Documentation Home Page OPAL-RT Schematic Editor Home Page
Pour la documentation en FRANÇAIS, utilisez l'outil de traduction de votre navigateur Chrome, Edge ou Safari. Voir un exemple.

Skip to end of metadata
Go to start of metadata

You are viewing an old version of this page. View the current version.

Compare with Current View Page History

Version 1 Next »

This block implements a squirrel-cage induction machine (SCIM)

The SCIM block implements a three-phase induction machine (asynchronous machine) with a squirrel-cage rotor model with resolvers and encoders. The machine can operate in both motoring mode, when the mechanical torque is positive, and generating mode when the mechanical torque is negative.

Model Formulation

Q-d Transformation

The 3-phase to q-d transformation and the inverse used for the model are:


θ required for the q-d transformation depends on the chosen reference frame as follows:

  • Rotor reference frame: θ=θr,
  • Stationary reference frame: θ=0,
  • Synchronous reference frame: θ=θe.

Since the Induction Machine is modeled in rotor reference frame, the θ required for the q-d transformation is the rotor electrical angle (θr).

Induction Machine Electrical Model

Induction machine models in state space framework are based on magnetic fluxes as the state variables and winding currents as the outputs, and can be represented as follows:


where the coefficient matrices are as follows:



and


The Induction Machine is modeled in rotor reference frame so ω=ωr.

In the model, all the rotor parameters and variables are seen from the stator distinguished by a prime sign. Since the squirrel-cage rotor type is not supplied by an external source, then it is always the case that V'rq=V'rd=0.

The electrical torque can be calculated as follows:

Mechanical Model

The equation of the mechanical model in torque mode can be expressed as follows:


where ωm is the rotor speed, Te is the electromagnetic torque, Tm is the torque command, Fv is the viscous friction coefficient, J is the inertia and Ts the time step. There is a dead-zone implementation with the static friction torque, if the electromagnetic doesn't exceed the static friction torque, the speed remains zero.

In speed mode, the rotor speed is directly set to the speed command ωrc.

Resolver Encoder Model

The equations of the resolver encoder can be expressed as follows:



where θres is the resolver angle, θmec is the mechanical angle of the machine, θoffset is the angle offset, Rpp is the Number of pole pairs of the resolver and Rk are the resolver sine cosine gains.

Parameters and Measurements

The SCIM's parameters and measurements are separated in 4 different tabs, Electrical, Mechanical, Resolver and Encoder.

Electrical Parameters and Measurements

SymbolNameDescriptionUnitType
RsStator resistanceStator winding resistance of phase a, b, and cΩEdit-input
LlsStator leakage inductanceStator winding leakage inductance of phase a, b, and cHEdit-input
Rr'Rotor resistanceEquivalent rotor winding resistance referred to the stator of phase a, b, and cΩEdit-input
Llr'Rotor leakage inductance Equivalent rotor winding leakage inductance referred to the stator of phase a, b, and cHEdit-input
LmMutual inductanceStator-rotor mutual (magnetizing) inductance of phase a, b, and cHEdit-input
ppNumber of pole pairsNumber of pole pairsN/AEdit-input
isStator phase currentsStator currents measured at phases a, b and cAMeasurement
isqdStator qd currentsStator currents in qd frameAMeasurement
ΦsqdStator qd fluxesStator fluxes in qd frameWbMeasurement
VsqdStator qd voltagesStator voltages in qd frameVMeasurement
ir'Rotor phase currentsRotor equivalent phase a, b, and c currents, referred to the statorAMeasurement
irqdRotor qd currentsRotor currents in qd frame, referred to the statorAMeasurement
Φrqd'Rotor qd fluxesRotor fluxes in qd frame, referred to the statorWbMeasurement
RsnSnubber resistanceResistances of the snubber on phase A, B and CΩInput
CsnSnubber capacitanceCapacitance of the snubber on phase A, B and CFInput

