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用于中压配电网电压和电流测量的光纤供电LPIT

Power-over-Fiber LPIT for Voltage and Current Measurements in the Medium Voltage Distribution Networks.

作者信息

Bassan Fabio R, Rosolem Joao B, Floridia Claudio, Aires Bruno N, Peres Rodrigo, Aprea Javier F, Nascimento Carlos Alexandre M, Fruett Fabiano

机构信息

CPQD Research and Development Center in Telecommunications, Campinas 13086-902, Brazil.

IMS Power Quality, Porto Alegre 91160-310, Brazil.

出版信息

Sensors (Basel). 2021 Jan 14;21(2):547. doi: 10.3390/s21020547.

DOI:10.3390/s21020547
PMID:33466683
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7828781/
Abstract

In this work, we present the design, laboratory tests, and the field trial results of a power-over-fiber (PoF) low power instrument transformer (LPIT) for voltage and current measurements in the medium voltage distribution networks. The new proposed design of this power-over-fiber LPIT aims to overcome the drawbacks presented by the previous technologies, such as the continuous operation (measuring and data transmission) for a wide current range conducted in the medium voltage transmission lines, damage due to lightning strikes, accuracy dependency on vibration, position and temperatures. The LPIT attends the accuracy criteria of IEC 61869-10 and IEC 61869-11 in terms of current and voltage accuracy and it attends the practical criteria adopted by Utilities companies including voltage measurements without removing the coating of the covered conductors. The PoF based LPIT was developed to be applied at 11.9 kV, 13.8 kV, and 23.0 kV phase-to-phase nominal voltages, and in two current ranges 1.25-30 A and 37.5-900 A. The digital data transmission of current, voltage, and temperature from the sensing unit to the processing unit uses a special synchronism technique and it is performed by two 62.5 µm multimode fibers in 850 nm. The optical powering in 976 nm is also performed by one 62.5 µm multimode fiber from the processing unit to the sensor unit. We presented all details of the sensor design and its laboratory characterization in terms of accuracy and temperature correction. We also presented the results of field tests of the sensor made in two different conditions: in a standard distribution network and an experimental hybrid fiber/power distribution network. We believe that these studies aim to incorporate optical fiber and devices, digital technologies, communications systems in electrical systems driving their evolution.

摘要

在这项工作中,我们展示了一种用于中压配电网电压和电流测量的光纤供电(PoF)低功率仪表变压器(LPIT)的设计、实验室测试和现场试验结果。这种新提出的光纤供电LPIT设计旨在克服先前技术存在的缺点,例如在中压输电线路中针对宽电流范围进行的连续运行(测量和数据传输)、雷击造成的损坏、精度对振动、位置和温度的依赖性。LPIT在电流和电压精度方面符合IEC 61869-10和IEC 61869-11的精度标准,并且符合公用事业公司采用的实际标准,包括在不拆除被覆导体涂层的情况下进行电压测量。基于PoF的LPIT开发用于11.9 kV、13.8 kV和23.0 kV的相间标称电压,以及两个电流范围1.25 - 30 A和37.5 - 900 A。从传感单元到处理单元的电流、电压和温度的数字数据传输采用一种特殊的同步技术,由两根62.5 µm多模光纤在850 nm波长下进行。976 nm的光供电也由一根62.5 µm多模光纤从处理单元传输到传感器单元。我们展示了传感器设计的所有细节及其在精度和温度校正方面的实验室特性。我们还展示了在两种不同条件下进行的传感器现场测试结果:在标准配电网和实验性混合光纤/电力配电网中。我们相信这些研究旨在将光纤和设备、数字技术、通信系统纳入电气系统,推动其发展。

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3
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Sensors (Basel). 2021 Feb 25;21(5):1615. doi: 10.3390/s21051615.
IEEE Sens J. 2017;17(23). doi: 10.1109/JSEN.2017.2729893.
4
A current sensor based on the giant magnetoresistance effect: design and potential smart grid applications.基于巨磁电阻效应的电流传感器:设计及在智能电网中的潜在应用。
Sensors (Basel). 2012 Nov 9;12(11):15520-41. doi: 10.3390/s121115520.