Lecture 16 Solar PV Systems PDF

Summary

This document is a lecture on solar PV systems, detailing the components and functions of a solar power system. It explains different types of photovoltaic systems and their applications, along with necessary components like solar panels, batteries, inverters, and controllers. The lecture is intended for an undergraduate audience and will cover useful components for a solar system and important safety considerations relevant for renewable energy production.

Full Transcript

Matthew 21:22.
If you believe, you will receive whatever you ask
for in prayer.”
Matthew 7:7-8.
“Ask and it will be given to you; seek and you will
find; knock and the door will be opened to
you. For everyone who asks receives; the one
who seeks finds; and to the one who knocks, the
door will be opened.
 ENVS3200:ENERGY
TECHNOLOGY.
Lecture 16: Solar PV Systems

Lecturer: Mr. Buya Morgen.
Semester II, 2024 MSc
Objective.

To learn the primary
components of a fully
functioning solar PV
system and their specific
functions.
Solar PV Systems
What are the various
components required
to construct a working
solar PV system?
A fully functional solar
PV (Photovoltaic)
system requires
several key
components to
generate, convert,
store, and distribute
solar electricity
effectively.
 Simple PV System.
Use a PV module to power a 12V DC
light bulb - Simple
Use a PV Module to charge a12V
battery – complex
The battery can then be used to power
the light when sun is not shining.
A charge controller prevents overcharging
battery.
Overcharging the battery can create hydrogen
gas which is explosive and dangerous.
Battery powers the light bulb.
Fuse protects the battery.
 Small PV System Components
Typical Components for a Solar PV
Systems.
Electric meter.
measures electricity
Solar modules and panels. production.
Mounting Structure/Racking
System
Wiring and Electrical
Batteries. Accessories.
Charge Controller/Battery Bank. Connects system
Inverter. components.

Disconnect Switches.
On/Off Switch for PV system.
Functions

Solar PV Panels (Modules)
Convert sunlight into direct
current (DC) electricity using the
photovoltaic effect. The solar PV
panels are typically made up of
multiple solar cells that are
connected to form a module.
Types of PV Cells:
Monocrystalline, polycrystalline,
thin-film, and ___.
Functions Roof-Mounted: Panels are
mounted directly on a building's
Mounting Structure/Racking System roof.

Supports and secures the solar panels to
rooftops, ground mounts, or other
structures at the optimal tilt and orientation
to maximize sun exposure.

Tracking System: Mounts that adjust the panel’s orientation
Ground-Mounted: Panels are installed on
to follow the sun’s movement for increased energy capture.
frames or poles anchored to the ground.
Functions
Inverter.
Converts the DC electricity produced by the solar
panels into alternating current (AC) electricity,
which is used by most home appliances and can
be fed into the electrical grid. String Inverter: Connects multiple
solar panels in series (string).
Converts DC to AC Power.

Microinverter: Attached
to each individual panel
for independent
conversion.

Hybrid Inverter: Combines a Central Inverter: Used in large-
standard inverter and a scale solar installations for
battery inverter to manage multiple strings of solar panels
solar and battery storage.
Functions

DC Disconnect Switch
Collects the output from multiple solar
panel strings into a single DC output. It
provides circuit protection with fuses or
breakers and often includes a surge
protection device.
On/Off Switch for PV system.
Mainly used in large installations where
multiple strings of panels need to be
combined.
Functions
AC Disconnect Switch
Allows for the disconnection of
AC power from the inverter to the
main electrical panel or grid.
Typically installed for safety and
required by local utility
companies for grid-tied systems.
Functions
Junction Box.
A protective enclosure where
connections between solar
panels are made.
It houses important
electrical components like
fuses and bypass diodes.
Functions
Combiner Box.
Collects the output from
multiple solar panel strings
into a single DC output.
It provides circuit protection
with fuses or breakers and
often includes a surge
protection device.
Mainly used in large
installations where multiple
strings of panels need to be
combined.
Functions
Battery Bank (for Off Grid or Hybrid Systems)
Stores excess electricity generated by the
solar panels for use when sunlight is not
available (e.g., during the night or cloudy
days).
Flow Batteries: Provide longer discharge times
Store PV-produced electricity. and better scalability.

Lead-Acid Batteries: Economical but
heavier and have shorter lifespans. Lithium-Ion Batteries: Lightweight, higher energy density,
longer lifespan, but more expensive.
Functions
Battery Bank (for Off Grid or Hybrid Systems)
Regulates the voltage and current
coming from the solar panels to
prevent overcharging and protect the
batteries.
Prevents Batteries overcharging.
PWM (Pulse Width Modulation)
Controllers: Suitable for smaller
systems with minimal power loss.
MPPT (Maximum Power Point
Tracking) Controllers: Optimizes the
power output from the panels,
especially under varying sunlight
conditions.
Functions
Metering and Monitoring Systems.
Measures the electricity generated,
consumed, and sent back to the grid.
Monitoring systems also provide data
on the performance of the solar
system, often accessible remotely via
a smartphone or computer.
Functions
Wiring and Electrical Accessories
Transfers electrical current between
different components of the solar PV
system.
Includes solar cables, connectors (MC4
connectors), grounding wires, conduits, and
protective casings to ensure a safe and
efficient flow of electricity.
Functions
Main electrical Panel.
Distributes electricity throughout the
building and connects to the inverter to
utilize solar power in conjunction with grid
electricity.
Houses circuit breakers that control the flow
of electricity to various parts of the home.
Functions
Net Meter – for Grid Tied System.
Measures the electricity fed into the grid
from the solar system and the electricity
consumed from the grid. It allows for net
metering, where excess solar power sent
back to the grid can offset the electricity
consumed from the grid.
Installed by the utility company to track the
bidirectional flow of electricity.
Functions
Fuse/Circuit Breaker
Provides overcurrent protection to prevent
electrical faults and fires by breaking the
circuit when excessive current flows through
it.
Essential safety components used in both
DC and AC circuits of the solar PV system.
Grid Tied Solar PV System
Solar PV system backed up with power from a local utility.
 Off-grid Solar PV Systems

Isolated PV
system not
connected to
local utility grid.
Grid Tied PV System with Battery Backup
Same as off-grid system, but now tied to local utility system
Large Scale Solar PV System
PV System designed to provide electricity to the grid.

Current from PV arrays
combined at collector box
1,500 V (DC)
Inverter (Utility Scale)
Converts DC to AC
Transformer increases AC
to substation voltage.
11kV (AC)
Substations increases AC to
transmission voltage to a far
away city.
138+kV (AC).
Summary –Solar PV Systems
PV system components
Solar modules and panels
Batteries
Charge Controller
Inverter
Electric Current
PV Systems can be
Off grid
Grid tied
Battery Storage
The various components of a solar PV system are designed to work
together to harness solar energy efficiently.
References
https://energyeducation.ca/encyclopedia/Photovoltaic_system#:~
:text=A%20photovoltaic%20(PV)%20system%20is%20composed
%20of%20one%20or%20more
https://www.energy.gov/eere/solar/solar-photovoltaic-technology-
basics#:~:text=Department%20of%20Energy.%20What%20is%20
photovoltaic%20(PV)%20technology%20and%20how
https://solarmagazine.com/solar-power-
systems/#:~:text=PART%201:%20What%20is%20a%20solar%20p
ower%20system?%20The%20term