Development of an Over-Temperature Supervising System of Switch Cabinet Based on Gas Sensing Technology
-
Jian Le
,
Qian Zhou
Abstract
Existing over-temperature supervising (OTS) systems available for switch cabinet, even those based on advanced optical fiber sensing technology, are unable to satisfy the critical requirements such as reliability, safety, practicability and economy simultaneously. In this paper, a novel OTS scheme that take a special kind of gas to carry the signal indicating the over-temperature state of a switch cabinet is developed elaborately. Serving for the CO2 gas which has comprehensive and overwhelming superiorities in situation of OTS, a gas storage unit that is composed of a hard plastic crust and an inner tubular airbag, a gas releasing mechanism that consists of bimetallic and acupuncture, and a gas sensing terminal are designed artfully. The overall OTS system is finally developed by integrating these three parts with a background server via wireless communication technology. The advantages of the proposed system, such as high reliability and safety, fast response speed and universal applicability have been proven by lab tests and field experiments. Moreover, the inherent low cost and easy installation and maintenance features of our scheme facilitate the development of OTS systems for other electrical devices in power system.
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Artikel in diesem Heft
- Prospectives for the Use of Li-Ion Batteries in Hybrid Stand-Alone Power Sources
- Development of an Over-Temperature Supervising System of Switch Cabinet Based on Gas Sensing Technology
- Robust Investment for Demand Response in a Distribution Network considering Wind Power and Load Demand Uncertainties
- Reduction of Electric Field Stress on the Surface Contour and at the Triple Junction in UHVAC GIS by Spacer Design Optimization
- Optimal Energy Scheduling Method under Load Shaping Demand Response Program in a Home Energy Management System
- Sequence Component-Based Improved Passive Islanding Detection Method for Distribution System with Distributed Generations
- Optimal Switching Angle Scheme for a Cascaded H Bridge Inverter using Pigeon Inspired Optimization
- A Novel System and Experimental Verification for Locating Partial Discharge in Gas Insulated Switchgears
- A Comprehensive Induction Machine Model for Multi-Phase Power Flow Studies – Application to Industrial Power Systems and Wind Farms
- A Simplified Indirect Technique for the Measurement of Mechanical Power in Three-Phase Asynchronous Motors
- Three-Phase Grid Connected Bi-Directional Charging System to Control Active and Reactive Power with Harmonic Compensation
