MATHEMATICAL MODELING OF DIRECT CURRENT MOTOR OPERATION WITH DIFFERENT EXCITATION TYPES FOR VIBRATIONAL MACHINES

Abstract

This work is dedicated to the development and analysis of a mathematical model for a direct current motor with various types of excitation for vibrational machines. Vibrational machines play a crucial role in many industrial sectors, and their operational characteristics are determined by the efficiency and accuracy of motor performance. In this study, we investigate different types of excitation for direct current motors and develop corresponding mathematical models. Employing principles from control theory and quantitative electronics, we account for the influence of different excitation parameters on the motor's dynamic behavior. The obtained results could be valuable for the development of new hybrid excitation systems for vibrational machines, capable of operating in diverse modes depending on specific additional conditions. Additionally, the analysis and development of the mathematical model can serve as a foundation for further research in optimizing the operation of vibrational systems using direct current motors. Analyzing the results, we compare the efficiency of various excitation types and their impact on the operational characteristics of vibrational machines. Moreover, we explore possibilities for reducing power consumption and enhancing speed regulation accuracy. Special attention is devoted to analyzing system stability under different operating conditions and parameter variations. The findings of our research hold important practical applications in the design and improvement of vibrational machines for industrial, technical, and scientific purposes. They contribute to understanding the influence of different factors on the performance of direct current motors with various excitation types, which can aid engineers and designers in enhancing the efficiency and reliability of vibrational systems. In conclusion, this research is aimed at developing and analyzing a mathematical model for a direct current motor with various excitation types, considering their impact on the operational characteristics of vibrational machines. It makes a significant contribution to understanding and optimizing the processes of such systems, potentially exerting a substantial influence on the advancement of modern technology in the field of vibrational systems and their applications.