Photovoltaic Systems Engineering Electronic Control Devices (ECDs)

Slides:



Advertisements
Similar presentations
Solar Array & Maximum Power Point Tracker Group Senior Design Project 2003 Stephanie Chin Jeanell Gadson Katie Nordstrom Advisor: Karen Panetta.
Advertisements

Supercapacitor Energy Storage System for PV Power Generation
Team: – Brad Jensen – Will Klema – Nate Schares Client: – PowerFilm, Inc. Advisor: – Dr. Ayman Fayed Solar-Powered Mobile Power Station (MPS)
Introduction Since the beginning of the oil crises, which remarkably influenced power development programs all over the world, massive technological and.
+ DC – DC Converter For a Thermoelectric Generator Ciaran Feeney 4 th Electronic Engineering Student FYP Progress Presentation Supervisor: Dr. Maeve Duffy.
A NOVEL EFFICIENT STAND- ALONE PHOTOVOLTAIC DC VILLAGE ELECTRICITY SCHEME A.M. Sharaf, SM IEEE, and Liang Yang Department of Electrical and Computer Engineering.
Solar Power Controllers. Why you need to know about controllers A charge controller is an essential component of any battery-based system because it protects.
Solar Charge Controllers Alison Ray and Scott Hamshaw.
DC bus for photovoltaic power supplying computing loads
Guided By:- Mr. Sibasish Panda (Assistant Professor) Presented By:-
Chapter 8 Inverters AC Power • Inverters • Power Conditioning Units • Inverter Features and Specifications.
POWER SUPPILES LECTURE 20.
To develop a small scale solar powered system that will power a DC load, which incorporates power management techniques, DC-DC conversion and a user interface.
1 © Alexis Kwasinski, 2012 Power electronic interfaces Power electronic converters provide the necessary adaptation functions to integrate all different.
M OBILE P OWER S TATION A BSTRACT The Mobile Power Station (MPS) is a device that manages and stores solar energy in a lithium ion (Li-ion) battery pack.
Cost-Effective Hundred-Year Life for Single-Phase Inverters and Rectifiers in Solar and LED Lighting Applications through Port-Based Ripple Management.
Solar Powered Battery Charger
Sustainable Energy Systems Engineering Peter Gevorkian Ch 2: Solar Power Generation Design Brevard Community College EST1830 Bruce Hesher.
ET3380 Principles and Methods of Electric Power Conversion David Morrisson MS,MBA Week 1.
SOLAR TRACKING USING FUZZY LOGIC
Charge Controllers Regulating Battery Charging.
Michael Ikerionwu 4 th year Electronic Engineering.
Fearghal Kineavy 4 th Energy Systems Engineering – Electrical Stream Department of Electrical and Electronic Engineering, NUIG Supervisor: Dr Maeve Duffy.
Dc bus for photovoltaic power supplying computing loads 4 th year Electronic Engineering Michael ikerionwu.
Balance of Systems (BOS)
Stand-Alone PV Systems, Part 2
CUER Electrical System
Battery Backup PV Systems Design Considerations
Students: Thomas Carley Luke Ketcham Brendan Zimmer Advisors: Dr. Woonki Na Dr. Brian Huggins Bradley University Department Of Electrical Engineering 2/28/12.
Solar Power Charge Controller. Solar Power Charge Controller Introduction  A charge controller, or charge regulator is basically.
Date of download: 6/26/2016 Copyright © ASME. All rights reserved. From: A Single Stage Photovoltaic Inverter With Common Power Factor Control and Maximum.
Renewable Energy Systems David Buchla | Thomas Kissell | Thomas Floyd Copyright © 2015 by Pearson Education, Inc. All Rights Reserved Buchla, Kissell,
SEC598F16 Photovoltaic Systems Engineering Session 12 PV System Components Inverters Balance of Systems (BOS) October 04, 2016.
DOUBLE INPUT Z-SOURCE DC-DC CONVERTER
National Conference on Recent Trends in Power Engineering
DOUBLE INPUT Z-SOURCE DC-DC CONVERTER
POWER ELECTRONICS & ITS APPLICATION
Date of download: 10/21/2017 Copyright © ASME. All rights reserved.
Photovoltaic Systems Engineering Electronic Control Devices (ECDs)
PROBLEM DEFINITION: In general, various single-input single-output dc–dc converters with different voltage gains are combined to satisfy the requirement.
Photovoltaic Systems Engineering Session 15 Stand-Alone PV Systems
At National Institute of Technology, Meghalaya, Shillong, India
Photovoltaic Systems Engineering Session 21
Photovoltaic Systems Engineering Session 22 Solar+Storage Systems
Photovoltaic Systems Engineering Stand-Alone PV Systems – Review
What is MPPT and why it is needed? (Maximum power point tracking)
By: Raed Wa’el Ennab & Raja Sa’ed Anabtawi
Photovoltaic Systems Engineering Session 19
SELF-SUSTAINABLE SOLAR STREET LIGHT CHARGING
DESIGN AND SIMULATION OF GRID CONNECTED
Graduation Project-II submitted to:
Peak-Power Operation In Solar PV
Photovoltaic Systems Engineering Residential Scale – Part 2
Dr. Unnikrishnan P.C. Professor, EEE
Department of Electrical Engineering
Photovoltaic (PV) Systems
Vibration Energy Harvesting Circuit to Power Wireless Sensor Nodes
Power Electronic Drives - DC to AC converter / Inverter
Photovoltaic Systems Engineering Session 10
Photovoltaic Systems Engineering Session 11
Photovoltaic Systems Engineering Session 16 Solar+Storage Systems
Photovoltaic Systems Engineering Session 12
DC-DC Switch-Mode Converters
Regulating Battery Charging
Photovoltaic Systems Engineering Residential Scale – Part 2
Photovoltaic Systems Engineering Session 19 Solar+Storage Systems
Photovoltaic Systems Engineering Session 19a Solar+Storage Systems
Solar Energy Commercialization Utility Scale Solar Development
Chris Leonard and Baylor Howard Advisor: Dr. Jing Wang
Presentation transcript:

