Hybrid Dual Energy Source MPPT PV System with BESS Storage.

Problem Definition

Problem Description: One of the main challenges faced in renewable energy systems, particularly in solar PV systems, is the fluctuation in power output due to changing weather conditions such as atmospheric temperature and solar irradiation. This variability in power output can lead to inefficiencies in the overall system and a loss of potential energy generation. In order to address this issue, an effective Maximum Power Point Tracking (MPPT) mechanism is essential to optimize the power output of the PV arrays in real-time. Furthermore, with the increasing integration of multiple energy sources such as solar and wind, there is a need for developing hybrid systems that can effectively utilize the advantages of both sources. The integration of different energy sources poses challenges in terms of system design, operation, and control to ensure a stable and reliable power supply.

In addition, the utilization of Battery Energy Storage Systems (BESS) to store and utilize excess power produced by the renewable sources is crucial for ensuring a continuous power supply during periods of low generation or high demand. However, effective integration and management of BESS with the renewable energy systems are essential to maximize the benefits of energy storage and ensure system stability. Addressing these challenges requires the development of a hybrid dual energy source PV model with an efficient MPPT system that can effectively integrate solar and wind energy sources, optimize power output, and utilize BESS for energy storage and management. This project aims to develop a comprehensive solution to enhance the performance and reliability of renewable energy systems in real-world applications.

Proposed Work

The proposed work focuses on a Hybrid Dual Energy Source PV Model with an analysis of MPPT system. Renewable power systems are increasingly popular globally, with solar energy being the most widely used due to its noise-free and pollution-free characteristics. This project will explore the use of different materials in semiconductors and the configuration of cells in series and parallel to meet voltage and current requirements. The fluctuation in power output due to weather conditions necessitates the use of MPPT mechanism for maximum power extraction from PV arrays. The integration of solar and wind energy systems will be studied, with the utilization of Battery Energy Storage System for efficient power storage and utilization.

The project will be implemented using Basic Matlab and MATLAB Simulink software tools in the category of Electrical Power Systems for M.Tech and PhD Thesis Research Work. This research falls under the subcategories of Latest Projects and MATLAB Projects Software.

Application Area for Industry

This project can be used in a variety of industrial sectors, including renewable energy, power generation, and smart grid systems. Industries that rely on solar PV systems for energy generation can benefit from the efficient Maximum Power Point Tracking (MPPT) mechanism proposed in this project, which can optimize power output and minimize inefficiencies due to fluctuating weather conditions. Furthermore, industries looking to integrate multiple energy sources, such as solar and wind, can utilize the hybrid dual energy source PV model to effectively utilize the advantages of both sources and ensure a stable and reliable power supply. The integration of Battery Energy Storage Systems (BESS) also makes this project relevant for industries looking to store and manage excess power for continuous supply during periods of low generation or high demand. By addressing the challenges of power output variability, integration of multiple energy sources, and efficient energy storage management, this project offers a comprehensive solution to enhance the performance and reliability of renewable energy systems in real-world applications.

Industries can benefit from increased energy efficiency, cost savings, and improved system stability by implementing the proposed solutions. Overall, this project has the potential to revolutionize the way renewable energy systems are designed, operated, and controlled in various industrial domains, contributing to a more sustainable and reliable energy future.

Application Area for Academics

The proposed project on a Hybrid Dual Energy Source PV Model with an efficient MPPT system offers significant potential for research by MTech and PhD students in the field of renewable energy systems. This project addresses the crucial issue of power output fluctuation in solar PV systems due to changing weather conditions, and the integration of multiple energy sources to optimize power output and ensure a stable power supply. The research work involves the analysis of different materials in semiconductors, cell configurations, and the development of an effective MPPT mechanism for maximum power extraction. The integration of solar and wind energy systems, along with the utilization of Battery Energy Storage Systems, will be explored for efficient power storage and management. MTech and PhD students can use the code and literature of this project for innovative research methods, simulations, and data analysis in their dissertations, theses, or research papers.

This project covers the technology and research domain of Electrical Power Systems, offering a practical application for researchers in this field. The future scope of this research includes the potential for further advancements in hybrid energy systems and renewable energy technologies. This project provides a valuable opportunity for MTech students and PhD scholars to contribute to the advancement of renewable energy systems and sustainable energy solutions.

Keywords

renewable energy systems, solar PV systems, power output, weather conditions, atmospheric temperature, solar irradiation, inefficiencies, Maximum Power Point Tracking (MPPT), hybrid systems, energy integration, system design, operation, control, power supply, Battery Energy Storage Systems (BESS), energy storage, system stability, dual energy source PV model, solar energy, wind energy, power optimization, energy management, real-world applications, semiconductors, series and parallel configuration, voltage requirements, current requirements, Matlab, MATLAB Simulink, Electrical Power Systems, M.Tech thesis, PhD thesis, research work, Latest Projects, MATLAB Projects Software.