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Software for Laboratory stand with inverters and motors
Smolák, Martin ; Ctibor, Jiří (referee) ; Knobloch, Jan (advisor)
This bachelor‘s thesis focuses on control firmware for two microprocessors and visualization software of laboratory tasks on the computer. The first of the microprocessor controls a DC motor with permanent magnets and the second one an induction motor. The thesis first describes the hardware of the stand, the principle of AC motors control, Clark‘s and Park‘s transformation, description of firmware for DC and induction motor. Further there is described the visualization environment which serves students for controlling the stand and for calculation of the current regulator using the method of optimal module.
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Modeling and controling of a laboratory stand with an induction and DC motor
Musil, Pavel ; Pazdera, Ivo (referee) ; Knobloch, Jan (advisor)
This bachelor thesis deals with the theory of an asynchronous machine and the types of its management. It focuses on assembling a laboratory model with an asynchronous and DC motor connected via resolver on a common shaft. In order to set the model correctly, the asynchronous motor is first measured, the appropriate parameters are obtained and the model's behavior towards the real device is tested. The resulting part is a set of laboratory tasks possible for this model and equipment.
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Software for Laboratory stand with inverters and motors
Smolák, Martin ; Ctibor, Jiří (referee) ; Knobloch, Jan (advisor)
This bachelor‘s thesis focuses on control firmware for two microprocessors and visualization software of laboratory tasks on the computer. The first of the microprocessor controls a DC motor with permanent magnets and the second one an induction motor. The thesis first describes the hardware of the stand, the principle of AC motors control, Clark‘s and Park‘s transformation, description of firmware for DC and induction motor. Further there is described the visualization environment which serves students for controlling the stand and for calculation of the current regulator using the method of optimal module.
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