Study on Installation of Neutral Ground Resistance in Very Small Power Plant Transformer

2022 IEEE Industry Applications Society Annual Meeting (IAS) Pub Date : 2022-10-09 DOI:10.1109/IAS54023.2022.9939721

P. Chiradeja, C. Pothisarn, Panu Srisuksai, Suntiti Yoomak, A. Ngaopitakkul, Natthanon Phannil

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Abstract

Faults in the distribution system of the Thai electrical system occur frequently. Such faults directly affect the protective equipment of the distribution system. The protective device disconnects the circuit unnecessarily on many occasions because it detects a higher current than expected. In this study, a 22-kV distribution system and a very small power plant (VSPP) were connected. The system consists of two feeders. Feeder 1 supplies electricity directly to the load; a fault was enforced in this feeder. Feeder 2 supplies electricity directly to the load; the VSPP was connected to this feeder. The fault in Feeder 1 was simulated, and the behavior of the defense system was studied. Unnecessary disconnection of the VSPP circuit took place because the high fault current caused the overcurrent protection relay to operate instantaneously. Therefore, a neutral ground resistance was installed at the VSPP transformer to reduce the fault current, extend the relay operating time to the delay range, and reduce unnecessary disconnections of the overcurrent protection relay of the VSPP. In addition, when a fault occurs in the distribution system, the faulted phase voltage decreases, whereas the non-faulted phase voltage increases. Surge arresters and voltage transformers must be able to withstand an increase in voltage. This is also explained and discussed in this paper.

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小型发电厂变压器中性点接地电阻的安装研究

泰国电力系统配电系统故障频繁。此类故障直接影响配电系统的保护设备。在许多情况下，保护装置会因为检测到比预期更高的电流而不必要地断开电路。在本研究中，连接了一个22kv配电系统和一个非常小的发电厂(VSPP)。该系统由两条馈线组成。馈线1直接向负载供电;这台馈线出现了故障。馈线2直接向负载供电;VSPP连接到这个馈线。对馈线1的故障进行了仿真，研究了防御系统的行为。由于故障电流过大导致过流保护继电器瞬间动作，导致VSPP电路不必要的断开。因此，在VSPP变压器处安装中性点接地电阻，以减小故障电流，将继电器动作时间延长到延时范围，减少VSPP过流保护继电器不必要的断开。此外，当配电系统发生故障时，故障相电压降低，而非故障相电压升高。避雷器和电压互感器必须能够承受电压的升高。本文也对此进行了说明和讨论。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 IEEE Industry Applications Society Annual Meeting (IAS)

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