Equivalent modeling of large-scale photovoltaic hydrogen production stations driven by physics-data collaboration

doi:10.11930/j.issn.1004-9649.202507070

Abstract

Abstract:

To address the problem of the traditional single-driven modeling methods being difficult to accurately characterize the complex dynamic characteristics of photovoltaic (PV) hydrogen production stations under different operating states, an equivalent modeling method for large-scale photovoltaic hydrogen production stations driven by physics-data collaboration is proposed. Firstly, key factors that can characterize the station's dynamic characteristics are extracted based on physical mechanism analysis. Secondly, a sparse autoencoder is used for dimensionality reduction of the key factor data; under single-phase fault, the data dimension of a single PV unit can be reduced to 3 dimensions with an information retention rate as high as 92.2%. Then, the spectral clustering algorithm is applied to cluster the dimensionality-reduced data features to achieve the equivalent modeling of the entire station. Finally, the effectiveness and accuracy of the proposed equivalent modeling method are verified through single-phase and three-phase fault simulations on the PSCAD/EMTDC platform. Quantitative comparison results indicate that under single and three-phase fault, the fitting accuracy of the power response curve of the proposed equivalent model is superior to the traditional physical-based grouping method and the pure data-driven method.

Key words: physics-data collaborative driven, photovoltaic hydrogen production station, equivalent modeling, sparse autoencoder, spectral clustering

BAI Zhijun, LI Rui, LI Jiankang, HE Chenglong, HU Wei, LIU Yongpan, YUAN Tiejiang. Equivalent modeling of large-scale photovoltaic hydrogen production stations driven by physics-data collaboration[J]. Electric Power, 2026, 59(6): 154-165.

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URL: https://www.electricpower.com.cn/EN/10.11930/j.issn.1004-9649.202507070

https://www.electricpower.com.cn/EN/Y2026/V59/I6/154

Figures/Tables 11

References 35

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类型	参数	数值
220 kV线路	电阻/(Ω·km^–1)	0.080
220 kV线路	电抗/(Ω·km^–1)	0.417
35 kV线路	电阻/(Ω·km^–1)	0.270
35 kV线路	电抗/(Ω·km^–1)	0.379
主变	变比	35 kV/220 kV
	额定容量/(MV·A)	150
	短路电压百分比/%	12.96
箱变	变比	0.4 kV/0.4 kV/35 kV
	额定容量（光伏侧）/(MV·A)	3.15
	额定容量（电解槽侧）/(MV·A)	12.5
	短路电压百分比（光伏侧）/%	7
	短路电压百分比（电解槽侧）/%	10
光伏发电单元	额定容量/MW	3
光伏发电单元	额定光照强度/(W·m^–2)	1000
电解槽单元	额定产氢量/(N·m³·h^–1)	1000

类型	参数	数值
220 kV线路	电阻/(Ω·km^–1)	0.080
220 kV线路	电抗/(Ω·km^–1)	0.417
35 kV线路	电阻/(Ω·km^–1)	0.270
35 kV线路	电抗/(Ω·km^–1)	0.379
主变	变比	35 kV/220 kV
	额定容量/(MV·A)	150
	短路电压百分比/%	12.96
箱变	变比	0.4 kV/0.4 kV/35 kV
	额定容量（光伏侧）/(MV·A)	3.15
	额定容量（电解槽侧）/(MV·A)	12.5
	短路电压百分比（光伏侧）/%	7
	短路电压百分比（电解槽侧）/%	10
光伏发电单元	额定容量/MW	3
光伏发电单元	额定光照强度/(W·m^–2)	1000
电解槽单元	额定产氢量/(N·m³·h^–1)	1000

单元类型	降维维度	均方误差	信息保留率
光伏发电单元	1	0.983	0.632
	2	0.951	0.634
	3	0.738	0.922
	4	0.721	0.923
	5	0.712	0.924
电解槽单元	1	0.979	0.603
	2	0.961	0.613
	3	0.767	0.892
	4	0.734	0.932
	5	0.714	0.947

单元类型	降维维度	均方误差	信息保留率
光伏发电单元	1	0.983	0.632
	2	0.951	0.634
	3	0.738	0.922
	4	0.721	0.923
	5	0.712	0.924
电解槽单元	1	0.979	0.603
	2	0.961	0.613
	3	0.767	0.892
	4	0.734	0.932
	5	0.714	0.947

分群结果	本文等值方法	传统等值方法1	传统等值方法2
光伏子集群1	PV1-PV3、PV7-PV12、PV19-PV20、PV39-PV42、PV48-PV50	PV1- PV10	PV1-PV2、PV8-PV10、PV19-PV20、PV31、PV39-PV43、PV48-PV50
光伏子集群2	PV4-PV6、PV13-PV18、PV23-PV28、PV34-PV37	PV11- PV20	PV3-PV4、PV6-PV7、PV11-PV13、PV18、PV21-PV22、PV29-PV30、PV32-PV33、PV37-PV38、PV44-PV47
光伏子集群3	PV21-PV22、PV29-PV33、PV38、PV43-PV47	PV21- PV30	PV5、PV14-PV17、PV23-PV28、PV34-PV36
光伏子集群4	—	PV31-PV40	—
光伏子集群5	—	PV41-PV50	—
电解槽子集群1	EL1-EL8	EL1-EL8	EL1-EL8
电解槽子集群2	EL9-EL16	EL9-EL16	EL9-EL16
电解槽子集群3	EL17-EL26	EL17-EL26	EL17-EL26