Day-Ahead Scheduling of Traction Power Supply System with Photovoltaic and Energy Storage Access

doi:10.16183/j.cnki.jsjtu.2022.253

Abstract

Abstract:

In recent years, in order to achieve the goal of “carbon peaking and carbon neutrality” of the electrified railway, a number of railroad energy optimization initiatives have been implemented, but with little success. To further reduce the carbon emissions of the electrified railway, its energy supply structure is changed by connecting photovoltaic and energy storage devices to the traction power supply system. First, the composite traction power supply system is constructed, and its working conditions are classified according to the composition of system energy supply. Then, the priorities are set based on the priorities of system operation constraints, and the optimal state of the system under different operating conditions is realized through hierarchical optimization. Finally, the converter capacity is reasonably optimized to achieve the minimum carbon emission under the win-win situation of the system operation performance and economic benefits. The simulation results show that the composite traction power supply system ensures the stable operation of the system while greatly reducing the carbon emission of the system and achieving the optimal performance.

Key words: electrified railway, traction power supply system, photovoltaic power generation, energy storage device, railway carbon emission

CLC Number:

U223.6

GAO Fengyang, SONG Zhixiang, GAO Jianning, GAO Xuanyu, YANG Kaiwen. Day-Ahead Scheduling of Traction Power Supply System with Photovoltaic and Energy Storage Access[J]. Journal of Shanghai Jiao Tong University, 2024, 58(5): 760-775.

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储能分类	功率密度/ (W·kg^-1)	能量密度/ [(W·h)·kg^-1]	效率,η/%	单位成本	技术成熟度
飞轮储能	180~1800	5~50	90~95	250~350/(元·kW^-1)	试运行阶段
蓄电池	35~240	30~70	63~90	120~500/[元·(kW·h)^-1]	成熟
锂电池	500~3000	80~250	90~95	500~1200/[元·(kW·h)^-1]	成熟
超导电磁储能	10²~10⁵	1~10	90~98	200~700/(元·kW^-1)	研究阶段
电容储能	7000~18000	2.5~15	90~97	100~360/(元·kW^-1)	试运行阶段

形式	荷电状态/%
形式	健康	亚健康	不健康
充电	[20, 80]	(15, 20)∪(80, 85)	[0, 15]∪[85, 100]
放电	[25, 85]	(20, 25)∪(85, 90)	[0, 20]∪[90, 100]

系统方案	平均1 h碳排放量/kg	平均1 h变流器容量利用率/%	平均1 h系统综合性能(p.u.)
调度前	2229.9700	11.7175	0.8549
方案1	2576.3800	13.3592	0.8634
方案2	2259.5160	13.3135	0.8571
方案3	2256.3750	13.3992	0.8669