Unit 4-Field Oriented Control of Induction Motor
Transcript of Unit 4-Field Oriented Control of Induction Motor
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U.Shajith Ali / AP/ EEE / SSNCE
Field Oriented Control of
Induction Motor
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U.Shajith Ali / AP/ EEE / SSNCE
Vector versus Scalar Control of Induction Motors
• Scalar control involves controlling only the magnitude of the control
variables with no concern for the coupling effects between these variables.
Conversely, vector or field orientated control involves adjusting the
magnitude and phase alignment of the vector quantities of the motor.
• Scalar control, such as the Constant Volts/Hertz method when applied to an
AC induction motor is relatively simple to implement but gives a sluggish
response because of the inherent coupling effect due to torque and flux
being functions of current and frequency. Vector control de-couples the
vectors of field current and armature flux so that they may be controlled
independently to provide fast transient response.
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U.Shajith Ali / AP/ EEE / SSNCE
• Accurate position control is not possible with scalar control since this
requires instantaneous control of the torque. This requires either,
instantaneous change to the stator currents, which is not possible due to
energy storage effects, or instantaneous change to the rotor current which in
the case of scalar control is controlled indirectly via the stator currents.
Similarly, whilst scalar control may provide acceptable steady state speed
control, precise and responsive speed control due to load changes requires
accurate and responsive torque control.
• The vector approach overcomes the sluggish transient response when using
scalar control of AC motors.
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U.Shajith Ali / AP/ EEE / SSNCE
Field Orientated Control (FOC)Field Orientated Control (FOC)Field Orientated Control (FOC)Field Orientated Control (FOC)
• The Field Orientated Control consists of controlling the stator currents represented by a vector.
• This control is based on projections which transform a threephase time and speed dependent
system into a two co-ordinate (d and q co-ordinates) time invariant system.
• These projections lead to a structure similar to that of a DC machine control.
• Field orientated controlled machines need two constants as input references: the torque
component (aligned with the q co-ordinate) and the flux component (aligned with d co-ordinate).
• As Field Orientated Control is simply based on projections the control structure handles
instantaneous electrical quantities. This makes the control accurate in every working operation.
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U.Shajith Ali / AP/ EEE / SSNCE
Thus in Induction motor, FOC
• the ease of reaching constant reference
(torque component and flux component of
the stator current)
• the ease of applying direct torque control
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U.Shajith Ali / AP/ EEE / SSNCE
In implementation
• (the Clarke transformation) which outputs
a two co-ordinate time variant system
• (the Park transformation) which outputs a
two co-ordinate time invariant system
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U.Shajith Ali / AP/ EEE / SSNCE
Vector Control Implementation Principle
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U.Shajith Ali / AP/ EEE / SSNCE
Implementation of Vector Control
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Two methods of vector control
1. Direct or feedback method
2. Indirect or feedforward method
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U.Shajith Ali / AP/ EEE / SSNCE
Direct or Feedback Vector Method
• Direct vector control block diagram with rotor flux orientation
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U.Shajith Ali / AP/ EEE / SSNCE
Flux Vector Estimation
Two methods:
1.Voltage model
2.Current model
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Voltage Model
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The torque expression is
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U.Shajith Ali / AP/ EEE / SSNCE
Voltage model estimation
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Current ModelThe rotor circuit equations
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U.Shajith Ali / AP/ EEE / SSNCE
Therefore
But
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Indirect or Feedforward Control
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U.Shajith Ali / AP/ EEE / SSNCE
Derivations of indirect control
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U.Shajith Ali / AP/ EEE / SSNCE
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Block Diagram of Indirect Vector Control
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Direct Torque Control
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What is Direct Torque Control?What is Direct Torque Control?What is Direct Torque Control?What is Direct Torque Control?
• Direct Torque Control describes the way in which the control of torque and speed are directly based on the electromagnetic state of the motor, similar to a DC motor, but contrary to the way in which traditional PWM drives use input frequency and voltage. DTC is the first technology to control the “real” motor control variables of torque and flux.
Direct Torque and Flux Control (DTFC)
or
Direct Torque Control (DTC)
or
Direct Self Control (DSC)
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• Direct control of torque and stator flux of a
drive by inverter space vector selection
through a look up table.
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Control Strategy of DTC
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Advantages of DTC
• Fast torque response
• Torque control at low frequencies
• Torque linearity
• No feedback current control
• Do not need a tachometer or encoder
• No traditional PWM is applied