Abstract
In this paper, the Routh criterion has been used to analyze the stability of a self-excited induction generator-based isolated system which is regarded as an autonomous system. Special focus has been given to the load capacity of the self-excited induction generator. The state matrix of self-excited induction generators with resistor-inductor load has been established based on transient equivalent circuits in the stator stationary reference-frame. The recursive Routh table of self-excited induction generators is established by the characteristic polynomial coefficients of the state matrix. According to the Routh stability criterion, the necessary and sufficient condition to predict the critical loads of self-excited induction generators is deduced, from which the critical load impedance can be calculated. A simple self-excited induction generator-based isolated power system has been built up with a 2.2 kW self-excited induction generator. The theoretical analysis and experiments were all carried out based on this platform. In the range determined by the minimum excitation capacitance (Cmin) and the maximum excitation capacitance (Cmax), the critical loads under various power factors have been calculated. The agreement of the calculated theoretical results and experimental results demonstrate the effectiveness and accuracy of the proposed analysis method. The conclusions achieved lay a foundation for further application of Routh stability criterion in self-excited induction generator-based power systems analysis.
Highlights
Self-excited induction generators have been widely used in renewable energy systems, such as wind power generation [1,2,3,4,5], as well as in isolated power systems, such as ships, aircrafts, and drilling platforms [6,7,8,9], due to their advantages of simplicity, robustness, low-cost, high reliability, no external excitation, and convenient maintenance
This paper investigates the load capacity of self-excited induction generators
The self-excited induction generator-based isolated power system is regarded as voltage a linear dropsnon-time-varying to a lower value and the self-excited induction generator continues operating steadily
Summary
Self-excited induction generators have been widely used in renewable energy systems, such as wind power generation [1,2,3,4,5], as well as in isolated power systems, such as ships, aircrafts, and drilling platforms [6,7,8,9], due to their advantages of simplicity, robustness, low-cost, high reliability, no external excitation, and convenient maintenance. An isolated self-excited induction generator-static synchronous compensator system feeding dynamic and static loads was analyzed in [24]. The analysis of the critical load of self-excited induction generators should be paid more attention to for its effect on voltage control. In this paper, based on the transient equivalent circuits, the Routh criterion is used to analyze the load capacity of self-excited induction generators. The focus of this paper is on the feasibility of using the Routh criterion to analyze the self-excited induction generator-based isolated power system. The main contribution of this paper is the establishment of the model of self-excited induction generators for stability analysis using the Routh criterion. The feasibility of applying the Routh criterion to stability analysis of self-excited induction generators is verified by the analysis of load capacity.
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