Automatic Connection of Virtual Circuits in Smart Substations Based on Chaotic Two-Dimensional Mapping Sine and Cosine Algorithm

doi:10.11930/j.issn.1004-9649.202403026

Abstract

Abstract:

In this paper, a virtual loop automatic connection technology based on two-dimensional chaotic sine-cosine algorithm is proposed. Firstly, a virtual terminal matching model involving distance weight vector is constructed by using Jaro-Winkler distance. Then, on the basis of the historical data of virtual connection, the optimal distance weight vector is solved by using the two-dimensional chaotic sine-cosine algorithm. Finally, a 66 kV substation in eastern Mongolia is taken as an example to match virtual terminals with the proposed method. The results show that the virtual terminal connection results obtained by the proposed method are more accurate and more efficient than those obtained by the prior art.

Key words: virtual terminal, automatic connection, distance weight vector

CLC Number:

TM77

Guofeng JIN, Shifeng YANG, Lingling LIU, Kai WANG, Qiang WANG, Lei WANG. Automatic Connection of Virtual Circuits in Smart Substations Based on Chaotic Two-Dimensional Mapping Sine and Cosine Algorithm[J]. Electric Power, 2024, 57(8): 152-158.

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URL: https://www.electricpower.com.cn/EN/10.11930/j.issn.1004-9649.202403026

https://www.electricpower.com.cn/EN/Y2024/V57/I8/152

Figures/Tables 6

References 27

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序号	设备名称	设备	安装位置
1	主变保护	PCS-978T1-DA-GCN	预制舱
2	主变测控	PCS-9705G-DA-1	预制舱
3	66 kV线路保护测控	PCS-953A-DA-GCN-C	预制舱
4	66 kV分段保护测控	PCS-923LA-DA-GCN-C	预制舱
5	66 kV备自投	PCS-9651A-DA-GCN	预制舱
6	66 kV母线测控	PCS-9705G-DA-4	预制舱
7	主变66 kV间隔	PCS-224IMJA-DA-GZK	智能柜
8	主变本体终端	PCS-222ITA-GZK	智能柜
9	66 kV线路间隔	PCS-224IMJA-DA-GZK	智能柜
10	66 kV分段间隔	PCS-224IMJA-DA-GZK	智能柜
11	66 kV母线间隔	PCS-224IMMA-DA-GZK	智能柜
12	主变变低间隔	PCS-224IMJA-DA-GZK	智能柜

序号	设备名称	设备	安装位置
1	主变保护	PCS-978T1-DA-GCN	预制舱
2	主变测控	PCS-9705G-DA-1	预制舱
3	66 kV线路保护测控	PCS-953A-DA-GCN-C	预制舱
4	66 kV分段保护测控	PCS-923LA-DA-GCN-C	预制舱
5	66 kV备自投	PCS-9651A-DA-GCN	预制舱
6	66 kV母线测控	PCS-9705G-DA-4	预制舱
7	主变66 kV间隔	PCS-224IMJA-DA-GZK	智能柜
8	主变本体终端	PCS-222ITA-GZK	智能柜
9	66 kV线路间隔	PCS-224IMJA-DA-GZK	智能柜
10	66 kV分段间隔	PCS-224IMJA-DA-GZK	智能柜
11	66 kV母线间隔	PCS-224IMMA-DA-GZK	智能柜
12	主变变低间隔	PCS-224IMJA-DA-GZK	智能柜

