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**Measurement and Simulation of Induced Voltage and Current on 110 KV Crossing Transmission Lines under UHV AC Transmission Lines** ()

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*Energy and Power Engineering*,

**9**, 635-643. doi: 10.4236/epe.2017.94B069.

1. Introduction

Ultra-high-voltage AC power transmission has outstanding advantages of high transmission capacity, long distance of power transmission, low line loss, small coverage, etc., which is an energy-saving and eco-friendly advanced power transmission technology. At present, China has three 1000 kV AC UHV projects completed in operation in total [1] [2]. As construction of UHV lines is underway, it is inevitable that power transmission lines in other voltage classes may parallel or cross with UHV lines in construction due to space limitation of power transmission corridor [3] [4] [5]. While high-voltage lines are running, electromagnetic fields may arise in space surrounding the lines. As a result, induced voltage and current may arise in nearby low-voltage lines, triggering potential safety threats in low-voltage line shutdown overhaul [6] [7] [8]. As UHV lines have high running voltage and transmission power, it is more necessary to focus on their induced power on low-voltage lines.

Domestic and foreign studies on UHV AC power transmission line induction are more concerned with parallel construction. In Literature [9] [10], computation and field measurement are made on induced voltage and current in 500kV one-tower two-circuit parallel line; in Literature [11] [12] [13], simulated computation and analysis are made on induced voltage and current in two-circuit UHV line with one line in power and one line in shutdown and 1000kV UHV and 500 kV/220 kV lines parallel with each other on the same tower respectively; in Literature [14] [15], computation is made on induction of UHV AC power transmission lines on low-voltage power distribution lines below. Concerning line crossing, in Literature [16] [17], methods of computation of power-fre- quency electromagnetic fields in crossing areas of AC power transmission lines are introduced; in Literature [18], theoretical computation is made on electrostatic induction of crossing and elongating conductors below 500 kV power transmission line. Few systematic domestic and foreign studies are concerning power transmission line crossing induction.

In this paper, field measurement is made on induced voltage and current of 110 kV crossing lines below UHV line in Jinhua, Zhejiang, simulated model is set up by CDEGS software to compute and analyze fluctuations in induced voltage and current of 110 kV lines under different transmission currents of UHV line, different crossing distances and crossing angles between UHV and 110 kV lines, precautions in shutdown overhaul of low-voltage lines under UHV line are presented, and reference basis is offered for layout design of crossing lines.

2. System Overview and Simulation Model

Put into operation at the end of 2014, Zhebei-Fuzhou 1000kV UHV AC Power Transmission Project is constructed in two circuits all the way. Line Jianglian I, Line Jianglian II and 110 kV Line Xianchi 1555 (construction in two circuits on the same tower) cross in Jinhua. Their crossing distance is 18.3 m and crossing angle is 60˚. Figure 1 shows layout of conductors and ground wires at the crossing location of two lines. G1 and A1-C1 refer to ground wire and three- phase conductor of Line Jianglian I; G2 and A2-C2 refer to ground wire and three-phase conductor of Line Jianglian II. Conductor 1-3 and Conductor 4 - 6 refer to Line Xianchi 1555 Circuit I and Line Xianchi 1555 Circuit II respective-

(a) (b)

Figure 1.Layout of conductors and ground wires at the crossing location. (a) Line Jianglian; (b) Line Xianchi 1555.

ly; 7 and 8 refer to ground wires. Parameters of conductors and ground wires of crossing lines are shown in Table 1.

The simulated model of induced power of crossing lines is set up in the HIFREQ module in the simulation software of CDEGS as shown in Figure 2. Since induction is weaker somewhere farther from the crossing point, 2 km is taken as line length in simulated modeling, the crossing point is located in the center of line and line is deemed as a straight line by omitting the angle of rotation of line at the tension support; while power-frequency voltage and current are inflicted on three-phase conductor of Line Jianglian in normal operation, induction is computed in shutdown of Line Xianchi 1555.

3. Measurement of Induced Voltage and Current of 110 KV Line

In order to study and master effects of UHV line on induced power of power transmission lines below, field measurement is made on 110 kV Line Xianchi 1555 in Jinhua as shown in Figure 3. In measurement, 110 kV line is in shutdown due to substation overhaul. In the state of test run, UHV line has lower load and its running load is as shown in Table 2.

In the measurement, three-phase conductors of Circuit I and Circuit II at the No.15 Support below the crossing point or Conductor 1 - 6 in Figure 1(b) are selected. Measured results are shown in Table 3.

1) Induced voltage of all phase conductors is measured before earthing switches on both ends of line are closed following substation shutdown;

2) After earthing switches on both ends of line are closed, induced voltage of all phase conductors is re-measured;

3) Temporary ground wires are attached to locations near both sides of a measuring point to measure induced current of temporary ground wires.

