COMPARATIVE EVALUATION OF FOREIGN AND LOCALLY ASSEMBLED HYBRID 3.5KVA INVERTER SYSTEM
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Abstract
The aim of this project is to carry out a comparative evaluation of foreign and
homebased manufactured hybrid 3.5kva inverter system. Conventional non-hybrid inverter
systems are characterized by their dependency on the grid, low efficiency in solar charging, limited energy management capabilities, and ineffective communication between components. Therefore, this endeavor is designed to integrate hybrid features to overcome these shortcomings. The process entailed comparing a hybrid inverter system to address the limitations of non-hybrid inverters and to do this, we incorporated an alternative power source, i.e. solar energy, to charge the battery. This involved designing an MPPT (Maximum Power Point Tracking) charge controller and seamlessly integrating its circuitry with that of the inverter in the non-hybrid system. Additionally, we established effective communication between the DSPIC30F2010 microcontroller on the inverter and the DSPIC30F2010 microcontroller on the MPPT circuitry using serial communication, which we integrated into the inverter. All communication protocols were outlined in the source code. To ensure organization and tidiness, we housed all these components within a single enclosure. The project successfully achieved its intended objectives by comparing the hybrid features of the homebased and foreign manufactured inverter systems. Through meticulous design and implementation, all identified limitations were effectively addressed, leading to significant improvements in system performance and functionality. Relevant tests such as output voltage and frequency test, load and no load test, as well as power efficiency tests were carried out to compare the performances of the foreign and home based manufactured hybrid inverter systems. The performance of the home based hybrid inverter was 219.8V for output voltage versus 230V for the foreign. Frequency for home based was 50.04Hz versus 50.0Hz for the foreign. Both inverters displayed a comparable sine wave output. Power efficiency for home based was 90.64 percent while for foreign, it was 94.5 percent, these results show that there was no remarkable difference between the output of the home based compared to the foreign inverter. Furthermore, the locally assembled inverter cost far less than the foreign counterpart. Hence, this study proves that cost efficient inverter systems can be manufactured locally
homebased manufactured hybrid 3.5kva inverter system. Conventional non-hybrid inverter
systems are characterized by their dependency on the grid, low efficiency in solar charging, limited energy management capabilities, and ineffective communication between components. Therefore, this endeavor is designed to integrate hybrid features to overcome these shortcomings. The process entailed comparing a hybrid inverter system to address the limitations of non-hybrid inverters and to do this, we incorporated an alternative power source, i.e. solar energy, to charge the battery. This involved designing an MPPT (Maximum Power Point Tracking) charge controller and seamlessly integrating its circuitry with that of the inverter in the non-hybrid system. Additionally, we established effective communication between the DSPIC30F2010 microcontroller on the inverter and the DSPIC30F2010 microcontroller on the MPPT circuitry using serial communication, which we integrated into the inverter. All communication protocols were outlined in the source code. To ensure organization and tidiness, we housed all these components within a single enclosure. The project successfully achieved its intended objectives by comparing the hybrid features of the homebased and foreign manufactured inverter systems. Through meticulous design and implementation, all identified limitations were effectively addressed, leading to significant improvements in system performance and functionality. Relevant tests such as output voltage and frequency test, load and no load test, as well as power efficiency tests were carried out to compare the performances of the foreign and home based manufactured hybrid inverter systems. The performance of the home based hybrid inverter was 219.8V for output voltage versus 230V for the foreign. Frequency for home based was 50.04Hz versus 50.0Hz for the foreign. Both inverters displayed a comparable sine wave output. Power efficiency for home based was 90.64 percent while for foreign, it was 94.5 percent, these results show that there was no remarkable difference between the output of the home based compared to the foreign inverter. Furthermore, the locally assembled inverter cost far less than the foreign counterpart. Hence, this study proves that cost efficient inverter systems can be manufactured locally
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