ABSTRACT
This research studies the performance index of a 1.5kV/24V power inverter, seeking to assess its efficiency, dependability, and overall effectiveness in converting DC power to AC power. The study delves into the fundamental principles underpinning power inverter functioning, exploring crucial parameters such as input voltage, output voltage, frequency stability, and waveform quality. By studying these parameters, the study intends to provide insights into the inverter's capability to meet the demands of diverse applications, including renewable energy systems, uninterruptible power supplies, and industrial automation. The approach adopted in this inquiry comprises both theoretical analysis and experimental evaluation. Through literature study and theoretical modeling, the project offers a framework for understanding the underlying principles driving power inverter performance. Subsequently, detailed experimental testing is conducted utilizing a 1.5kV/24V power inverter prototype, concentrating on factors such as input/output voltage control, harmonic distortion and efficiency. These tests are carried out under diverse load levels and operating scenarios to analyze the inverter's behavior across a wide range of practical settings. Preliminary results from the experimental tests reveal favorable performance characteristics of the 1.5kV/24V power inverter. Initial studies reveal good efficiency levels, low harmonic distortion, and satisfactory frequency stability under typical operating settings. However, further investigation and validation are required to completely assess the inverter's performance index and its applicability for diverse real-world applications. The outputs of this research are intended to provide useful insights 7 for improving the design, operation, and utilization of power inverters, contributing to the advancement of energy conversion technologies and the creation of sustainable power systems.