序号	输入虚端子	自动连接的输出虚端子	样本匹配的输出虚端子
1	MU额定延时 PISV01/SVINGGIO1. DelayTRtg	额定延时 MUSV01/LLN0. DelayTRtg	额定延迟时间 MUSV/LLN0. DelayTRtg
2	保护A相电流Ia1(正) PISV01/SVINGGIO4. SAVSO1	A相保护电流1 MUSV01/PATCTR1. Amp1	保护1电流A相1 MUSV/TCTR1. Amp
3	保护A相电流Ia2(正) PISV01/SVINGGIO4. SAVSO2	A相保护电流2 MUSV01/PATCTR1. Amp2	保护1电流A相2 MUSV/TCTR1. AmpChB
4	保护B相电流Ib1(正) PISV01/SVINGGIO4. SAVSO3	B相保护电流1 MUSV01/PBTCTR1. Amp1	保护1电流B相1 MUSV/TCTR2. Amp
5	保护B相电流Ib2(正) PISV01/SVINGGIO4. SAVSO4	B相保护电流2 MUSV01/PBTCTR1. Amp2	保护1电流B相2 MUSV/TCTR2. AmpChB
6	保护C相电流Ic1(正) PISV01/SVINGGIO4. SAVSO5	C相保护电流1 MUSV01/PCTCTR1. Amp1	保护1电流C相1 MUSV/TCTR3. Amp
7	保护C相电流Ic2(正) PISV01/SVINGGIO4. SAVSO6	C相保护电流2 MUSV01/PCTCTR1. Amp2	保护1电流C相2 MUSV/TCTR3. AmpChB
8	闭锁重合闸 PIGO01/GOINGGIO1. SPCSO1.stVal	闭锁重合闸 RPIT01/GGIO1. Ind1.stVal	闭锁重合闸RPIT/ProtGGIO. Ind3.stVal
9	保护A相电压Ua1 PISV01/SVINGGIO3. SAVSO1	A相保护测量电压1 MUSV01/UATVTR1. Vol1	保护电压A相1 MUSV/TVTR10. Vol
10	保护A相电压Ua2 PISV01/SVINGGIO3. SAVSO2	A相保护电压2 MUSV01/UATVTR1. Vol2	保护电压A相2 MUSV/TVTR10. VolChB
11	保护B相电压Ub1 PISV01/SVINGGIO3. SAVSO3	B相保护测量电压1 MUSV01/UBTVTR1. Vol1	保护电压B相1 MUSV/TVTR11. Vol
12	保护B相电压Ub2 PISV01/SVINGGIO3. SAVSO4	B相保护电压2 MUSV01/UBTVTR1. Vol2	保护电压B相2 MUSV/TVTR11. VolChB
13	保护C相电压Uc1 PISV01/SVINGGIO3. SAVSO5	C相保护测量电压1 MUSV01/UCTVTR1. Vol1	保护电压C相1 MUSV/TVTR12. Vol
14	保护C相电压Uc2 PISV01/SVINGGIO3. SAVSO6	C相保护电压2 MUSV01/UCTVTR1. Vol2	保护电压C相2 MUSV/TVTR12. VolChB
15	断路器位置 PIGO01/GOINGGIO1. DPCSO1.stVal	断路器位置 RPIT01/XCBR1. Pos.stVal	断路器位置 RPIT/Q0 XCBR1. Pos.stVal

