Revenue allocation strategy for cooperation alliance of distributed new energies and shared energy storage in the distribution network based on contribution degree

doi:10.19799/j.cnki.2095-4239.2024.1240

Abstract

Abstract:

To meet the grid stability requirements associated with large-scale distributed new energy (DNE) integration into distribution networks, shared energy storage (SES) offers an effective solution for mitigating uncertainty and minimizing deviation penalty costs. However, the multifaceted contributions of DNEs—both economic and operational—when jointly utilizing SES remain insufficiently characterized, and current revenue allocation mechanisms lack fairness and rationality. This study proposes a contribution-based revenue allocation strategy for a cooperative alliance of DNEs and SES. A cooperative model is developed wherein multiple DNE participants co-deploy and share energy storage resources. An optimization-based scheduling model is established to maximize the alliance's net revenue by accounting for electricity sales, operating expenses, and deviation penalties, with opportunity constraints introduced to reflect renewable energy uncertainty. Three contribution indices are formulated—stability contribution, deviation adjustment contribution, and economic contribution—to quantify each DNE's role in alliance performance. These indices are used to define a correction factor that adjusts the classical Shapley value method, resulting in an improved revenue allocation strategy. Case study results demonstrate that the proposed alliance structure reduces deviation penalties and improves net economic benefits by 6.64%. Furthermore, the revised allocation method appropriately reflects the overall contributions of individual DNEs: members with higher stability and deviation adjustment contributions experience revenue increases of 82.73%, while those with stronger economic contributions gain 8.81%. The strategy thus ensures fairness and incentivizes active participation in cooperative storage-sharing schemes.

Key words: distributed new energy, shared energy storage, contribution degree, improved Shapley value method, deviation assessment

CLC Number:

TK 02

Junbo HAO, Guangyin YAN, Honglan PEI, Yingxin ZHAO, Jin HAO. Revenue allocation strategy for cooperation alliance of distributed new energies and shared energy storage in the distribution network based on contribution degree[J]. Energy Storage Science and Technology, 2025, 14(6): 2462-2472.