It is known by measured results that while earthing switches in the substation are not closed, higher electrostatic induced voltage arises on the 110 kV line and induced voltage of Conductor 1 that is the closest to UHV line attains as high as 12.24 kV; while earthing switches on both ends of substation are closed, induced voltage on the line is almost zero; due to lower running load of UHV line in

Figure 2. Simulated model.

Figure 3. Induced voltage and current of crossing lines in field measurement.

Table 1. Parameters of conductors and ground wires of crossing lines.

Table 2. UHV line load.

Table 3. Measured results of induced voltage and current.

measurement, after temporary ground wires are attached to both ends of the crossing point, the measured induced current flowing through the ground wires is very low as well, which is lower than 0.07A.

4. Simulated Computation and Analysis of Influence Factors

The maximum value in Table 2 is taken as load of UHV line to make simulated computation on results of induced voltage of all conductors and induced current of temporary ground wires as shown in Table 4.

It is known by table that results of simulated computation and field measurement are close to each other, proving the accuracy of simulated model. Different transmission currents of UHV line, crossing distances and crossing angles are taken to make simulated computation and analysis on induced voltage and current of 110 kV line.

4.1. Effects of Transmission Current of UHV Line

The maximum transmission capacity of the UHV line is 6000 MW in one circuit. However, since it is put into operation lately and experiences no peak of power consumption, it keeps running in a lower load. In order to ensure personal safety in shutdown overhaul of 110 kV line below, it is necessary to study induction in the state of high load. While UHV line is in the transmission powers of 2000 MW, 4000 MW and 6000 MW respectively, transmission current of each phase conductor is 1.15 kA, 2.31 kA and 3.46 kA respectively. Crossing distance of 18.3 m and crossing angle of 60˚ are taken to compute induced voltage and current of 110 kV line under different transmission currents as shown in Table 5.

While earthing switches in the substation are not closed, induced voltage of 110 kV line is generally electrostatic coupling component and electrostatic induction is irrelevant with transmission current. Therefore, induced voltage of conductors is almost unchanged; after earthing switches on both sides of station are closed, induced voltage of 110 kV line is generally electromagnetic coupling component and electromagnetic coupling voltage rises as transmission current rises in direct proportion and induced voltage is 12.3 V while UHV line is in

Table 4. Results of simulated computation on induced voltage and current.

Table 5. Computing results of UHV line under different transmission currents.

full-load operation; induced current flowing through temporary ground wires is very low, which is lower than 1A.

4.2. Effects of crossing Distance between 110 KV Line and UHV Line

Transmission current of 3.46 kA of each phase conductor and crossing angle of 60˚ are taken to compute induced voltage and current of 110 kV line under different crossing distances as shown in Table 6.

The farther UHV line is away from 110 kV line below, the lower electrostatic induced voltage and electromagnetic induced voltage of 110 kV line will be. As crossing distance rises from 20 m to 50 m, electrostatic induced voltage falls from 12.43 kV to 8.93 kV and electromagnetic induced voltage falls from 12.2 V to 11.0 V; induced current of temporary ground wires slightly declines as well.

4.3. Effects of crossing Angle between 110 KV Line and UHV Line

Transmission current of 3.46 kA of each phase conductor and crossing distance of 18.3 m are taken to compute induced voltage and current of 110 kV line under different crossing angles as shown in Table 7.

While crossing angle changes from 0˚ (parallel construction) to 90˚ (vertical crossing), induced voltage and current of 110 kV line show greater change. In parallel construction of two lines, electrostatic induced voltage attains 100.84 kV, electromagnetic induced voltage attains 358 V, and induced current of ground wires attains 16.3 A, much higher than those in the situation of line crossing. Even though crossing angle is only 30˚, electrostatic induced voltage falls 59.3%, electromagnetic inducted voltage and induced current of ground wires fall as much as 89.7% and 89.4% respectively.

Table 6. Computing results under different crossing distances.

Table 7. Computing results under different crossing angles.

5. Conclusions

While 1000 kV Line Jianglian is in liveoperation in Jinhua, Zhejiang, field measurement is made on induced voltage and current of conductors of 110 kV Line Xianchi 1555 that is 18.3 m below the above line and in a crossing angle of 60˚ with the above line. The electrostatic induced voltage attains 12.24 kV. Due to lower line load in measurement, the electromagnetic induced voltage is lower than 2V and induced current of ground wires is lower than 0.07A.

Results of simulated computation show that while UHV line is in full-load operation, electrostatic induced voltage is12.78 kV, electromagnetic induced voltage is 12.3 V and induced current is lower than 1 A in the 110 kV line below; as the crossing distance rises, the induced voltage and current gradually fall; while two lines are in parallel construction, the electrostatic induced voltage is 100.84 kV, electromagnetic induced voltage is 358 V and induced current of ground wires is 16.3A, much higher than those in the situation of line crossing. The higher the crossing angle is, the lower induced voltage and current will be.

