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Design and construction of photovoltaic panel power stabilizer / by Russell B. Escanilla and Jex Ysrael A. Juegas.

By:

Escanilla, Russell B [author]

Contributor(s):

Material type: Text

TextLanguage: English Publication details: Indang, Cavite : Cavite State University- Main Campus, 2019.Description: xxiii, 184 pages : illustrations ; 28 cmContent type:

text

Media type:

unmediated

Carrier type:

volume

Subject(s):

DDC classification:

621.36 Es1 2019

Online resources:

Click here to view abstract and table of contents

Production credits:

College of Engineering and Information Technology (CEIT), Department of Computer and Electronics Engineering

Abstract: ESCANILLA, RUSSELL B. and JUEGOS. JEX YSRAEL A. Design and Construction of Photovoltaic Panel Power Stabilizer. Undergraduate Design Project. Bachelor of Science in Electrical Engineering. Cavite State University, Indang, Cavite. June 2019. Adviser: Engr. Jonathan M. Calina. A study of a Photovoltaic Panel Power Stabilizer (3PS) was conducted at Cavite State University Indang, Cavite. It generally aimed to: (1) design and construct a Photovoltaic Panel Power Stabilizer through integrating supercapacitors technology; (2) test and evaluate the device' response; and (3) conduct a cost computation. The device were designed based on the parameters of the existing photovoltaic panel system: the PV panel, solar charge controller, and the battery. The input side of the system contains a buck converter which steps down the open circuit voltage (Voc) of the source, and the output side contains a boost converter which sets the constant voltage and constant current of the unit delivering a constant power output. The temporary storage device which consist of two supercapacitor bank were able to harness all the generated current regardless of high or low generation of the PV panel during the operation of the device starting from 6 a.m. and ends at 6 p.m.. The unit were tested in a PV panel with a rating of 100 W and 50 W PV panel for five days. The actual generated output of the PV panel and the output of the 3PS unit was compared. The study also calculated the total percentage addition of power to the load and the total cost of the device. Generally, this study proved that the device is reliable and improved the power output of the PV system. The total cost of the device was P20,000.

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Holdings ( 1 )
Title notes ( 5 )

Holdings
Item type	Current library	Collection	Call number	Materials specified	Status	Notes	Date due	Barcode
Theses / Manuscripts	Ladislao N. Diwa Memorial Library Theses Section	Non-fiction	621.36 Es1 2019 (Browse shelf(Opens below))		Room use only	DP-715		00079519

Design Project (Bachelor of Science in Electrical Engineering) Cavite State University.

Includes bibliographical references.

College of Engineering and Information Technology (CEIT), Department of Computer and Electronics Engineering

ESCANILLA, RUSSELL B. and JUEGOS. JEX YSRAEL A. Design and Construction of
Photovoltaic Panel Power Stabilizer. Undergraduate Design Project. Bachelor of Science
in Electrical Engineering. Cavite State University, Indang, Cavite. June 2019. Adviser:
Engr. Jonathan M. Calina.
A study of a Photovoltaic Panel Power Stabilizer (3PS) was conducted at Cavite State
University Indang, Cavite. It generally aimed to: (1) design and construct a Photovoltaic Panel
Power Stabilizer through integrating supercapacitors technology; (2) test and evaluate the
device' response; and (3) conduct a cost computation. The device were designed based on the
parameters of the existing photovoltaic panel system: the PV panel, solar charge controller, and
the battery.
The input side of the system contains a buck converter which steps down the open circuit
voltage (Voc) of the source, and the output side contains a boost converter which sets the
constant voltage and constant current of the unit delivering a constant power output. The
temporary storage device which consist of two supercapacitor bank were able to harness all the
generated current regardless of high or low generation of the PV panel during the operation of
the device starting from 6 a.m. and ends at 6 p.m..
The unit were tested in a PV panel with a rating of 100 W and 50 W PV panel for five
days. The actual generated output of the PV panel and the output of the 3PS unit was
compared. The study also calculated the total percentage addition of power to the load and the
total cost of the device. Generally, this study proved that the device is reliable and improved the
power output of the PV system. The total cost of the device was P20,000.

Submitted to the University Library 08/13/2019 DP-715