Coordinated Planning of Medium-Voltage and Low-Voltage Flexible Interconnection for Distribution Networks with High Proportion of Distributed Generation

doi:10.11930/j.issn.1004-9649.202309007

Abstract

Abstract:

Flexible interconnection technology is one of the effective means to solve numerous problems faced by distribution networks with high proportion of distributed generations (DGs). A multi-layer optimization based coordinated planning method for medium-voltage and low voltage flexible interconnection of distribution networks is proposed. Firstly, a power flow model for distribution network with medium-voltage and low-voltage flexible interconnection based on power electronics flexible interconnected devices (FID) is built. Then, a three-layer coordinated planning model is constructed. With the upper layer aiming to minimize the annual operating cost of low-voltage FIDs and the annual variance of transformer load rate in substation areas, and the middle layer aiming to minimize the annual operating cost of medium voltage FIDs and the annual electricity purchasing cost from the higher-level power grid, they respectively determine the installation location and capacity of low-voltage and medium-voltage FIDs. The lower layer optimizes the system operation with the goal of minimizing the electricity purchasing cost from the higher-level power grid in each scenario. A hybrid algorithm based on adaptive particle swarm optimization and second-order cone programming is adopted for solution. Finally, an IEEE-33 node distribution network with a high proportion of DGs is used for case study, and the results indicate that through flexible interconnection planning, the annual comprehensive operating cost of the example system is reduced by 19.01% and the annual variance of transformer load rate in substation areas is reduced by 82.59%, showing the effectiveness of the proposed planning model.

Key words: distributed generation, medium-voltage and low-voltage flexible interconnection, coordinated planning, power electronics flexible interconnection device, transformer load rate in substation area

Hanmei PENG, Tang YIN, Qianhao XIAO, Mao TAN, Yongxin SU, Hui LI. Coordinated Planning of Medium-Voltage and Low-Voltage Flexible Interconnection for Distribution Networks with High Proportion of Distributed Generation[J]. Electric Power, 2024, 57(8): 117-129.

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URL: https://www.electricpower.com.cn/EN/10.11930/j.issn.1004-9649.202309007

https://www.electricpower.com.cn/EN/Y2024/V57/I8/117

Figures/Tables 12

References 26

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台区编号	交流负荷/ kW	直流负荷/ kW	交流负荷类型	变压器额定容量/ kV·A	光伏有功容量/ kW	台区编号	交流负荷/ kW	直流负荷/ kW	交流负荷类型	变压器额定容量/ kV·A	光伏有功容量/ kW	台区编号	交流负荷/ kW	直流负荷/ kW	交流负荷类型	变压器额定容量/ kV·A	光伏有功容量/ kW
2	140	0	E	160	0	13	150	0	D	160	110	24	180	30	D	200	150
3	130	0	E	160	0	14	150	0	D	160	40	25	110	0	B	160	0
4	155	0	D	160	120	15	140	30	C	200	0	26	210	0	E	315	80
5	160	30	C	200	0	16	200	0	D	200	40	27	140	30	B	160	30
6	300	0	D	315	130	17	140	0	B	160	40	28	140	0	A	200	30
7	180	30	E	200	0	18	150	0	D	160	120	29	130	0	E	160	0
8	100	0	B	160	120	19	135	0	E	160	0	30	140	0	E	160	0
9	130	30	C	160	0	20	140	0	D	160	30	31	180	0	C	200	40
10	125	0	E	160	50	21	130	30	B	200	0	32	150	0	D	160	120
11	290	0	E	315	0	22	140	0	E	160	30	33	130	0	B	200	0
12	100	0	A	160	0	23	120	0	E	160	30

