城轨超级电容储能的容量配置和控制策略研究

doi:10.19799/j.cnki.2095-4239.2019.0275

摘要/Abstract

摘要：

采用超级电容储能装置实现轨道交通工程存在的再生制动能量吸收功能，同时可以有效解决逆变回馈型节能装置的再生能量倒送110 kV主变电所问题。本文以实际工程中的列车运行参数为基础，对列车制动过程进行力学和电学分析，提出了电容储能型节能装置的整体设计方案。储能型节能装置包括双向斩波器和超级电容组，斩波器主电路采用交错并联的双向Buck-Boost电路，超级电容组采用串并联方案；根据储能装置的电压和电流需求，设计了超级电容组的串联配置数量和并联配置数量。建立了列车、整流机组和储能装置模型，并在此基础上设计了储能装置中斩波电路的控制策略，实现储能装置在列车制动过程中能量的储存功能和牵引过程中能量的释放功能；最后以PWM整流器的功率源模式作为列车模拟源，模拟列车的牵引过程和制动过程，通过试验验证了斩波电路的控制策略和超级电容组的充放电特性，结果表明该储能方案的斩波电路控制策略和电容组容量配置方案满足要求。

关键词: 超级电容, 容量配置, Buck-Boost, 控制策略

Abstract:

Supercapacitor energy storage devices are used to realize the regenerative braking energy absorption functions in rail transit projects. These devices can be effectively used to solve the problem that the inverter feedback-type energy-saving device transmits the regenerative energy to the 110-kV main substation. Based on the train operation parameters in the actual project, mechanical and electrical analyses of the train-braking process are conducted. Further, an overall designs scheme of the energy-saving device with capacitor energy storage is proposed. The energy-storage-type energy-saving device includes a two-way chopper and a supercapacitor bank. The main circuit of the chopper adopts a staggered parallel two-way buck-boost circuit, and the supercapacitor bank adopts a series and parallel scheme. According to the voltage and current requirements of the energy storage device, several series and parallel configurations are designed for a supercapacitor bank. Based on the train model, rectifier unit, and energy storage device, a control strategy is designed for the chopper circuit in the energy storage device to realize energy storage during train braking and energy release during traction. Finally, the pulse-width modulator rectifier in its power-source mode is used as the train simulation source to simulate the traction and braking processes of the train. The control strategy of the chopper circuit and the charging and discharging characteristics of the supercapacitor are verified through experiments. Results show that the control strategy of the chopper circuit and the capacity configuration scheme of the power bank of the energy storage scheme satisfy the requirements of the source device.

Key words: super capacitor, capacity configuration, Buck-Boost, control strategy

中图分类号:

TM 64

赵正一, 俞葆青, 孔德卿, 任海滢. 城轨超级电容储能的容量配置和控制策略研究[J]. 储能科学与技术, 2020, 9(5): 1558-1561.

Zhengyi ZHAO, Baoqing YU, Deqing KONG, Haiying REN. Research on capacity configuration and control strategy of the super capacitor energy storage device for rail transit[J]. Energy Storage Science and Technology, 2020, 9(5): 1558-1561.

图/表 5

参考文献 9

1	许爱国, 谢少军, 姚远. 基于超级电容的城市轨道交通车辆再生制动能量吸收系统[J]. 电工技术学报, 2010(3): 118-123.
	XU Aiguo, XIE Shaojun, YAO Yuan. Regenerating energy storage system based on ultra-capacitor for urban railway vehicles[J]. Transactions of China Electrotechnical Society, 2010(3): 118-123.
2	刘广欢, 刘兰, 陈广赞, 等. 基于超级电容储能的列车制动节能技术[J]. 大功率变流技术, 2017(2): 47-50.
	LIU Guanghuan, LIU Lan, CHEN Guangzan, et al. Braking energy saving technology of train based on super capacitor energy storage[J]. High Power Converter Technology, 2017(2): 47-50.
3	王彬, 杨中平, 林飞，等.超级电容储能装置容量配置影响因素分析[J]. 都市快轨交通, 2014(3): 18-22.
	WANG Bin, YANG Zhongping, LIN Fei, et al. Impact factors analysis of capacity configuration of super-capacitor energy storage device[J]. Urban Rapid Rail Transit, 2014(3): 18-22.
4	秦晓宇, 赵大伟. 再生能量吸收装置在轨道交通中的应用与配置优化[J]. 电气化铁道, 2018(4): 44-47.
	QIN Xiaoyu, ZHAO Dawei. Application and arrangement optimization of regenerative energy absorbing device in urban rail transit[J]. Urban Mass Transit, 2018(4): 44-47.
5	曹成琦, 王欣, 秦斌, 等. 超级电容储能系统中双向DC-DC变换器控制策略研究[J]. 湖北工业大学学报, 2016(6): 19-22.
	CAO Chengqi, WANG Xin, QIN Bin, et al. Research on control strategy for bi-directional DC-DC converter in super apacitor energy storage system[J]. Journal of HUST, 2016(6): 19-22.
6	王龙军. 轨道交通超级电容储能双向 DC-DC 变换器拓扑分析[C]// 电气化铁道： 2019年中国电气化铁路发展 60 年暨智能牵引供电技术论坛论文集, 2019： 108-111.
	WANG Longjun. Analysis of topology of bilateral DC-DC converter of super capacitor storage of urban mass transit[C]//Urban Mass Transit: Paper Collection of 60 Years' Development of China's Electrified Railway and Intelligent Traction Power Supply Technology Forum in 2019, 2019: 108-111.
7	王彬, 杨中平, 林飞, 等. 基于节能稳压的地面式超级电容储能系统容量配置优化研究[J]. 铁道学报, 2016(6): 46-52.
	WANG Bin, YANG Zhongping, LIN Fei, et al. Study on optimization of capacity configuration of stationary super capacitor storage system for improving energy efficiency and voltage profile[J]. Journal of the China Railway Society, 2016(6): 46-52.
8	叶兰兰, 邹凯, 宋立. 城市轨道交通超级电容储能装置控制策略[J]. 都市快轨交通, 2017(5): 118-122.
	YE Lanlan, ZOU Kai, SONG Li. Control strategy for super capacitor energy storage device of urban rail transit[J]. Urban Rapid Rail Transit, 2017(5): 118-122.
9	赵思锋, 唐英伟, 王赛, 等. 基于飞轮储能技术的城市轨道交通再生能回收控制策略研究[J]. 储能科学与技术, 2018, 7(3): 524-529.
	ZHAO Sifeng, TANG Yingwei, WANG Sai, et al. The study of control strategy for urban mass transit based on flywheel energy storage system[J]. Energy Storage Science and Technology, 2018, 7(3): 524-529.

