VECTOR CONTROL DRIVES OF PERMANENT MAGNET SYNCHRONOUS MOTOR

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Presentation transcript:

VECTOR CONTROL DRIVES OF PERMANENT MAGNET SYNCHRONOUS MOTOR A mini project report submitted in partial fulfillment of the requirement For the award of the degree of BACHELOR OF TECHNOLOGY IN ELECTRICAL & ELECTRONICS ENGINEERING Under the esteemed guidance of KAMAKHYA.PRASAD SAHU B.TECH., BY B.NAGAMANI 09RD1A0203 K.R.SEENAPRIYANKA 09RD1AO219 K.SWAPNA 09RD1A0223 DEPARTMENT OF ELECTRICAL AND ELECTRONICS ENGINEERING J.M.N.RAO WOMEN’S ENGINEERING COLLEGE Yenkapally, Moinabad Mandal, R.R District Affiliated to J.N.T.University, Hyderbad. 2012

AGENDA Objectives Introduction. Description of the Drive Systems. Modeling of PM Drive System. Implementation of vector controlled Permanent Magnet Synchronous Motor Drives in MATLAB/SIMULINK. Simulink Results. Advantages. Applications. Future Scope. Conclusion.

OBJECTIVE Nowadays, PMSM is designed not only to be more powerful but also with lower mass and lower moment of inertia. Due to its high power density and smaller size, PMSM has in recent years evolved as the preferred solution for speed and position control drives on machine tools and robots. In vector control drive, the highly accurate position from position sensor is required to transform the abc variables to the dq variable in the synchronously rotating reference frame aligned with the rotor flux linkage vector. It deals with the selection of the simulation tool for dynamic simulation of motor drives.

INTRODUCTION This feature is important to gain the maximum starting torque in such drive system. 1.1 Literature review: In 1986 Sebastian, T., Slemon, G. R. and Rahman, M. A. reviewed permanent magnet synchronous motor advancements and presented equivalent electric circuit models for such motors. In 1986 Jahns, T.M., Kliman, G.B. and Neumann, T.W. discussed that interior permanent magnet (IPM) synchronous motors. In 1988 Pillay and Krishnan, R. presented PM motor drives and classified them into two types such as PMSM and BDCM drives The paper in 1997 by Wijenayake, A.H. and Schmidt, P.B. described the development of a two-axis circuit model for PMSM by taking machine magnetic parameter variations and core loss into account. Bowen, C., Jihua, Z. and Zhang, R. in 2001 addressed the modeling and simulation of permanent magnet synchronous motor .

Description of the Drive System This deals with the description of the different components such as permanent magnet motors, position sensors, inverters and current controllers of the drive system.. Permanent Magnet Synchronous Motor Drive System: The motor drive consists of four main components, the PM motor, inverter, control unit and the position sensor. Permanent Magnet Synchronous Motor: A permanent magnet synchronous motor (PMSM) is a motor that uses permanent magnets to produce the air gap magnetic field rather than using electromagnets. These motors have significant advantages, attracting the interest of researchers and industry for use in many applications. Position Sensor: Operation of permanent magnet synchronous motors requires position sensors in the rotor shaft when operated without damper winding. The need of knowing the rotor position requires the development of devices for position measurement. There are four main devices for the measurement of position, the potentiometer, linear variable differential transformer, optical encoder and revolvers. Depending on the application and performance desired by the motor a position sensor with the required accuracy can be selected

Permanent Magnet Synchronous Motor Drive System

MODELING OF PM DRIVE SYSTEM This deals with the detailed modeling of a permanent magnet synchronous motor. Field oriented control of the motor in constant torque and flux- weakening regions are discussed. Detailed Modeling of PMSM: Detailed modeling of PM motor drive system is required for proper simulation of the system. The d-q model has been developed on rotor reference frame. At any time t, the rotating rotor d-axis makes and angle θr with the fixed stator phase axis and rotating stator mmf makes an angle α with the rotor d-axis. Stator mmf rotates at the same speed as that of the rotor.  The model of PMSM without damper winding has been developed on rotor reference frame using the following assumptions: 1) Saturation is neglected. 2) The induced EMF is sinusoidal. 3) Eddy currents and hysteresis losses are negligible. 4) There are no field current dynamics.

Motor Axis

IMPLIMENTATION OF VECTOR CONTROLED PERMANENT MAGNET SYNCHORONOUS MOTOR DRIVE IN MATLAB/SIMULINK This describes different tools available for electrical and electronic systems simulation and then justification is given for selecting Simulink for the PMSM system. Block by block an explanation is given for Simulink simulation of the drive system.

Variables Description ias = Phase-a stator current ibs = Phase-b stator current ias = Stationary a-axis stator current ibs = Stationary b-axis stator current ids = Synchronously rotating d-axis stator current iqs = Synchronously rotating q-axis stator current vas = Stationary a-axis stator voltage vbs = Stationary b-axis stator voltage vds = Synchronously rotating d-axis stator voltage vqs = Synchronously rotating q-axis stator voltage vdc = DC-bus voltage qlr = Rotor flux angle qm = Mechanical angle dir = Rotor direction wr = Rotor speed Ta = Phase-a duty cycle ratio of PWM signal Tb = Phase-b duty cycle ratio of PWM signal Tc = Phase-c duty cycle ratio of PWM signal

vector control of pmsm drive

SIMULATION RESULTS

TORQUE WAVE-FORM

CURRENT WAVE-FORMS

ROTOR ANGLE(rad)

ADVANTAGES The PMSM also has advantages when compared to an AC induction motor. PMSM generate the rotor magnetic flux with rotor magnets, so achieve higher efficiency. Compared with a DC motor, the PMSM misses a commutator and so it is more reliable than the DC motor

APPLICATIONS PMSMs are very popular in a wide array of applications. Therefore PMSM are used in Electric and Hybrid vehicles, Refrigerators, Washing machines, Dishwashers, High-end pumps, Fans and in other appliances, which require high reliability and efficiency.

FUTURE SCOPE Detailed modeling and simulation of other types of synchronous motor drives can also be taken up for transient and steady state analysis.

CONCULSION In this paper, the proposed resolver algorithm has been verified in the current controlled drive system of PMSM. Both simulation and experimental results are presented. According to thus results, the resolver algorithm can force the angle error to zero. Thus, the computed angle can eventually match with the actual rotor angle. Then, the correct rotor speed computation is guaranteed. In the future works, this algorithm will be extensively tested in the speed controlled drive system of PMSM.

THANK YOU…..!