Design a grid-tied solar systems for East Wing buildings of Mariano Marcos State University- Batac Campus / Cherry Anne Abarca, Rowel Jake R. Baloaloa, Lucky G. Bungcayao, Camille Rhea C. Caballes, John Paul A. Miguel, John Paul T. Tapon, Abigail A. Turla, Mark Lesther U. Ubi
Material type:
TextPublication details: City of Batac : MMSU, 2024Description: xxvii, 78 leaves : 29 cmSummary: The evolving global energy landscape has significantly due to increasing demand for sustainable and reliable energy solutions to address the challenges of aging infrastructure, rising costs, and environmental concerns associated with traditional fossil fuel-based power generation; This study evaluates the feasibility and design considerations for installing a rooftop Solar Photovoltaic (PV) system in the East Wing buildings of Mariano Marcos State University (MMSU) - Batac Campus. The objectives include developing a single-line diagram, analyzing demand and energy consumption, designing a suitable solar PV system with appropriate capacity and battery storage, and determining the financial feasibility of the project; Data were gathered through hourly energy meter readings over 14 days and analyzed to estimate energy usage and demand. The study concluded that four buildings—Covered Court & Student Center (CC & SC), College of Business, Economics, and Accountancy (CBEA), College of Health and Sciences (CHS), and College of Medicine (COM)—are suitable for solar panel installation, covering a total roof area of 17,009 m² and accommodating 2,000 solar panels. The designed systems include 300kWp grid-tied systems for CBEA and CC & SC buildings, a 200kWp grid-tied system for the CHS building, and a 150kWp hybrid system for the COM building. Financial analysis is also included indicating a five-year return on investment. The study demonstrates that implementing a solar PV system at MMSU's East Wing buildings is feasible, providing significant potential for reducing energy costs, carbon xxvi footprint, and reliance on conventional energy sources, thereby contributing to the university's sustainability goals.
| Item type | Home library | Shelving location | Call number | Status | Notes | Date due | Barcode |
|---|---|---|---|---|---|---|---|
| Thesis/Dissertation | MMSU Main Library | Theses and Dissertation Section | Available | Room Use Only | UTHESIS-6921 |
Browsing MMSU Main Library shelves, Shelving location: Theses and Dissertation Section Close shelf browser (Hides shelf browser)
UTHESIS ( Bachelor of Science in Electrical Engineering)
Bibliography: leaves 78
The evolving global energy landscape has significantly due to increasing demand for sustainable and reliable energy solutions to address the challenges of aging infrastructure, rising costs, and environmental concerns associated with traditional fossil fuel-based power generation; This study evaluates the feasibility and design considerations for installing a rooftop Solar Photovoltaic (PV) system in the East Wing buildings of Mariano Marcos State University (MMSU) - Batac Campus. The objectives include developing a single-line diagram, analyzing demand and energy consumption, designing a suitable solar PV system with appropriate capacity and battery storage, and determining the financial feasibility of the project; Data were gathered through hourly energy meter readings over 14 days and analyzed to estimate energy usage and demand. The study concluded that four buildings—Covered Court & Student Center (CC & SC), College of Business, Economics, and Accountancy (CBEA), College of Health and Sciences (CHS), and College of Medicine (COM)—are suitable for solar panel installation, covering a total roof area of 17,009 m² and accommodating 2,000 solar panels. The designed systems include 300kWp grid-tied systems for CBEA and CC & SC buildings, a 200kWp grid-tied system for the CHS building, and a 150kWp hybrid system for the COM building. Financial analysis is also included indicating a five-year return on investment. The study demonstrates that implementing a solar PV system at MMSU's East Wing buildings is feasible, providing significant potential for reducing energy costs, carbon xxvi footprint, and reliance on conventional energy sources, thereby contributing to the university's sustainability goals.
There are no comments on this title.