Photovoltaic Systems Engineering Electronic Control Devices (ECDs) SEC598F17 Photovoltaic Systems Engineering Session 14 Electronic Control Devices (ECDs) Charge Controllers Inverters October 05, 2017

Session 13 content Charge Controllers Inverters Purpose, utility Operation, reliability, failure mechanisms

Learning Outcomes Introduction to the power electronics used in PV systems Recognition of the importance of controllers and inverters to the operation of certain PV systems

PV Systems – Charge Controllers Pulse Width Modulation (PWM) – Duty Cycle Vm v(t) Vavg ton toff time

PV Systems – Charge Controllers Pulse Width Modulation (PWM) – Duty Cycle

PV Systems – Charge Controllers Pulse Width Modulation (PWM) – Duty Cycle

PV Systems – DC-DC converters Boost converter The transfer characteristic is: en.wikipedia.org/wiki/Boost_converter

PV Systems – DC-DC converters Boost converter ON OFF

PV Systems – DC-DC converters Buck converter The transfer characteristic is: en.wikipedia.org/wiki/Buck_converter

PV Systems – DC-DC converters Buck converter

PV Systems – DC-DC converters Buck-Boost converter The transfer characteristic is: en.wikipedia.org/wiki/Buckboost_converter

PV Systems – DC-DC converters Buck-Boost converter

PV Systems – DC-DC converters Summary Boost Converter Buck Converter Buck-boost Converter

PV Systems – DC-DC converters Summary Boost Converter Toyota Prius LED Lamps Buck Converter Impedance matching Charge controllers Buck-boost Converter

PV Systems – Charge Controllers 12V, 24V, 48V 45A, 70A, 100A 1600W, 3200W www.morningstar.com

PV Systems – Charge Controllers Charge controller block diagram Isolation of PV array and battery Protection from overcharging Protection from deep discharging www.morningstar.com

PV Systems – Charge Controllers Charge controller operation www.morningstar.com

PV Systems - Maximum Power Point Tracking The PV system produces electrical power and is best utilized when the maximum power produced can be fully delivered to the electrical “load” – this can only happen when the power source and the power load “match” C.S.Solanki, Solar Photovoltaic Technology and Systems

PV Systems - MPPT Other representative electrical loads

PV Systems - MPPT An approach to assuring a better match is the use of Maximum Power Point Tracking (MPPT) – an electronic technique that moves the operating point along the maximum power hyperbola (I*V = constant) associated with the PV array until it intersects the electronic load IV characteristic

PV Systems - MPPT IMPPT Imp VMPPT Vmp

PV Systems - MPPT Imp IMPPT MPPT Vmp VMPPT

PV Systems - MPPT Perturb and Observe PV operating points from P&O algorithm N.Fermia et al., Power Electronics and Control Techniques for Maximum Harvesting in PV Systems

PV Systems - MPPT Perturb and Observe Time domain behavior N.Fermia et al., Power Electronics and Control Techniques for Maximum Harvesting in PV Systems

PV Systems - MPPT Perturb and Observe P&O flowchart

PV Systems - MPPT Perturb and Observe N.Fermia et al., Power Electronics and Control Techniques for Maximum Harvesting in PV Systems

PV Systems - Inverters The inverter is the essential electronic system that converts the DC electrical output from the PV array into the AC electrical input for the residence, national electrical grid, and so on INVERTER DC input AC output

PV Systems - Inverters Heart of the inverter – the “H-bridge”

PV Systems - Inverters The H-bridge in operation

PV Systems - Inverters The output of the inverter is controlled by pulse width modulation (PWM)

PV Systems - Inverters State of the Art Inverters: High efficiency – 98% or higher Dual independent MPPT systems Integrated DC disconnect and combiner inputs No fans or electrolytic capacitors

PV Systems - Inverters J.M.Jacob, Power Electronics: Principles and Applications

Feedback: Privacy Policy Feedback
Do Not Sell My Personal Information
About project: SlidePlayer Terms of Service

© 2025 SlidePlayer.com. Inc. All rights reserved.