Equivalent energy storage model for district heating network and its application in non-iterative combined electricity-heat scheduling

doi:10.11930/j.issn.1004-9649.202509039

Abstract

Abstract:

District heating networks exhibit considerable energy storage potential due to their thermal inertia, enabling sufficient operational flexibility for power systems. However, the complex energy transfer characteristics and data privacy concerns of heating networks pose great challenges to the accurate evaluation of their storage capability. To address this issue, an approximate model considering dynamic properties of heating networks is proposed to aggregate the storage capacity of heating networks. First, the flexibility of the heating network is modeled as a physically meaningful equivalent energy storage model to quantify the thermal storage capacity of pipelines. Building upon this, the basic polyhedron translation and scaling method is employed to determine the parameters of the heating network equivalent energy storage model. Furthermore, the proposed flexibility aggregation model is applied to the coordinated optimization of integrated electricity-thermal energy systems, and numerical simulations are conducted for validation. Simulation results demonstrate that the proposed aggregation model can solve the combined power-heat dispatch problem non-iteratively while avoiding the detailed heating network modeling required by conventional centralized approaches. Meanwhile, the optimized results can maintain a high level of computational accuracy.

Key words: district heating network, equivalent energy storage, flexibility aggregation, combined electricity-heat scheduling

WENG Liangtao, XIAO Tianying, ZHENG Weiye. Equivalent energy storage model for district heating network and its application in non-iterative combined electricity-heat scheduling[J]. Electric Power, 2026, 59(6): 145-153.

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References 34

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方法	总调度成本/美元	迭代次数	从热网收集的约束数量	计算时间/s	隐私保护
集中式调度	39323	1	1536	0.027	否
分布式调度（Benders算法）	39323	19	1257	0.093	是
本文所提方法	39323	1	96	0.025	是

方法	总调度成本/美元	迭代次数	从热网收集的约束数量	计算时间/s	隐私保护
集中式调度	39323	1	1536	0.027	否
分布式调度（Benders算法）	39323	19	1257	0.093	是
本文所提方法	39323	1	96	0.025	是

场景	总调度成本/美元		误差/%
场景	集中式	所提方法	误差/%
1	95495	96534	1.09
2	95499	97270	1.85
3	95496	95723	0.24
4	95496	100060	4.78
5	95499	96884	1.45
6	95498	97971	2.59
7	95496	95925	0.49
8	95495	99529	4.23
9	95497	98233	2.87
10	95497	96505	1.06

场景	总调度成本/美元		误差/%
场景	集中式	所提方法	误差/%
1	95495	96534	1.09
2	95499	97270	1.85
3	95496	95723	0.24
4	95496	100060	4.78
5	95499	96884	1.45
6	95498	97971	2.59
7	95496	95925	0.49
8	95495	99529	4.23
9	95497	98233	2.87
10	95497	96505	1.06

方法	总调度成本/ 美元	从热网收集的约束数量	计算时间/s
集中式调度	633181	10320	69.54
本文所提方法	656343	480	3.55