Optimization Strategy for Spatiotemporal Cooperative Operation of Multiple Data Centers Considering Load Response Characteristics

doi:10.11930/j.issn.1004-9649.202412049

Abstract

Abstract:

Unlike traditional flexible loads that have only temporal regulation capability, the loads of multiple data centers can be migrated among them both in time and spatiality, thus becoming a flexible demand response resource with temporal and spatial regulation potential. However, previous studies on load management of multiple data centers have neglected the need for multiple time windows depending on the timeliness in batch load response characteristics. In this regard, we propose a spatio-temporal cooperative operation optimization strategy for multiple data centers considering the load response characteristics. Firstly, the coupling of business and energy flows of multiple data centers is modeled to flexibly configure the number of servers powered on. Then, the temporal and spatial migration characteristics of batch loads are analyzed to establish a multi-data center demand response mechanism. And then, a multi-data center operation optimization model is established with minimum total operation cost as the objective function and user satisfaction as the constraint. Finally, a case study is carried out with multiple data centers as an example. The simulation results show that the proposed scheme can effectively stimulate the demand response potential of multiple data centers, reduce the total operation cost while ensuring user satisfaction, and provide an effective load management strategy for multiple data centers.

Key words: load response characteristics, multiple data centers, spatio-temporal coordination, multiple time windows, business flow and energy flow coupling, demand response

XIANG Shilin, XIANG Yue, WANG Yanliang, LU Yu. Optimization Strategy for Spatiotemporal Cooperative Operation of Multiple Data Centers Considering Load Response Characteristics[J]. Electric Power, 2025, 58(4): 170-181.

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URL: https://www.electricpower.com.cn/EN/10.11930/j.issn.1004-9649.202412049

https://www.electricpower.com.cn/EN/Y2025/V58/I4/170

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References 28

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参数	取值	参数	取值
$ \gamma _i^{{\text{pue}}} $	1.25	$ P_i^{\max } $/kW	0.65
$ m $/%	10	$ P_i^{_{{\text{idle}}}} $/kW	0.25
$ \bar N $/台	10000	$ {d^{{\text{ser}}}} $/(个·h^–1)	85
$ T_{i,t}^{\max } $/h	0.1	$ {v^{{\text{dtol}}}} $/(个·h^–1)	8000
$ \alpha $	90	$ {c^{{\text{mig}}}} $/(元·个^–1)	10^–4

参数	取值	参数	取值
$ \gamma _i^{{\text{pue}}} $	1.25	$ P_i^{\max } $/kW	0.65
$ m $/%	10	$ P_i^{_{{\text{idle}}}} $/kW	0.25
$ \bar N $/台	10000	$ {d^{{\text{ser}}}} $/(个·h^–1)	85
$ T_{i,t}^{\max } $/h	0.1	$ {v^{{\text{dtol}}}} $/(个·h^–1)	8000
$ \alpha $	90	$ {c^{{\text{mig}}}} $/(元·个^–1)	10^–4

对比项	平均开机数量/台	平均CPU 利用率	总用电功率/kW	购电成本/元
灵活配置前	6 000	0.6534	366 082	255 869
灵活配置后	4 308	0.8999	315 321	227 436
变化率/%	–28.2	37.7	–13.9	–11.1

对比项	平均开机数量/台	平均CPU 利用率	总用电功率/kW	购电成本/元
灵活配置前	6 000	0.6534	366 082	255 869
灵活配置后	4 308	0.8999	315 321	227 436
变化率/%	–28.2	37.7	–13.9	–11.1

场景	总成本/元	购电成本/元	迁移成本/元	成本降低率/%
1	227 436	227 436	—	—
2	220 455	220 189	266	3.1
3	216 903	216 496	407	4.6
4	210 469	209 823	646	7.5