Power Capacitors
Outline Definition Power capacitor applications Typical applications of: Series capacitors Shunt capacitors Capacitor Placement / Sizing Standards WEIHUA WANG 2
Definition Power System Capacitor is an assembly of dielectric Materials and Metal-electrodes in a container (casing), with terminals brought out, that is intended to introduce capacitance into an electric power circuit. [1] WEIHUA WANG 3
Fig.1 Power Capacitor in Service[2] WEIHUA WANG 4
Nature of the power capacitors The power capacitor can be considered to be a VAR-GEN (reactive power Source), since it actually supplies needed-magnetizing current requirements for inductive loads.[3] The fundamental function of power capacitor is to provide needed reactive power compensation. WEIHUA WANG 5
Motivations The first use of capacitors on power circuits was in 1920.[4] The initial motivation for power capacitor application was for power factor correction. Until present, Fixed- shunt capacitor banks for Power Factor Correction has been a well established approach. WEIHUA WANG 6
Motivations Power factor correction Feeder-Loss Reduction Release of System capacity Voltage- Stabilization/Regulation Efficient Power Utilization Power Quality Enhancement Power Harmonic Filtering WEIHUA WANG 7
Series Capacitors Series capacitors are used on transmission lines to compensate for inductive reactance/ Enhance Power Transfer. It is best to think of series capacitor as voltage regulator which regulate Series voltage (Boost/Buck) based on polarity and Bank Size.[5] Series capacitor can be used as a blocking filter for offending harmonics WEIHUA WANG 8
Series Capacitors For steady state Power Flow and transient state stability, the real power flow (P) over a transmission line is given by formula (1), where Es is the sending end voltage, ER is the receiving end voltage, X is the line reactance and β is the angle between Es and ER . WEIHUA WANG 9
Series Capacitors The power transfer can be increased considerably by the use of series capacitor banks. Series capacitors are suited practically to circuits where light flicker is encountered due to Dynamic load fluctuations, such as frequent inrush motor starting, electric welders and arc-furnaces. WEIHUA WANG 10
Shunt Capacitors[5] The shunt capacitors are used to supply a Capacitive type-Leading VAR reactive power to the AC Power system at the point of Connection, in order to: WEIHUA WANG 11
Shunt Capacitors[5] Reduce the lagging component of the circuit current Increase the voltage of the load bus Improve bus-voltage regulation and/or power factor Reduce Transmission losses Reduce Electricity Billing cost based on KVA Demand WEIHUA WANG 12
Switched-Type Capacitor A lot of dynamic/adaptive controller are used to switch or modulate Capacitor- Banks connected to the AC-systems. Schemes are employed to change the compensation Level/topologies of the Capacitor Banks based on Load-voltage and current variations / excursions or sudden system faults. WEIHUA WANG 13
Capacitor Placement The Capacitor Location or Placement for low voltage systems determines capacitor type, size, location and control schemes. Optimal capacitor placement is generally a hard combinatorial .optimization problem that can be formulated as a nonlinear/Search Minimization problem.[6] WEIHUA WANG 14
Capacitor Placement Almost all the methods to solve capacitor placement problems are based on the historical data of the load models and associated cost of the energy and the cost of capacitor banks. Cost $/Kvar for Power savings and Losses (Power losses/Energy losses) WEIHUA WANG 15
Capacitor Placement However, Historical Data and Load models are uncertain and may change in reality. To account for such load model and load pattern/cycles uncertainties Soft- Computing AI Based algorithms using fuzzy sets/Neural networks/Genetic Algorithm can be utilized.[7] WEIHUA WANG 16
Capacitor Placement In general, capacitor placement problems can be solved in two steps:[8] Use of load flow model and find the V,P,Q at all the buses and also the feeder losses Minimize the cost function-Jo-min - subject to constraints, like practical limits of voltage and capacitor size! WEIHUA WANG 17
Limitations and Cautions Resonance-Series or Shunt Type Capacitor inrush current transients caused by Capacitor Switching Capacitor Sinking harmonic currents Transient Recovery Voltage WEIHUA WANG 18
Resonance Resonance is a condition whereby the capacitive reactance of the AC-System, offsets its inductive reactance leaving only the resistive elements in the AC- Network as the only impedance. The resonant frequency can be calculated by as WEIHUA WANG 19
Resonance If the resonant frequency happens to coincide with one generated by an existing harmonic source, then the dangerous voltages and currents will increase disproportionately, causing damage to capacitors and other electrical equipments. [3] WEIHUA WANG 20
Capacitor Switching Transients Capacitor switching transient typically occurs when energizing a large capacitor on the high voltage side of the power system (the utility side) result in magnification/intensification of the transients at lower voltage capacitors. The magnified transient at lower voltage end can reach up to 400%. WEIHUA WANG 21
Standards There are two standards provide a basis for uniformity in design and testing of shunt power capacitors: IEEE Std. 18-2002 IEEE Standard for Shunt Power Capacitors IEEE Std. 824-1985 IEEE Standard for Series Capacitors in Power Systems WEIHUA WANG 22
Conclusion Power capacitor are very useful for power factor correction, loss reduction, voltage profile improvement and distribution system-capacity release/increase. Best location and sizing of the capacitor bank should be carefully selected. WEIHUA WANG 23
Reference [1] IEEE standards, IEEE Standard for Shunt Power Capacitor, IEEE Std. 18-2002 [2] http://www.abb.com [3] M.H.Shwehdi and M.R.Sultan, “Power Factor Correction Capacitors; Essentials and Cautions”, 2000 IEEE Power Engineering Society Summer Meeting, Vol.3, pp.1317-1322 [4] S.W.Cichanowaki and G.R. Newcomb, Power Capacitors, Electrical Electronics Insulation Conference, 1991. Boston '91 EEIC/ICWA Exposition, Prodeedings of the 20th WEIHUA WANG 24
Reference [5] Dr. G. Thomas Bellarmine, Optimum Series Compensated High Voltage Transmission Lines, Southeastcon '97 'Engineering New Century', Proceedings, IEEE 12-14 April 1997 P307-309 [6] Ramon A. Callego, Alcir Jose Monticelli and Ruben Romero, “Optimal Capacitor Placement in Radial Distribution Networks”, IEEE Transactions on power systems, Vol.16, No.4, November 2001 [7] H.N.Ng.M.M.A.Salama, “Fuzzy Optimal Capacitor Sizing and Placement”, Electrical and Computer Engineering, 1995. Canadian Conference on Vol.2, 5- 8 Sept. 1995 P680-683 WEIHUA WANG 25
Reference [8] A.M.Sharaf and S.T. Ibrahim, “Optimal capacitor placement in distribution networks”,1996 Electric Power System Research 37, 181-187 WEIHUA WANG 26