Review of Solid State Transfer Switch on Requirements, Standards, Topologies, Control, and Switching Mechanisms: Issues and Challenges

Mohammad Faisal,Mahammad Abdul Hannan,Muhamad Safwan Bin Abd Rahman,Pin Jern Ker,Mohammad Sazib Mollik,Muhamad Bin Mansur

doi:10.3390/electronics9091396

Mohammad Faisal, Mahammad Abdul Hannan + Show 4 more

Open Access

https://doi.org/10.3390/electronics9091396

Copy DOI

Journal: Electronics	Publication Date: Aug 28, 2020
Citations: 9	License type: CC BY 4.0

Affiliation: Universiti Tenaga Nasional

Abstract

Large-scale industrial loads, sensitive loads, and electrical power distribution systems suffer from power quality issues such as voltage interruptions, flickering, and sags which can cause a significant financial loss. The semiconductor based solid-state transfer switch (SSTS) can utilize the dual power feeders to protect the loads against these power disturbance issues. Conventional SSTS often requires more than quarter cycles to complete the transfer process because of load dependent commutation. Numerous researchers proposed the improved SSTS with impulse commutated circuit, which can reduce the transfer time and provide better ride-through capability against voltage sags. However, the SSTS specification depends on the application types and design procedure. Recently, hybrid SSTS has been introduced by the researchers to overcome all these issues. It has been investigated that not much papers are available in literature so far to aggregate all these issues. Therefore, towards the novel contribution of research, this review critically described the requirements, standards, and specifications of SSTS; control and switching mechanisms; and application of SSTS as single or hybrid topology, to give a comprehensive idea to the future researchers about the design of SSTS for a specific application. This paper also contributes to analyzing the key issues related to the SSTS applications, which can provide an easy control strategy and reduce the transfer time significantly. Overall, this research will strengthen the efforts of the researchers and industrialists to select, develop, and design the appropriate SSTS for a particular application.

Highlights

Transfer time of traditional mechanical switches to switch the fault power to the alternate power during interruption approximately ranges between 6 to 36 cycles
This paper gives a comprehensive idea for solid-state transfer switch (SSTS) design requirements, standards, and available specifications towards achieving the goal of mitigating the power quality issues, reducing the transfer time and losses
Available control strategies and switching mechanisms have been discussed in this paper

Summary

Introduction

Transfer time of traditional mechanical switches to switch the fault power to the alternate power during interruption approximately ranges between 6 to 36 cycles. These switches are applied in most of the medium and high voltage applications previously. If the heat does not release in time, they may damage the semiconductor devices. They need to be equipped with a large capacity cooling system [2]. ATS is advantageous in improving the power quality and reliability through voltage sag and power interruption minimization.

Methods

Results

Conclusion