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References 21

1	李笑竹, 陈来军, 杜锡力, 等. 发电侧共享储能运营机制与交易模式研究综述[J]. 电气工程学报, 2023, 18(1): 188-200.
	LI X Z, CHEN L J, DU X L, et al. Research status and prospect of shared energy storage operation mechanism and trading mode on generation side[J]. Journal of Electrical Engineering, 2023, 18(1): 188-200.
2	潘艳, 赵伟, 徐鹏, 等. 考虑动态电压稳定性的新能源受端电网规划模型[J]. 太阳能学报, 2024, 45(10): 242-248. DOI: 10.19912/j. 0254-0096.tynxb.2023-0969.
	PAN Y, ZHAO W, XU P, et al. Planning model for new energy receiving-end power grid considering dynamic voltage stability[J]. Acta Energiae Solaris Sinica, 2024, 45(10): 242-248. DOI: 10. 19912/j.0254-0096.tynxb.2023-0969.
3	张军, 钟康骅, 张勇军, 等. 基于混合博弈的多区域电-储共享运营模式与经济效益分析[J]. 电力系统自动化, 2024, 48(3): 31-41.
	ZHANG J, ZHONG K H, ZHANG Y J, et al. Hybrid game based sharing operation mode for multi-regional electric power and energy storage and its economic benefit analysis[J]. Automation of Electric Power Systems, 2024, 48(3): 31-41.
4	闫东翔, 陈玥. 共享储能商业模式和定价机制研究综述[J]. 电力系统自动化, 2022, 46(23): 178-191.
	YAN D X, CHEN Y. Review on business model and pricing mechanism for shared energy storage[J]. Automation of Electric Power Systems, 2022, 46(23): 178-191.
5	段佳南, 谢俊, 邢单玺. 风电-光伏-抽蓄-电制氢多主体能源系统增益的合作博弈分配策略[J]. 上海交通大学学报, 2024, 58(6): 872-880. DOI: 10.16183/j.cnki.jsjtu.2022.531.
	DUAN J N, XIE J, XING S X. A cooperative game allocation strategy for wind-solar-pumped storage-hydrogen multi-stakeholder energy system[J]. Journal of Shanghai Jiao Tong University, 2024, 58(6): 872-880. DOI: 10.16183/j.cnki.jsjtu. 2022.531.
6	江岳文, 郑晨昕. 风电场群联合共享储能两阶段协同并网优化[J]. 电网技术, 2022, 46(9): 3426-3439. DOI: 10.13335/j.1000-3673.pst. 2022.0217.
	JIANG Y W, ZHENG C X. Two-stage operation optimization for grid-connected wind farm cluster with shared energy storage[J]. Power System Technology, 2022, 46(9): 3426-3439. DOI: 10. 13335/j.1000-3673.pst.2022.0217.
7	王秀丽, 闫璐, 刘豹, 等. 基于合作-非合作博弈的光储荷网协同运行策略[J]. 太阳能学报, 2023, 44(5): 128-138. DOI: 10.19912/j.0254-0096.tynxb.2022-0574.
	WANG X L, YAN L, LIU B, et al. Cooperative operational strategies of photovoltaic, energy storage, load and power grid based on cooperative and non-cooperative game[J]. Acta Energiae Solaris Sinica, 2023, 44(5): 128-138. DOI: 10.19912/j. 0254-0096.tynxb.2022-0574.
8	刘寅韬, 江全元, 耿光超, 等. 基于合作联盟的电化学储能共享模式研究[J]. 电网技术, 2024, 48(5): 1947-1956. DOI: 10.13335/j.1000-3673.pst.2023.0552.
	LIU Y T, JIANG Q Y, GENG G C, et al. Sharing model of electrochemical energy storage based on cooperative alliance[J]. Power System Technology, 2024, 48(5): 1947-1956. DOI: 10. 13335/j.1000-3673.pst.2023.0552.
9	杨昶兴, 李笑竹, 陈来军, 等. 计及联盟合作成本的新能源场站共享储能优化配置策略[J]. 电网技术, 2025, 49(4): 1403-1412. DOI: 10.13335/j.1000-3673.pst.2024.0957.
	YANG C X, LI X Z, CHEN L J, et al. Energy storage allocation strategy for renewable energy generation station clusters co-build and share considering the cost of alliance cooperation[J]. Power System Technology, 2025, 49(4): 1403-1412. DOI: 10.13335/j. 1000-3673.pst.2024.0957.
10	张海宁, 陶以彬, 梅惠, 等. 基于合作博弈的风光储集群协同优化调度模型[J]. 热力发电, 2021, 50(8): 87-94. DOI: 10.19666/j.rlfd. 202102023.
	ZHANG H N, TAO Y B, MEI H, et al. Collaborative optimal scheduling model of photovoltaic-wind-battery cluster based on cooperative game[J]. Thermal Power Generation, 2021, 50(8): 87-94. DOI: 10.19666/j.rlfd.202102023.
11	郝俊博, 闫晓宏, 裴红兰, 等. 基于改进Shapley值的台区多共享储能运行效能分配方法[J]. 储能科学与技术, 2025, 10(4): 1507-1518. DOI:10.19799/j.cnki.2095-4239.2024.0888.
	HAO J B, YAN X H, PEI H L, et al. Allocation method of operational efficiency of multi-shared energy storages in the distribution network based on Improved-Shapley value[J/OL]. Energy Storage Science and Technology, 2025, 10(4): 1507-1518. DOI:10.19799/j.cnki.2095-4239.2024.0888.
12	仓鹤鸣, 蔺红. 基于电价联动的虚拟电厂源-荷协调经济性研究[J]. 现代电子技术, 2022, 45(23): 149-155. DOI: 10.16652/j.issn.1004-373x.2022.23.028.
	CANG H M, LIN H. Economic research on virtual power plant source-load coordination based on electricity price linkage[J]. Modern Electronics Technique, 2022, 45(23): 149-155. DOI: 10.16652/j.issn.1004-373x.2022.23.028.
13	刘吉成, 郭启蒙, 孙嘉康. 区块链下虚拟电厂混合储能容量优化配置及收益分配[J]. 现代电力, 2023, 40(6): 957-966. DOI: 10.19725/j.cnki.1007-2322.2022.0102.
	LIU J C, GUO Q M, SUN J K. Optimal allocation and revenue distribution of hybrid energy storage capacity in virtual power plant under blockchain[J]. Modern Electric Power, 2023, 40(6): 957-966. DOI: 10.19725/j.cnki.1007-2322.2022.0102.
14	余思雨. 虚拟电厂多时间尺度内部优化调度与利益均衡[D]. 北京: 华北电力大学, 2021. DOI: 10.27140/d.cnki.ghbbu.2021.001159.
	YU S Y. Multi-time scale internal optimal dispatch and benefit balance of virtual power plant[D]. Beijing: North China Electric Power University, 2021. DOI: 10.27140/d.cnki.ghbbu. 2021. 001159.
15	赵瑞锋, 郑文杰, 余志文, 等. 基于合作博弈的光伏产销者分布式储能容量优化配置[J]. 可再生能源, 2023, 41(10): 1391-1400. DOI: 10.13941/j.cnki.21-1469/tk.2023.10.013.
	ZHAO R F, ZHENG W J, YU Z W, et al. Optimal allocation strategy of distributed energy storage capacity based on cooperative game[J]. Renewable Energy Resources, 2023, 41(10): 1391-1400. DOI: 10.13941/j.cnki.21-1469/tk.2023.10.013.
16	侯晨佳. 基于博弈论的虚拟电厂电源优化配置[D]. 北京: 华北电力大学, 2021. DOI: 10.27140/d.cnki.ghbbu.2021.000397.
	HOU C J. Optimization allocation of generators in virtual power plant based on game theory[D]. Beijing: North China Electric Power University, 2021. DOI: 10.27140/d.cnki.ghbbu. 2021. 000397.
17	栗占伟, 樊东方, 曾超, 等. 考虑风光消纳的储能系统容量优化配置及运行策略研究[J]. 储能科学与技术, 2024, 13(8): 2713-2725. DOI: 10.19799/j.cnki.2095-4239.2024.0165.
	LI Z W, FAN D F, ZENG C, et al. Research on capacity optimization configuration and operation strategy of energy storage system considering wind and solar consumption[J]. Energy Storage Science and Technology, 2024, 13(8): 2713-2725. DOI: 10.19799/j.cnki.2095-4239.2024.0165.
18	黄旭, 祖国强, 司威, 等. 配电台区灵活资源多时间尺度优化调度方法——以含虚拟储能的建筑微网为例[J]. 储能科学与技术, 2024, 13(2): 568-577. DOI: 10.19799/j.cnki.2095-4239.2023.0677.
	HUANG X, ZU G Q, SI W, et al. Multi-time-scale optimal scheduling method for flexible resources at distribution stations: A case study of building microgrid considering virtual storage system[J]. Energy Storage Science and Technology, 2024, 13(2): 568-577. DOI: 10.19799/j.cnki.2095-4239.2023.0677.
19	石俊逸, 贾燕冰, 韩肖清, 等. 基于改进p-有效点法的多风电场共享储能联合参与一次调频的容量优化[J]. 太阳能学报, 2024, 45(8): 503-512. DOI: 10.19912/j.0254-0096.tynxb.2023-0542.
	SHI J Y, JIA Y B, HAN X Q, et al. Capacity optimization of multi-wind farm sharing energy storage joint participation in primary frequency regulation based on improved p-effective point method[J]. Acta Energiae Solaris Sinica, 2024, 45(8): 503-512. DOI: 10.19912/j.0254-0096.tynxb.2023-0542.
20	KARIMI H, JADID S. Sustainable and reliability based coalition forming model for smart multi-microgrid systems considering battery and water storage systems[J]. Journal of Energy Storage, 2024, 102: 114050. DOI: 10.1016/j.est.2024.114050.
21	国家发展改革委, 国家能源局. 国家发展改革委国家能源局关于深化新能源上网电价市场化改革促进新能源高质量发展的通知[EB/OL]. [2025-01-17]. https://zfxxgk.ndrc.gov.cn/web/iteminfo.jspid=20482.