Mechanical Parameters and Measurements

SymbolNameDescriptionUnitType
JRotor inertiaMoment of inertia of the rotorkg*m2Input
FvViscous friction coefficientViscous frictionN*m*s/radInput
FsStatic friction torqueStatic frictionN*mInput
ctrlMechanical control modeControl mode of the mechanical model. Has two possible values: speed or torque. In speed mode, the mechanical model is bypassed and the speed command is sent directly. In torque mode, the torque command is used to measure the speed using the mechanical parameters of the machine.
Input
TTorque commandTorque command sent to the mechanical modelN*mInput
ωrcRotor speed commandSpeed command sent to the mechanical modelrpmInput
ωrRotor speedSpeed of the rotorrpmMeasurement
TeElectromagnetic torqueTorque measured at the rotorN*mMeasurement
θ0Initial rotor angleRotor position at time t = 0°Input
θRotor angleRotor position from 0 to 360 degrees°Measurement

Resolver Parameters and Measurements

SymbolNameDescriptionUnitType
RenEnable resolverWhether or not to enable the resolverN/AInput
RscResolver feedback signalsThe two two-phase windings producing a sine and cosine feedback current proportional to the sine and cosine of the angle of the motorN/AMeasurement
RppNumber of resolver pole pairsNumber of pole pairs of the resolverN/AInput
RdirDirection of the sensor rotationDirection in which the sensor is turning, either clockwise or counterclockwiseN/AInput
RθAngle offset Δθ ( Sensor-  Rotor )Angle offset between the resolver and the rotor position from 0 to 360 degrees°Input
RkResolver sine cosine gainsThe sine/cosine modulation output sine/cosine component amplitude. Default value are 1, 0, 0 and 1N/AInput
EtypeExcitation source typeThe source from which the excitation of the resolver is generated. Can either be AC, which is generated inside the FPGA with the specified frequency, DC, which is generated with a 90° from the rotor and External, which is generated from outside the modelN/AInput
EfExcitation frequencyFrequency of the excitation when in AC modeHzInput
EsrcExcitation sourceSource of the external excitation source when in External modeN/AInput
EtsExcitation time shiftThis parameter is used to compensate the time offset between the carrier generation's input in the system and modulated signals' outputsInput

Encoder Parameters and Measurements

SymbolNameDescriptionUnitType
EncenEnable encoderWhether or not to enable the encoderN/AInput
QABZA B Z encoder signalsA B and Z signals of the encoderN/AMeasurement
QpprNumber of pulses per revolutionNumber of pulses in one full revolution of the encoderN/AInput
QdirDirection of the sensor rotationDirection in which the sensor is turning, either A leads B or B leads AN/AInput
θoffsetAngle offset Δθ ( Sensor - Rotor )Angle offset between the encoder and the rotor position from 0 to 360 degrees°Input

Visualization of Resolver Encoder Parameters Effects

Number of resolver pole pairs affects the number of electrical turns per mechanical turns. On the left figure, the number of resolver pole pairs is 2, on the right figure, the number of resolver pole pairs is 4.

Resolver sine cosine gains affect the sine ( first axe ) and cosine ( second axe ) modulation output. Default values set to 1, 0, 0, 1 make it so the sine modulation has a sine form and the cosine modulation has a cosine form. If set to 0, 1, 1, 0, the sine modulation would have a cosine and the cosine modulation would have a sine form.

Excitation frequency, in AC excitation source type, affects the frequency of the carrier signal. We can see the time step highlighted in red. ( Figure 3 is a zoomed in view of Figure 2 )

Number of pulses per revolution (Qppr) defines how many times signals A and B pulse between two Z pulses ( one full rotation ).

Direction of the sensor rotation describes if A leads B ( Clockwise ) or if B leads A ( Counterclockwise )

Electrical ports

  • This block has three electrical ports, the three terminals of the stator.


  • No labels