Real-time implementation of PMSM software model on external hardware

Sjöberg, Alexander

January 2017

When developing three phase motor drives, the best way to validate the desiredfunctionality is to connect the inverter to an actual electrical motor. However, when developingfunctions which are not directly involved in controlling the motor, it could bemore efficient to use a real-time software model of the motor. In this master thesis, the developmentand implementation of a software model of a permanent magnet synchronousmotor (PMSM) is presented. This model was based on general dynamic equations forPMSM in a rotating reference frame (dq-frame). The model was simulated and convertedto C code using model based software development in Mathworks Simulink. To providemore realistic performance of the model, a finite element analysis (FEA) was done of anactual PMSM using the software tool FEMM. This analysis resulted in data describingthe relation between flux linkage and current which, when added into to software model,limits the produced torque due to magnetic saturation. Both the FEMM model and thefinal software model was compared to a corresponding actual motor for validation andperformance testing. All this resulted in a fully functional software model which was executableon the inverter. In the comparison of FEMM model to the real motor, a deviationin produced torque was discovered. This led to the conclusion that the model needed to beimproved to perform more alike the real motor. However, for this application the modelwas considered good enough to be used in future software development projects. / N¨ar kontrollsystem till trefasmotorer utvecklas s°a ¨ar det mest vanliga och troligendet b¨asta s¨attet f¨or funktionsvalidering att k¨ora drivenheten kopplad mot en riktig elektriskmotor. D¨aremot, om funktioner som ej ¨ar direkt kopplade till sj¨alva drivningen av motornutvecklas, s°a kan det vara mer effektivt att ist¨allet anv¨anda en mjukvarumodell. I det h¨arexamensarbetet s°a presenteras en mjukvarumodell av en permanentmagnetiserad synkronmotor(PMSM). Modellen baserades p°a de generella ekvationerna f¨or PMSM och simuleradessamt kodgenererades i Mathworks verktyg Simulink. F¨or att g¨ora modellen mer realistisks°a kompletterades den med data som beskriver relationen mellan det l¨ankade fl¨odetoch str¨om f¨or att ¨aven ta h¨ansyn till magnetisk m¨attnad. Den informationen simuleradesfram i verktyget FEMMgenom fl¨odesber¨akningar p°a en specifik motor typ. Samma motortyp har ocks°a j¨amf¨orts med den slutgiltiga mjukvarumodellen med avseende p°a utvecklatvridmoment vilket resulterade i n°agot st¨orre skillnader ¨an f¨orv¨antat. Slutsatsen blevs°aledes att modellen beh¨over f¨orb¨attras f¨or att p°a ett b¨attre s¨att st¨amma ¨overens med verklighetenmen att den fungerar tillr¨ackligt bra f¨or den ¨amnade applikationen.

Model based software development

real-time software model

Modellbasserad mjukvaruutveckling

realtidsmodellering

Elektroteknik och elektronik

Non-Coupled and Mutually Coupled Switched Reluctance Machines for an E-Bike Traction Application: Pole Configurations, Design, and Comparison

Howey, Brock

January 2018

This dissertation contains a comprehensive analysis of both non-coupled and mutually coupled switched reluctance motors with concentrated windings for an electric bicycle traction application. Multiple pole configurations are analyzed and compared for each motor type. Includes magnetic design, thermal analysis, and structural analysis. A prototype is designed, manufactured, and validated. / This thesis discusses the design of both a conventional non-coupled switched reluctance motor (CSRM) and a mutually-coupled SRM (MCSRM) for an exterior rotor e-bike application. Several novel pole configurations were analyzed for each machine type, and the performance of the final CSRM and MCSRM designs were compared for this application. A commercially available e-bike permanent magnet synchronous motor (PMSM) was purchased, reverse engineered, and validated to define the geometry constraints and performance targets for the designs. Since switched reluctance motors do not use rare-earth permanent magnets, they are often seen as a potential low-cost alternative to permanent magnet machines. The goal of this research is to explain the relative advantages of CSRMs and MCSRMs when compared to PMSM machines for a direct-drive e-bike application. The final CSRM and MCSRM designs are analyzed in detail; electromagnetic, controls, thermal, and structural considerations are all studied. A prototype of the final CSRM design was manufactured and validated experimentally, using a dynamometer setup. The finalized CSRM design is shown to be competitive with the PMSM machine when considering torque output, and is superior in terms of peak efficiency, and high speed torque performance. However, the CSRM noise output and torque ripple were not compared to the PMSM, and a less-common asymmetric-bridge converter is required for the CSRM, which may hinder the ability for the machine to be implemented into existing e-bike packages. The high speed torque performance of the MCSRM is shown to be inferior to both the CSRM and PMSM, as is the torque quality and efficiency. The MCSRM is shown to be highly resistant to saturation which gives it the potential for high torque output at low speed (if thermal limits are not breached), though low saturation levels also contribute to low machine power factor. The MCSRM may be better suited to lower speed, high torque applications, for this reason. / Thesis / Doctor of Philosophy (PhD) / This thesis studies the design process and analysis of two different motor types, for an electric bicycle application. They are designed to replace a commercially available permanent magnet synchronous motor (PMSM). This type of motor is typically expensive due to the rare-earth magnet material it requires. The two motors discussed in this thesis are switched reluctance motors (SRMs), which do not require magnet material, and thus have the potential to save cost (in addition to other benefits). One of the SRMs has magnetic fields that are independently controlled (CSRM), and one has fields that are controlled together to produce torque (MCSRM). The magnetics, control, thermal, and structural aspects of the CSRM and MCSRM are studied in detail. Novel geometry considerations (i.e. novel pole configurations) which impact the magnetics of each machine are compared to find the best-performing configuration for each machine type.

Switched Reluctance Motor

Traction Motor

Reluctance Machine

Motor Modelling

Magnetic Saturation

Electric Bicycle

SRM

MCSRM

E-Bike

Concentrated Winding

Mutual Coupling