ABSTRACT
Switched Reluctance
Motor (SRM) is becoming increasingly popular in industrial applications such as
wind energy systems and electric vehicles due to its simple and rugged design,
capacity for high-speed operation, resistance to high temperatures, and
fault-tolerant features. Despite these features, SRM has some drawbacks such as
torque ripple and acoustic noise. Hence, there is need for detailed design and
analysis of the motor. Finite element analysis of a 3-phase, 6/4, 1.5 kW SRM
has been performed for enhanced performance in this dissertation. An
intelligent optimization program based on multi-objective genetic algorithm
(NSGA-II) was implemented to study the effects of saturation, stator yoke, pole
embrace of the stator and rotor on the average torque, efficiency, average
total loss, and average torque ripples. It was observed that the stator pole
embrace, and yoke thickness, are the key parameters to the optimization
objectives. The comprehensive performance of the optimized design in terms of
average torque and efficiency were 5.59 Nm and 96.20% respectively, which were
15 % and 13.2 % better than the base model. Also, there were 30.1 % and 1.55 %
reduction in average total loss and torque ripple in the optimized model when
compared with the base design. This proves the success of the NSGA-II
intelligent optimization program as a framework to optimize the specified
objective functions. Furthermore, 2D thermal FEM model was established in
Maxwell 2D and was exported to lumped parameter thermal network of MotorCAD.
The lumped parameter method was used to analyze the temperature of the motor in
which all parts of the heat path were combined to form thermal circuit system
for the entire motor. It was observed that flow rate II of 15 l/min gave the
lowest temperature levels of 251.5 0C and 158.3 0C in the winding and 150.2 0C
and 198.1 0C in the lamination at both regions respectively; hence, it was
adopted for further thermal analysis of motor over wide range of speed.
Maxwell’s stress tensor method was used in the 2D electromagnetic FEA analysis
to compute radial and tangential electromagnetic forces that were applied on
the stator tips in Maxwell 2D/3D. It was observed that tangential force
increased by 48.6% in the optimized model which indicates higher torque
generation than the initial model whereas the radial force decreased by 19.2%
in the optimized model which shows that the effect of vibration was minimized
in the optimized model. The full acoustic fingerprints of the normal and
optimized models were also given by the waterfall diagrams which displayed the
equivalent radiated power level that estimated the radiated structure-borne
sound power from the vibrating structural surface which is the stator surface
in this dissertation. For laboratory testing of the studied motor, the
electromagnetic torque equivalent of the electronic load box has maximum limit
torque of 6.6 Nm, which was the adopted torque limit for experimental
verification. The experimental results sufficiently validate the accuracy of
the proposed SRM model.
-- (2023). Finite Element Analysis Of Switched Reluctance Motor For Enhanced Performance. Mouau.afribary.org: Retrieved Nov 23, 2024, from https://repository.mouau.edu.ng/work/view/finite-element-analysis-of-switched-reluctance-motor-for-enhanced-performance-7-2
--. "Finite Element Analysis Of Switched Reluctance Motor For Enhanced Performance" Mouau.afribary.org. Mouau.afribary.org, 20 Jun. 2023, https://repository.mouau.edu.ng/work/view/finite-element-analysis-of-switched-reluctance-motor-for-enhanced-performance-7-2. Accessed 23 Nov. 2024.
--. "Finite Element Analysis Of Switched Reluctance Motor For Enhanced Performance". Mouau.afribary.org, Mouau.afribary.org, 20 Jun. 2023. Web. 23 Nov. 2024. < https://repository.mouau.edu.ng/work/view/finite-element-analysis-of-switched-reluctance-motor-for-enhanced-performance-7-2 >.
--. "Finite Element Analysis Of Switched Reluctance Motor For Enhanced Performance" Mouau.afribary.org (2023). Accessed 23 Nov. 2024. https://repository.mouau.edu.ng/work/view/finite-element-analysis-of-switched-reluctance-motor-for-enhanced-performance-7-2