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Application of energy function to assess the first-swing stability of a power system with a SVC

Application of energy function to assess the first-swing stability of a power system with a SVC

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The transient energy function method is usually used to assess the stability of a power system without considering the effect of control devices. A modification of the method is proposed to determine the first-swing stability limit of a power system in the presence of a static VAR compensator (SVC). The effect of the SVC is carefully incorporated in determining the value of critical energy needed for system separation. The unstable equilibrium point at which the critical energy is to be evaluated is determined by considering that the SVC operates at its full capacitive rating. A recent control strategy of SVC proposed to maximise the first-swing stability limit can justify the use of such an unstable equilibrium point. The above technique of determining the first-swing stability limit of a power system in the presence of a SVC is tested on both single- and multimachine systems. The results obtained by the proposed technique are also compared with the corresponding actual values found through repetitive time-domain simulations of system dynamic equations.

Inspec keywords: power system control; power system dynamic stability; power system transient stability; time-domain analysis; static VAr compensators

Other keywords: single-multimachine systems; power system stability; transient energy function method; control devices; power system swing stability; time-domain simulations; control strategy; SVC; static VAR compensator; system dynamic equations; unstable equilibrium point

Subjects: Power system control; Other power apparatus and electric machines; Control of electric power systems; Stability in control theory; Mathematical analysis; Mathematical analysis

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