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Permanent Magnet Synchronous Motor Control

Beyond Bits Motor Control Edition Permanent Magnet Synchronous Motor Control High-performance and power-efficient Motor Control Introduction Figure 1: Field-Oriented Control Vector Explanation Permanent Magnet Synchronous motors (PMSM) are typically used for The d axis refers Axis of phase B to the direct axis high-performance and high-efficiency of the rotor flux Motor drives. High-performance Motor The q axis is the axis of Rotor position Control is characterized by smooth Motor torque along against phase A. which the stator field (measured by rotation over the entire speed range must be developed position sensor).

Permanent magnet synchronous motors (PMS) are typically used for high-performance and high-efficiency motor drives. High-performance motor control is characterized by smooth rotation over the entire speed range of the motor, full torque control at zero speed, and fast acceleration and deceleration.

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  Control, Torque, Permanent, Synchronous, Magnet, Permanent magnet synchronous, Torque control

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Transcription of Permanent Magnet Synchronous Motor Control

1 Beyond Bits Motor Control Edition Permanent Magnet Synchronous Motor Control High-performance and power-efficient Motor Control Introduction Figure 1: Field-Oriented Control Vector Explanation Permanent Magnet Synchronous motors (PMSM) are typically used for The d axis refers Axis of phase B to the direct axis high-performance and high-efficiency of the rotor flux Motor drives. High-performance Motor The q axis is the axis of Rotor position Control is characterized by smooth Motor torque along against phase A. which the stator field (measured by rotation over the entire speed range must be developed position sensor).

2 Of the Motor , full torque Control at N. zero speed, and fast acceleration and Rotation Axis of phase A. deceleration. To achieve such Control , S. vector Control techniques are used for PM Synchronous motors. The vector Stator windings Control techniques are usually also referred to as field-oriented Control (FOC). The basic idea of the vector maximal, when they are perpendicular How to Simplify Control Control algorithm is to decompose to each other. It means that we want of Phase Currents to a stator current into a magnetic to Control stator current in such a field-generating part and a torque - Achieve Maximum torque way that creates a stator vector generating part.

3 Both components DC Motor Control is simple because perpendicular to rotor magnets. As can be controlled separately after all controlled quantities are DC values the rotor spins we must update the decomposition. Then, the structure in a steady state and current phase/. stator currents to keep the stator flux of the Motor controller (vector Control angle is controlled by a mechanical vector at 90 degrees to rotor magnets controller) is almost the same as a commutator. How can we achieve that at all times. The reactance torque of separately excited DC Motor , which in PMSM Control ?

4 An interior PM type PMSM (IPMSM). simplifies the Control of a Permanent is as follows, when stator and rotor DC Values/Angle Control Magnet Synchronous Motor . magnetic fields are perpendicular. First, we need to know the rotor Let's start with some basic torque = 32pplPMIqs position. The position is typically FOC principles. related to phase A. We can use pp Number of pole pairs an absolute position sensor ( , torque Generation lPM Magnetic flux of the Permanent resolver) or a relative position sensor A reactance torque of PMSM is magnets ( , encoder) and process called generated by an interaction of two Iqs Amplitude of the current in alignment.

5 During the alignment, the magnetic fields (one on the stator and quadrature axis rotor is aligned with phase A and we one on the rotor). The stator magnetic know that phase A is aligned with As shown in the previous equation, the direct (flux producing) axis. In field is represented by the magnetic reactance torque is proportional to the this state, the rotor position is set to flux/stator current. The magnetic field amplitude of the q-axis current, when zero (required voltage in d-axis and of the rotor is represented by the magnetic fields are perpendicular.)

6 Rotor position is set to zero, static magnetic flux of Permanent magnets that is constant, except for the field MCUs must regulate the phase stator voltage vector, which causes that rotor weakening operation. We can imagine current magnitude and at the same attracted by stator magnetic field and those two magnetic fields as two bar time in phase/angle, which is not such to align with them [with direct axis]). magnets, as we know a force, which an easy task as DC Motor Control . tries to attract/repel those magnets, is Beyond Bits Motor Control Edition 1.

7 Three-phase quantities can Figure 2: Basic Principle of Field-Oriented Control transform into equivalent two-phase quantities (stationary reference Measured Current Generated Voltage frame) by Clarke transformation. 2. Then, we transform two-phase quantities into DC quantities by rotor Phase A d d Phase A. electrical position into DC values Three-Phase Stationary Rotating Process Control Phase B Phase B. to to q q to SVM. (rotating reference frame) by Phase C Two-Phase Rotating Stationary Phase C. Park transformation. The electrical rotor position is a Electrical rotor Electrical rotor position position mechanical rotor position divided by numbers of magnetic pole pairs pp.

8 7. Using the space vector modulation, voltage. The calculation of the BEMF. After a Control process we should the output three-phase voltage observer requires math computation generate three-phase AC voltages is generated as multiply accumulation, division, on Motor terminals, so DC values A complete FOC speed PMSM Control sin/cos, sqrt which is suited for DSCs, of the required/generated voltage structure with Freescale Motor Control Kinetis ARM core-based MCUs or the should be transformed by inverse library functions is shown in the Beyond Power Architecture family.

9 Park/Clarke transformations. Bits: Motor Control Edition article titled, Amplitude Control Industrial/Appliance PMSM Drive. Field/Flux Weakening All quantities are now DC values, Control which are easy to Control , but how do Sensorless Control The operation beyond the machine we Control them in magnitude? The rotor position information is base speed requires the PWM inverter For magnitude Control we use PI needed to efficiently perform the to provide output voltages higher than controllers in the cascade structure. Control of the PMS Motor , but a rotor its output capability limited by its DC.

10 We can Control many state variables position sensor on the shaft decreases link voltage. To overcome the base as phase current ( torque loop), speed the robustness and reliability of the speed limitation, a field-weakening or position as with DC motors. overall system in some applications. algorithm can be implemented. A. Therefore, the aim is not to use this negative d-axis required current will FOC in Steps mechanical sensor to measure the increase the speed range, but the To perform vector Control : position directly but instead to employ applicable torque is reduced because some indirect techniques to estimate of a stator current limit.


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