Your search keyword '"Pang, Wenlong"' showing total 2 results

1. Preliminary study on the structure design of 330 KV GIS with three phase in one tank

Author

Pang Wenlong, Cheng Shi-min, Wu Xixiu, and Wu Shipu

Subjects

internal GIS, Materials science, business.industry, probability, high-voltage power system, voltage 330.0 kV, General Engineering, design principle, Energy Engineering and Power Technology, Structural engineering, eddy effect, gas insulated switchgear, skin effect, weak insulation-level problem, Three-phase, lcsh:TA1-2040, energy consumption, Structure design, GIS structure design, tank, electromagnetic-temperature-flow multiphysical field coupling model, lcsh:Engineering (General). Civil engineering (General), business, Software

Abstract

This paper focus on the research about the probability and practicability of 330 kV GIS structure design with three phase in one tank， which represents the miniaturisation and compact developing trend of GIS. The design principle is proposed according to the volume of three phase in one tank (structure A) is generally smaller than that of the sum volume of three single phase (structure B). Then, the dimension size of 330 kV GIS with structure A is presented. To solve the weak insulation-level problem between phases of structure A, which prevents it from being used in high-voltage power system especially above 330 kV, an electromagnetic-temperature-flow multi-physical field coupling model considering eddy effect and skin effect is established to analyse the influencing factors on the insulation level of internal GIS. Therefore， the insulation level between the phases of structure A is calculated under the condition of power frequency and short circuit, respectively. The results show that the insulation margin of 330 kV GIS with structure A is enough and completely meet the insulation requirement of GIS. Furthermore, compared with structure B, structure A has lower temperature rise and energy consumption.

Published

2019

2. Study on the reliability of new kind of ±1 100 Kv DC voltage divider under the action of impulse voltage

Author

Wu Shipu, Wu Xixiu, Yang Zhining, Pang Wenlong, and Zhang Kejie

Subjects

Materials science, high-voltage engineering, bushings, Energy Engineering and Power Technology, power transmission reliability, internal bushing, Impulse (physics), HVDC voltage divider, HVDC power convertors, electric fields, cumulative effect, Dc voltage, DC transmission system, DC voltage divider, insulation demand, maximum resistance current, voltage field strength, business.industry, General Engineering, Electrical engineering, structure voltage divider, HVDC power transmission, maximum electric field strength, peak voltage, 3D transient electric field calculation model, voltage dividers, lcsh:TA1-2040, electric field strength distribution, equalisation voltage, lightning impulse test, impulse voltage, business, time 1.2 mus, lcsh:Engineering (General). Civil engineering (General), Software, Voltage

Abstract

To meet the special insulation demand of the DC transmission system with the highest voltage in the world, a new kind of ±1 100 kV DC voltage divider is designed. The reliability of the new structure voltage divider under the action of lightning impulse is studied. To achieve the voltage and electric field strength distribution of the voltage divider, a 3D transient electric field calculation model is established and a lightning impulse test for the prototype is carried out. The results reveal that (1)The voltage and electric field strength distributing on the voltage divider changing with time show a cumulative effect. (2)The maximum electric field strength occurs at the junction where the first grading ring connecting to the internal bushing. (3)The maximum current of resistance occurs at the peak voltage of lightning impulse with the corresponding time is 1.2 µs. (4)The voltage distributing on the capacitance imply that the capacitance really does play the role of equalisation voltage when the voltage divider suffering lightning impulse. (5)The prototype of HVDC voltage divider passing through the lightning impulse test successfully strongly demonstrates the correctness and reliability of the new structure ±1 100 kV voltage divider voltage.

Published

2019