Modelling a Possibility Framework of a Smart Self Sustainable Hybrid Power Generation System for a Typical Residential Loading

Year 2018, Volume: 2 Issue: 2, 70 - 83, 30.06.2018

İfedayo Oladeji Aminat Oyinlola

https://doi.org/10.30521/jes.413691

Abstract

Generation of electricity using fossil fuels
could be regarded as the greatest invention of mankind. However, with the
depletion of this resource and also due to the effect of burning fossil fuels
on the environment, it is imperative to find an alternative to generating
electricity for local consumption using non-fossil fuel methods. In the bid to
key into the global idea of power generation decarburization and also smart
distribution system through the internet of things (IOT), this paper presents
an active redundancy possibility framework for generating constant electricity
from the motor-generator (M-G) and the battery-inverter (B-I) systems. The
specifications of each component can be obtained from design models presented
in this paper. The functionality of the system is achieved through the smart
home distribution hub (SHDH). Each unit are modeled and simulated to obtain the
transfer functions. The result of the residential loading is presented. The
simulation results show that the system is achievable and also stable under
circumstances which are being monitored and controlled by the smart hub. The
framework presented in this paper has proved to be a viable and smart
alternative source of electric energy for residential loading.

Keywords

Power electronics, Motor-Generator Set, Battery-Inverter Set, Smart control hub and Reliability

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