Optimal location of tcsc due to power loss reduction and static voltage stability improvement using genetic algorithm shadmesgaran m. R., Hashimov a. M., Yusifbeyli n. A
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1. INTRODUCTION
The main duty of power systems is energy supply. Supplying demand and power system stability with the minimum cost needs services which are named side services. Of these services it is possible to name supplying reactive power needed for network. On the other hand, maintaining security of network with developing the network and increasing power transactions is one of the serious problems for system operator. Supplying reactive power needed for network is one of the services which impose some costs to system. Reactive power is considered as side services of electricity network which plays an important role in stability of electricity supply and in reduction of network costs. Supplying reactive power and common problems of transmission systems which cause improper exploitation alongside with low efficiency and high cost of available and traditional compensators lead to new generation compensators based on electronic devices of power in the late 70s.These devices were named FACTS devices due to flexibility they give to ac transmission system. These devices could be effective in changing flow active and reactive power of the lines by controlling amount and angle of voltage of busses and impedance of the lines. Of these devices it is possible to mention to cases below: These advantages alongside with desired performance, high reliability, high flexibility, proper cost and economical saving, has caused rapid spread of these devices around the world. By developing technology, a new generation of these devices was provided which showed a better performance comparing with previous generations and became competitor- less compensators of transmission and distribution networks [1]. References [2-9] show samples of installing these devices in electricity networks of the world. Various articles on voltage static stability and reducing loss have been provided which will be mentioned below. References [10] and [11] have involved with finding weak busses of network using medal analysis. Results of these articles have shown that medal analysis has provided acceptable performance determining weak busses of network. Reference [12] has involved with evaluating network voltage stability of Khuzestan using continuation demand distribution and medal analysis. This evaluation has been investigated in two conditions of normal and occurrence of event in demand peak condition in summer 2007. Finally weak busses of network have been identified in terms of voltage collapse. Reference [13] has provided a new possible approach for finding optimal capacity of FACTS devices to improve voltage stability of a power network. In this article uncertainties related to demand of system and generator planning, have been considered. Two scenarios have been considered in this article for installing FACTS devices and finally article has solved the problem using Monte Carlo simulation and bisection algorithm. Reference [14] also deals with increase in power system voltage static stability using FACTS devices. In this reference using continuation demand distribution, a comparison has been made between TCSC and STATCOM. Results show that STATCOM has had better performance than TCSC. Reference [15] has studied the issue of finding TCSC optimal place and adjustments in power system. In this reference reduction of loss in transmission lines has been addressed using evolutionary algorithms. This reference has used one of the newest evolutionary algorithms known as differential-evolutionary algorithm to solve the problem. Simulations of reference [15] have been conducted on IEEE standard 14-bus network. Reference [16] addressed performance of another device in loss reduction. This article has studied performance of APLC in reducing loss of distribution network. APLC is a combination of series and parallel convertors which could have an effective and determining role in reducing losses. In this reference PSCAD software has been used in order to conduct simulations. Mentioned equipping has also been effective on reducing harmonics as well as reducing costs. Reference [17] has introduced differential particles cumulative optimization algorithm in order to distribute optimal reactive power for reducing losses and preventing voltage instability. This reference has dealt with optimum control of reactive power in the network using differential particles cumulative optimization algorithm and has succeeded to minimize loss amounts in system. In this article standard 30-bus network has been used for running simulations. In reference [18] the subject of optimal allocation of sources for distribution reactive power for reducing losses has been studied and investigated considering constraints of network. Of reactive power sources used in this article are wind farms with double-fed induction generators. In order to run simulations, IEEE standard 30-bus network has been used in this reference. In this article we are dealing with simultaneously improving voltage static stability and reducing power losses in normal and emergency conditions of network by finding location and optimum capacity of TCSC.
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