Though induced voltage and current of the crossing line below the UHV line are lower than those in parallel construction, greater electrostatic induced voltage may arise. In shutdown overhaul, it is necessary to ensure that earthing switches on both sides of line in the substation are closed. While crossing angle of lines is lower than 30˚, electromagnetic induced voltage of lines will be higher than human safety voltage of 36 V after earthing switches are closed. Thus, in line overhaul, it is also necessary to attach temporary ground wires on both sides of a working point to ensure personal safety.

Conflicts of Interest

The authors declare no conflicts of interest.

[1] | Liu, Z.Y. (2013) Innovation of UHVAC Transmission Technology in China. Power System Technology, 37, T1-T8. |

[2] | Liu, Z.Y. (2013) UHVAC/DC Power Grid. China Electric Power Press, Beijing. |

[3] | Shu, Y.B. and Zhang, W.L. (2007) Research of Key Technologies for UHV Transmission. Proceedings of the CSEE, 27, 1-6. |

[4] | Xiao, D.P., Jiang, K.R., Zhang, Z.L., et al. (2015) Optimization Algorithm for Arranging Extra-and Ultra-High Voltage Transmission Lines Subjected to the Constraints of Power Fre-quency Electromagnetic Environment Condition. Proceedings of the CSEE, 35, 2333-2341. |

[5] | Hu, S.S., Li, J., Ma, L., et al. (2012) Ground Clearance and Crossing Clearance of ±1100 kV UHVDC Transmission Line. Electric Power Construction, 33, 25-28. |

[6] | Tanen, J.D. and Wilson, G.L. (1971) Electrostatically Induced Voltages and Currents on Conducting Objects under EHV Transmission Lines. IEEE Transactions on Power Apparatus and Systems, 90, 341-349. |

[7] | Lin, C., Chuang, H. and Chen, K. (1990) Steady-state and Shock Currents Induced by ELF Electric Fields in a Human Body and a Nearby Vehicle. IEEE Transactions on Electromagnetic Compatibility, 32, 59-65. https://doi.org/10.1109/15.45251 |

[8] | Wang, C.Y. (2010) The Reason and Protection Measurement of" Induced Electricity" inTransmission Lines Maintanence. Electrical Security Technology, 12, 6-12. |

[9] | Hu, D.H., Tu, C.Q., Jiang, W., et al. (2008) Calculation of Inductive Voltage and Current for 500 kv Double Circuits Transmission Lines on Single Tower. High Voltage Engineering, 34, 1927-1931. |

[10] | Guo, Z.H., Yao, J.X., Cheng, X.Q, et al. (2006) StudyandMeasure-mentofInducedVoltageandCurrentfor500kVDoublyCircuitLineonSameTower.HighVoltageEngineering, 32, 11-14,50. |

[11] | Li, B.J. and Zhou, H. (2011) Calculation and Analysis on Induced Voltage and Current of 1000 kV Transmission Line Adopting Structure of Double Circuit on the Same Tower. Power System Technology, 35, 14-19. |

[12] | Liu, H.J, Yan, G.Z., Wang, S.H, et al. (2015) Analysis of Electrostatic Induced Voltageon1000 kV Wannan-Zhebei UHVAC Transmission Line. High Voltage Engineering, 41, 1687-1693. |

[13] | Li, Z.Q., Liu, C.Q., Dai, M., et al. (2013) Induced Voltage and Induced Current on AC Same-Tower Four-Circuit Lines Comprised of Double-Circuit 1000 kV Lines and Double-circuit 500 kV or 220 kV Lines. High Voltage Engineering, 39, 3022-3028. |

[14] | He, Y.W., Liu, Y.K., Yan, N.N., et al. (2015) Evaluation of Induced Voltage and Current on Low-Voltage Distri-bution Lines under EHV/UHVAC and DC Transmission Lines. Power System Technology, 39, 2640-2646. |

[15] | Abdel-Salam, M. and Al-Shehri, A. (1994) Induced Voltages on Fence Wires and Pipelines by AC Power Transmission Lines. IEEE Transaction on Industry Applications, 30, 341-349. https://doi.org/10.1109/28.287525 |

[16] | Chen, N., Wen, X.S., Lan, L., et al. (2011) Accurate Calculation of Three- Dimensional Power Frequency Electromagnetic Field for Space Crossed Transmission Line. High Voltage Engineering, 37, 1752-1759. |

[17] | Wang, X.Y., Zhao, J.G., Wu, X., et al. (2011) Calculation Method of Electric Field Intensity for AC Crossing Transmission Lines. High Voltage Engineering, 37, 411-416. |

[18] | Shao, F.Y. (1983) Electrostatic Induced Voltage and Current of Elongation Shaped Conductors under 500 kV Transmission Lines. Electrical Technology, 5, 2-7. |

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