Download - Sensor Less Control of Pmsm Motor
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SIMULATION OF SENSORLESS CONTROL OF PERMANENT MAGNET SYNCHORONOUS
MOTOR
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Sensor less drives In Sensor less drives the speed and position is
obtained by monitored voltage/current and by utilizing mathematical models or artificial intelligence based systems.
The performance of the sensor less drives is based on the torque control capabilities and also on the speed estimation accuracy and bandwidth.
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MAIN TECHNIQUES OF SENSORLESS CONTROL OF PMSM
Open loop estimator using monitored stator voltage/current
Estimator using spatial saturation stator phase third harmonic voltage.
Model reference adaptive system Observers Artificial intelligence Back emf based position estimators
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Vector control The three phase stator currents are measured.
These measurement provides Ia and Ib . Ic can be calculated from the following relationship
Ia +Ib+Ic=0. The three phase current is then converted
into two axis system. The conversion provides the variables Iα and Iβ.
The two axis coordinate system is rotated to align with the rotor flux using a transformation angle calculated at the last iteration of the control loop. this conversion provides the Id and Iq from Iα and Iβ.
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Vector control Error signals are formed using Id, Iq and
reference values for each. The error signal is then provided to PI
controller. The output of the controller provide Vd and Vq which is a voltage vector that will be sent to the motor .
A new transformation angle is estimated where Vα,Vβ,Iα and Iβ are the inputs. the new angle guides the FOC algorithm as to where to place the next voltage vector.
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Vector control The Vd and Vq output values from the PI
controller are rotated back to the stationary reference frame using the new angle. This provides the next quadrature voltage values Vα and Vβ.
The Vα and Vβ values are transformed back to 3 phase values Va Vb and Vc. The 3 phase voltage values are used to calculate the new PWM duty cycle values that generate the desired voltage vector
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Vector control block diagram
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Clarke transformation
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Park transformation
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PI controller
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Inverse park transformation
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Inverse Clarke transformation
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Parameters to be estimated Three phase current Ia, Ib,Ic Position θ Speed ω
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Position and speed estimation methodI) Model based estimators
a) state observersb)back EMF methodc)flux linkage methods
II) Signal injection methoda)high frequency signal injectionb)low frequency signal injection
III) Phase loop lock technique
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References DISADVANTAGE OF MODEL BASED ESTIMATOR
At zero speed the current ,voltage and back emf are zero, so this method is not suitable at low speeds.
DISADVANTAGE OF SIGNAL INJECTION TECHNIQUE Ripples at high speed When Saliency ratio close to unity error
signal is too small
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PHASE LOCKED LOOP Combination of both back emf
method and high frequency injection technique.
At low speed high frequency injection technique is used and switched to back emf method at high speed.
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REFERENCES Sensor less vector control of interior
permanent magnet synchronous motor drives at very low speed without signal injection,” IET ELECTRICAL APPLICATIONS 2009”.
Simple rotor position estimation using the current saturation at a standstill.
An improved back-EMF based initial rotor position estimation for IPMSM ,”ECCE Asia 2011”.
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DANKEDANKE