[1]	王宇作, 卢颖莉, 邓苗, 杨斌, 于学文, 荆葛, 阮殿波. 超级电容器自放电的研究进展[J]. 储能科学与技术, 2022, 11(7): 2114-2125.
[2]	董树锋, 刘灵冲, 唐坤杰, 赵海祺, 徐成司, 林立亨. 基于Simulink和低代码控制器的储能控制实验教学方法[J]. 储能科学与技术, 2022, 11(7): 2386-2397.
[3]	杨孝杰, 王海云, 蒋中川, 宋章华. 应用于飞轮储能的BLDC电机功率双向流动策略设计[J]. 储能科学与技术, 2022, 11(7): 2233-2240.
[4]	林楠, KREWER Ulrike, ZAUSCH Jochen, STEINER Konrad, 林海波, 冯守华. 电化学能量储存和转换体系多物理场模型的建立及其应用[J]. 储能科学与技术, 2022, 11(4): 1149-1164.
[5]	郭铁柱, 周迪, 张传芳. MXenes胶体氧化的调控策略及其对超级电容器性能的影响[J]. 储能科学与技术, 2022, 11(4): 1165-1174.
[6]	佟永丽, 武祥. 金属有机框架衍生的Co₃O₄ 电极材料及其电化学性能[J]. 储能科学与技术, 2022, 11(3): 1035-1043.
[7]	岳博文, 佟佳欢, 刘玉文, 霍锋. 离子液体电解液的模拟计算方法及应用[J]. 储能科学与技术, 2022, 11(3): 897-911.
[8]	陈玉龙, 武鑫, 滕伟, 柳亦兵. 用于风电功率平抑的飞轮储能阵列功率协调控制策略[J]. 储能科学与技术, 2022, 11(2): 600-608.
[9]	韩雪, 邓伟, 周旭峰, 刘兆平. 石墨烯在储能领域应用的专利分析[J]. 储能科学与技术, 2022, 11(1): 335-349.
[10]	张诗钽, 楚帅, 葛维春, 李音璇, 刘闯. 大规模弃风与储热协调调控评估方法[J]. 储能科学与技术, 2022, 11(1): 283-290.
[11]	乔亮波, 张晓虎, 孙现众, 张熊, 马衍伟. 电池-超级电容器混合储能系统研究进展[J]. 储能科学与技术, 2022, 11(1): 98-106.
[12]	谢雨轩, 白云驹, 肖意军. 含地面充电桩的储能式有轨电车车地整体性容量配置[J]. 储能科学与技术, 2021, 10(4): 1388-1399.
[13]	毕志杰, 赵宁, 郭向欣. 基于氧化钨和普鲁士蓝的可变色超级电容器[J]. 储能科学与技术, 2021, 10(3): 952-957.
[14]	王凯, 侯朝霞, 李思瑶, 屈晨滢, 王悦, 孔佑健. 可拉伸全固态超级电容器的研究进展[J]. 储能科学与技术, 2021, 10(3): 887-895.
[15]	陈帅, 陈灵, 江浩. 氮掺杂无定形氧化钒纳米片阵列用于快充型准固态超级电容器[J]. 储能科学与技术, 2021, 10(3): 945-951.