序号	输入虚端子	自动连接的输出虚端子	样本匹配的输出虚端子
1	MU额定延时 PISV01/SVINGGIO1. DelayTRtg	额定延时 MUSV01/LLN0. DelayTRtg	额定延迟时间 MUSV/LLN0. DelayTRtg
2	保护A相电流Ia1(正) PISV01/SVINGGIO4. SAVSO1	A相保护电流1 MUSV01/PATCTR1. Amp1	保护1电流A相1 MUSV/TCTR1. Amp
3	保护A相电流Ia2(正) PISV01/SVINGGIO4. SAVSO2	A相保护电流2 MUSV01/PATCTR1. Amp2	保护1电流A相2 MUSV/TCTR1. AmpChB
4	保护B相电流Ib1(正) PISV01/SVINGGIO4. SAVSO3	B相保护电流1 MUSV01/PBTCTR1. Amp1	保护1电流B相1 MUSV/TCTR2. Amp
5	保护B相电流Ib2(正) PISV01/SVINGGIO4. SAVSO4	B相保护电流2 MUSV01/PBTCTR1. Amp2	保护1电流B相2 MUSV/TCTR2. AmpChB
6	保护C相电流Ic1(正) PISV01/SVINGGIO4. SAVSO5	C相保护电流1 MUSV01/PCTCTR1. Amp1	保护1电流C相1 MUSV/TCTR3. Amp
7	保护C相电流Ic2(正) PISV01/SVINGGIO4. SAVSO6	C相保护电流2 MUSV01/PCTCTR1. Amp2	保护1电流C相2 MUSV/TCTR3. AmpChB
8	闭锁重合闸 PIGO01/GOINGGIO1. SPCSO1.stVal	闭锁重合闸 RPIT01/GGIO1. Ind1.stVal	闭锁重合闸RPIT/ProtGGIO. Ind3.stVal
9	保护A相电压Ua1 PISV01/SVINGGIO3. SAVSO1	A相保护测量电压1 MUSV01/UATVTR1. Vol1	保护电压A相1 MUSV/TVTR10. Vol
10	保护A相电压Ua2 PISV01/SVINGGIO3. SAVSO2	A相保护电压2 MUSV01/UATVTR1. Vol2	保护电压A相2 MUSV/TVTR10. VolChB
11	保护B相电压Ub1 PISV01/SVINGGIO3. SAVSO3	B相保护测量电压1 MUSV01/UBTVTR1. Vol1	保护电压B相1 MUSV/TVTR11. Vol
12	保护B相电压Ub2 PISV01/SVINGGIO3. SAVSO4	B相保护电压2 MUSV01/UBTVTR1. Vol2	保护电压B相2 MUSV/TVTR11. VolChB
13	保护C相电压Uc1 PISV01/SVINGGIO3. SAVSO5	C相保护测量电压1 MUSV01/UCTVTR1. Vol1	保护电压C相1 MUSV/TVTR12. Vol
14	保护C相电压Uc2 PISV01/SVINGGIO3. SAVSO6	C相保护电压2 MUSV01/UCTVTR1. Vol2	保护电压C相2 MUSV/TVTR12. VolChB
15	断路器位置 PIGO01/GOINGGIO1. DPCSO1.stVal	断路器位置 RPIT01/XCBR1. Pos.stVal	断路器位置 RPIT/Q0 XCBR1. Pos.stVal

序号	输入虚端子	自动连接的输出虚端子	样本匹配的输出虚端子
1	MU额定延时 PISV01/SVINGGIO1. DelayTRtg	额定延时 MUSV01/LLN0. DelayTRtg	额定延迟时间 MUSV/LLN0. DelayTRtg
2	保护A相电流Ia1(正) PISV01/SVINGGIO4. SAVSO1	A相保护电流1 MUSV01/PATCTR1. Amp1	保护1电流A相1 MUSV/TCTR1. Amp
3	保护A相电流Ia2(正) PISV01/SVINGGIO4. SAVSO2	A相保护电流2 MUSV01/PATCTR1. Amp2	保护1电流A相2 MUSV/TCTR1. AmpChB
4	保护B相电流Ib1(正) PISV01/SVINGGIO4. SAVSO3	B相保护电流1 MUSV01/PBTCTR1. Amp1	保护1电流B相1 MUSV/TCTR2. Amp
5	保护B相电流Ib2(正) PISV01/SVINGGIO4. SAVSO4	B相保护电流2 MUSV01/PBTCTR1. Amp2	保护1电流B相2 MUSV/TCTR2. AmpChB
6	保护C相电流Ic1(正) PISV01/SVINGGIO4. SAVSO5	C相保护电流1 MUSV01/PCTCTR1. Amp1	保护1电流C相1 MUSV/TCTR3. Amp
7	保护C相电流Ic2(正) PISV01/SVINGGIO4. SAVSO6	C相保护电流2 MUSV01/PCTCTR1. Amp2	保护1电流C相2 MUSV/TCTR3. AmpChB
8	闭锁重合闸 PIGO01/GOINGGIO1. SPCSO1.stVal	断路器低气压闭锁 RPIT01/GOYxGGIO. Ind8.stVal	闭锁重合闸RPIT/ProtGGIO. Ind3.stVal
9	断路器位置 PIGO01/GOINGGIO1. DPCSO1.stVal	断路器位置 RPIT01/XCBR1. Pos.stVal	断路器位置 RPIT/Q0 XCBR1. Pos.stVal