Title :
Maximum power delivery capability of a three-phase self-excited induction generator
Author_Institution :
Sch. of Eng., Univ. of South Australia, Mawson Lakes, SA, Australia
Abstract :
Self-excited induction generators (SEIG) are increasingly being used in remote areas to energize isolated communities. The maximum power delivery capability of a SEIG depends on various factors, such as excitation capacitance, generator parameters, operating speed and load power factor. This paper proposes a simple method of determining the maximum power that can be delivered by a three-phase SEIG for various operating conditions. The maximum power of the generator is carefully formulated as a multi-variable constrained optimization problem. The problem is then solved using a numerical based routine “fmincon” given in the optimization toolbox of MATLAB. The effectiveness of the proposed method is then evaluated on a 1.5-kW, 220-V induction machine operated as a SEIG. The simulation results obtained by the proposed method are also compared with the corresponding experimental values.
Keywords :
asynchronous generators; machine theory; optimisation; MATLAB toolbox; excitation capacitance; generator parameters; induction machine; load power factor; maximum power delivery capability; optimization problem; power 1.5 kW; three-phase SEIG; three-phase self-excited induction generator; voltage 220 V; Capacitance; Equations; Induction generators; Optimization; Reactive power; Steady-state; excitation capacitance; induction generator; maximum power; rural electrification; self-excited induction generator; stand-alone operation;
Conference_Titel :
Electrical and Computer Engineering (ICECE), 2014 International Conference on
Conference_Location :
Dhaka
Print_ISBN :
978-1-4799-4167-4
DOI :
10.1109/ICECE.2014.7026966