参数	数值
额定功率	9 MW
额定容量	18 MWh
充/放电效率	0.89/0.89
初始SOC	0.5
SOC上限	0.9
SOC下限	0.1
单位电量运行成本	300元/MWh

模式	新能源运行成本/元	储能运行成本/元	偏差惩罚成本/元	总收入/元	净收益/元
DES1	25720.85	3641.34	1359.18	58122.63	27401.26
DES2	15601.24	2214.26	850.76	29261.47	10595.21
DES3	10458.33	487.69	791.33	20390.12	8652.77
DES4	6351.45	335.04	380.70	14203.06	7135.86
分散-不合作	58131.88	6678.33	3381.97	121977.28	53785.10
共享-不合作	58131.88	837.07	11431.26	122506.15	52105.95
共享-合作	58131.88	5365.27	860.17	121712.42	57355.10

序号	联盟组合	总成本/元	总收益/元	净收益/元	盈余收益/元
1	{PW1}	30721.37	58122.63	27401.26	0
2	{PW2}	18666.26	29261.47	10595.21	0
3	{PV1}	11737.35	20390.12	8652.77	0
4	{PV2}	7067.20	14203.06	7135.86	0
5	{PW1,PW2}	47102.85	87385.85	40283.00	2286.52
6	{PW1,PV1}	42218.64	78417.27	36198.63	144.59
7	{PW1,PV2}	37063.07	72234.84	35171.77	634.65
8	{PW2,PV1}	29135.31	49569.82	20434.51	1186.53
9	{PW2,PV2}	25106.16	43425.30	18319.14	588.07
10	{PV1,PV2}	18286.55	34580.17	16293.61	504.98
11	{PW1,PW2,PV1}	58090.01	107624.98	49534.97	2885.73
12	{PW1,PW2,PV2}	53468.55	101470.85	48002.30	2869.98
13	{PW1,PV1,PV2}	48602.40	92614.12	44011.72	821.83
14	{PW2,PV1,PV2}	35664.07	63758.55	28094.47	1710.63
15	{PW1,PW2,PV1,PV2}	64357.32	121712.42	57355.10	3570.00

分配策略	PW1	PW2	PV1	PV2
策略2	-0.1280	-0.1420	0.1235	0.1464
策略3	-0.0638	-0.0249	-0.0633	0.1520
策略4	-0.1568	0.2385	-0.1055	0.0238
策略5	-0.1109	0.0190	-0.0199	0.1119

分配策略	PW1	PW2	PV1	PV2	总计
策略1	28183.46	12372.35	9044.78	7754.51	57355.10
策略2	20844.77	4227.15	16129.92	16153.26	57355.10
策略3	24523.30	10945.39	5413.77	16472.64	57355.10
策略4	19191.78	26054.25	2992.12	9116.94	57355.10
策略5	21820.29	13462.58	7902.12	14170.12	57355.10