiang, et al. Review on planning and operation methods for power system with participation of electrochemical energy storage systems[J]. Integrated Intelligent Energy, 2022, 44(6):37-44. doi: 10.3969/j.issn.2097-0706.2022.06.004
[15]	蒋文坤, 韩颖慧, 薛智文, 等. 多能互补能源系统中储能原理及其应用[J]. 综合智慧能源, 2022, 44(1):63-71. doi: 10.3969/j.issn.2097-0706.2022.01.009
	JIANG Wenkun, HAN Yinghui, XUE Zhiwen, et al. Energy storage technologies and their applications in multi-energy complementary power system[J]. Integrated Intelligent Energy, 2022, 44(1):63-71. doi: 10.3969/j.issn.2097-0706.2022.01.009
[16]	宋天立. 计及需求响应的港口综合能源系统研究[D]. 南京: 东南大学, 2020.
[17]	杨俊, 詹军, 佘勇. 基于多目标优化模型的港口多载AGV调度方法[J]. 中国航海, 2022, 45(1):66-72.
	YANG Jun, ZHAN Jun, SHE Yong. Multi-objective optimization of multiple loading AGV dispatch in ports[J]. Navigation of China, 2022, 45(1):66-72.
[18]	普月, 纪历, 刘皓明. 考虑综合需求响应的港口能源系统优化运行[J]. 电力需求侧管理, 2021, 23(1):11-17.
	PU Yue, JI Li, LIU Haoming. Optimal operation of port energy system considering integrated demand response[J]. Power Demand Side Management, 2021, 23(1):11-17.
[19]	普月, 刘皓明, 王健, 等. 考虑多源激励的港口能流-物流全过程协同调度优化[J/OL]. 中国电机工程学报:1-20.(2022-08-09)[2022-11-09]. https://doi.org/10.13334/j.0258-8013.pcsee.221326.
	PU Yue, LIU Haoming, WANG Jian, et al. Whole-process collaborative scheduling optimization for port energy flows and logistics flows considering multi-source incentives[J/OL]. Proceedings of the CSEE:1-20.(2022-08-09)[2022-11-09]. https://doi.org/10.13334/j.0258-8013.pcsee.221326.
[20]	应对气候变化司. 《关于做好2022年企业温室气体排放报告管理相关重点工作的通知》解读[EB/OL].(2022-03-15)[2022-11-01]. https://www.mee.gov.cn/zcwj/zcjd/202203/t20220315_971493.shtml.
[21]	李惠军, 陆建强, 周霞, 等. 面向智慧园区系统的网络攻击关联分析与防护策略研究[J]. 综合智慧能源, 2022, 44(7):1-9. doi: 10.3969/j.issn.2097-0706.2022.07.001
	LI Huijun, LU Jianqiang, ZHOU Xia, et al. Network attack association analysis and attack protection strategyfor smart park systems[J]. Integrated Intelligent Energy, 2022, 44(7):1-9. doi: 10.3969/j.issn.2097-0706.2022.07.001

方案	分时电价	储能调控	可转移负荷
1：仅调控储能	√	√	×
2：仅调控负荷	√	×	√
3：储荷协同调控	√	√	√

零碳视角下电气化码头源网荷储协同优化研究

Study on source-grid-load-storage cooperative optimization of an electrified quay from the perspective of zero carbon

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