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SIMULATION OF UPFC USING MATLAB. BY D.V.S.N.RAJU(05-272) M.SURESH KUMAR(06-208) D.J.SAI KRISHNA(05-275) J.P.NAIK(06-206) UNDER THE GUIDANCE OF B.DASU . Contents. Objective of the project FACTS devices Introduction to upfc Circuit Description Control schemes Present status.
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SIMULATION OF UPFC USING MATLAB BY D.V.S.N.RAJU(05-272) M.SURESH KUMAR(06-208) D.J.SAI KRISHNA(05-275) J.P.NAIK(06-206) UNDER THE GUIDANCE OF B.DASU
Contents • Objective of the project • FACTS devices • Introduction to upfc • Circuit Description • Control schemes • Present status
OBJECTIVE: • The aim of the project is to model UPFC and its control circuit using SIMULINK and to analyse the control circuit for effective power flow control using three different control schemes – 1. phase angle control 2. cross coupling control 3. generalized control. • After modeling UPFC, a single machine connected to a transmission line along with UPFC has been considered to study its performance. • It is the study of Unified Power Flow Controller and its role in damping power oscillations to improve system performance.
BENEFITS OF FACTS: In general FACTS devices possess the following technological attributes: • Regulation of power flows in prescribed transmission routes. • Reduces the need for construction of new transmission lines, capacitors and reactors. • Provides greater ability to transfer power between controlled areas, so that the generation reserve margin, typically 18 percent, may be reduced to 15 percent or less. These devices help to damp the power oscillations that could damage the equipment.
Improves the transient stability of the system. • Controls real and reactive power flow in the line independently. • Damping of oscillations which can threaten security or limit the usable line capacity.
FACTS Devices: Name Type Main function Controller SVC shunt voltage control Thyristor TCSC series power flow control Thyristor TCPAR series & power flow control Thyristor shunt STATCOM shunt Voltage control GTO SSSC series power flow control GTO UPFC shunt & voltage and power GTO series flow control
INTRODUCTION TO UPFC: • The UPFC is a device which can control simultaneously all three parameters of line power flow • Such "new" FACTS device combines together the features of two "old" FACTS devices: 1. STATCOM 2. SSSC. • These two devices are two Voltage Source Inverters (VSI’s) connected respectively in shunt with the transmission line through a shunt transformer and in series with the transmission line through a series transformer, connected to each other by a common dc link including a storage capacitor.
The shunt inverter is used for voltage regulation at the point of connection injecting an opportune reactive power flow into the line and to balance the real power flow exchanged between the series inverter and the transmission line. • The series inverter can be used to control the real and reactive line power flow inserting an opportune voltage with controllable magnitude and phase in series with the transmission line.
CIRCUIT DESCRIPTION: • The basic configuration of a UPFC, which is installed between the sending-end Vs and the receiving-end VR. The UPFC consists of a combination of a series device and a shunt device, the dc terminals of which are connected to a common dc link capacitor . Basic configuration of UPFC
FUNCTIONAL CONTROL OF SHUNT INVERTER • The shunt inverter is operating in such a way to inject a controllable current Ic into the transmission line. • This current consist of two components with respect to the line voltage: 1. the real or direct component id 2. reactive or quadrature component iq • The direct component is automatically determined by the requirement to balance the real power of the series inverter. The quadrature component, instead, can be independently set to any desired reference level (inductive or capacitive) within the capability of the inverter, to absorb or generate respectively reactive power from the line. So, two control modes are possible: • VAR control mode: the reference input is an inductive or capacitive var request; • Automatic Voltage Control mode: the goal is to maintain the transmission line voltage at the connection point to a reference value.
FUNCTIONAL CONTROL OF SERIES INVERTER • The series inverter injects a voltage, Vse which is controllable in amplitude and phase angle in series with the transmission line. This series voltage can be determined in different ways: • Direct Voltage Injection mode: The reference inputs are directly the magnitude and phase angle of the series voltage; • Phase Angle Shifter Emulation mode: The reference input is phase displacement between the sending end voltage and the receiving end voltage; • Line impedance emulation mode: The reference input is an impedance value to insert in series with the line impedance; • Automatic Power flow Control mode: The reference inputs are values of P and Q to maintain on the transmission line despite system changes.
OPERATING PRINCIPLE OF UPFC Single phase equivalent circuit
(a) Active power control (b) Reactive power control Phasor diagrams in case of active and reactive power
Control schemes: PHASE-ANGLE CONTROL : • Adjusting the amplitude of the 90" leading or lagging output voltage makes it possible to control active power . • The d-q frame coordinates based on space vectors, the d-axis current id corresponds to active power, and so it can be controlled by the q-axis voltage Vcq. Therefore, the reference voltage vector for the series device is given by ……….. for the series device is given by ………..
CROSS-COUPLING CONTROL : • The "cross-coupling control" has not only an active power feedback loop but also a reactive power feedback loop. • This control scheme is characterized by controlling both the magnitude and the phase angle
GENERALIZED CONTROL SCHEME This "generalized control scheme." The reference voltage vector for the series device, is generalized, as follows A voltage vector produced by the two terms is in phase with the current error vector i*-i. This means that the UPFC acts as a damping resistor against power swings.
CONCLUSION • Conventional power feedback control schemes make the UPFC induce power swings in transient states. • The time constant of damping is independent of the active and reactive power feedback gains Kp and Kq. Therefore, the conventional control schemes based on only the power feedback loops are not capable of damping of power swings. • The feedback gain Kr with a physical meaning of resistor is effective in damping of power swings. • The proposed control scheme achieves quick response of active and reactive power without causing power swings and producing steady state errors.