台区编号	交流负荷/ kW	直流负荷/ kW	交流负荷类型	变压器额定容量/ kV·A	光伏有功容量/ kW	台区编号	交流负荷/ kW	直流负荷/ kW	交流负荷类型	变压器额定容量/ kV·A	光伏有功容量/ kW	台区编号	交流负荷/ kW	直流负荷/ kW	交流负荷类型	变压器额定容量/ kV·A	光伏有功容量/ kW
2	140	0	E	160	0	13	150	0	D	160	110	24	180	30	D	200	150
3	130	0	E	160	0	14	150	0	D	160	40	25	110	0	B	160	0
4	155	0	D	160	120	15	140	30	C	200	0	26	210	0	E	315	80
5	160	30	C	200	0	16	200	0	D	200	40	27	140	30	B	160	30
6	300	0	D	315	130	17	140	0	B	160	40	28	140	0	A	200	30
7	180	30	E	200	0	18	150	0	D	160	120	29	130	0	E	160	0
8	100	0	B	160	120	19	135	0	E	160	0	30	140	0	E	160	0
9	130	30	C	160	0	20	140	0	D	160	30	31	180	0	C	200	40
10	125	0	E	160	50	21	130	30	B	200	0	32	150	0	D	160	120
11	290	0	E	315	0	22	140	0	E	160	30	33	130	0	B	200	0
12	100	0	A	160	0	23	120	0	E	160	30

参数	数值	参数	数值	参数	数值
中压B2B VSC贴现率	0.04	低压VSC贴现率	0.04	直流联络线贴现率	0.04
中压B2B VSC经济使用年限/年	20	低压VSC经济使用年限/年	20	直流联络线经济使用年限/年	20
中压B2B VSC单位容量投资成本/ (元·(kV·A)^–1)	600	低压VSC单位容量投资成本/ (元·(kV·A)^–1)	300	直流联络线单位长度的等值投资成本/ (元·km^–1)	6324
中压B2B VSC单位容量年运行维护费用/(元·(kV·A)^–1)	10	低压VSC单位容量年运行维护费用/ (元·(kV·A)^–1)	5.5	直流联络线最大传输有功功率/kW	150
中压B2B VSC最大可安装容量/(kV·A)	800	低压VSC最大可安装容量/(kV·A)	150	直流联络线损耗系数	0.01
中压B2B VSC单位安装容量/(kV·A)	50	低压VSC单位安装容量/(kV·A)	10	中、低压VSC损耗系数	0.02
平时段[06:00—10:00、14:00— 16:00、20:00—22:00]购电价格/ (元·(kW·h)^–1)	0.6723	谷时段[00:00—06:00、22:00— 24:00]购电价格/(元·(kW·h)^–1)	0.3814	峰时段[10:00—14:00、16:00—20:00] 购电价格/(元·(kW·h)^–1)	0.9618

参数	数值	参数	数值	参数	数值
中压B2B VSC贴现率	0.04	低压VSC贴现率	0.04	直流联络线贴现率	0.04
中压B2B VSC经济使用年限/年	20	低压VSC经济使用年限/年	20	直流联络线经济使用年限/年	20
中压B2B VSC单位容量投资成本/ (元·(kV·A)^–1)	600	低压VSC单位容量投资成本/ (元·(kV·A)^–1)	300	直流联络线单位长度的等值投资成本/ (元·km^–1)	6324
中压B2B VSC单位容量年运行维护费用/(元·(kV·A)^–1)	10	低压VSC单位容量年运行维护费用/ (元·(kV·A)^–1)	5.5	直流联络线最大传输有功功率/kW	150
中压B2B VSC最大可安装容量/(kV·A)	800	低压VSC最大可安装容量/(kV·A)	150	直流联络线损耗系数	0.01
中压B2B VSC单位安装容量/(kV·A)	50	低压VSC单位安装容量/(kV·A)	10	中、低压VSC损耗系数	0.02
平时段[06:00—10:00、14:00— 16:00、20:00—22:00]购电价格/ (元·(kW·h)^–1)	0.6723	谷时段[00:00—06:00、22:00— 24:00]购电价格/(元·(kW·h)^–1)	0.3814	峰时段[10:00—14:00、16:00—20:00] 购电价格/(元·(kW·h)^–1)	0.9618

台区编号	S_VSCLI/ kV·A	β(t)	台区编号	S_VSCLI/ kV·A	β(t)	台区编号	S_VSCLI/ kV·A	β(t)
3	80	0.45	14	30	0.45	23	80	0.39
4	10	0.46	15	40	0.58	26	60	0.45
5	100	0.45	16	90	0.45	27	120	0.45
6	150	0.45	17	90	0.46	28	20	0.56
8	50	0.47	18	70	0.46	31	150	0.45
9	120	0.45	20	10	0.45	32	70	0.45
10	100	0.46	21	20	0.60	33	90	0.46
13	80	0.45	22	30	0.46