Renewable Energy Engineering Module PDF

Summary

This document discusses renewable energy, focusing on solar energy and nuclear power. It explains different solar technologies and the principles behind nuclear fission. The text also touches on the importance of renewable resources in the context of climate change.

Full Transcript

INTERNATIONAL & ACCESS
FOUNDATION PROGRAMMES
ENGINEERING MODULE - SEMESTER I
ELECTRONIC & ELECTRICAL ENGINEERING

PART 11
RENEWABLE ENERGY
Dr Nevan Bermingham
THE NEED FOR RENEWABLE ENERGY

All fossil fuel reserve and consumption data from CIA World
THE NEED FOR RENEWABLE ENERGY

http://climate.nasa.gov/evidence/.
THE NEED FOR RENEWABLE ENERGY
CLIMATE CHANGE
Climate change is a reality.
“Global Warming” is not an entirely accurate term
– but sea and air temperatures are rising and that
energy manifests itself in erratic and extreme
climate changes.
The data is clear – the climate is changing and it
will impact on our species - conspiracy theories
and science denials do nothing to fix the issue
There is a very strong correlation with human
activity, but its more difficult to prove causality
Technology is the key to solving this issue
THE NEED FOR RENEWABLE ENERGY
Global sea level rose about 17cm in the last
century.
The rate in the last decade is nearly double that of the
last century.
Earth has warmed since 1880.
Most of this warming has occurred since the 1970’s
20 warmest years having occurred since 1981 and with
all 10 of the warmest years occurring in the past 12
years
Both the extent and thickness of Arctic sea ice has
declined rapidly over the last several decades
Increasing numbers of intense rainfall (storms)
since 1950
GLOBAL LAND-OCEAN TEMPERATURE INDEX
DATA SOURCE: NASA'S GODDARD INSTITUTE FOR SPACE STUDIES
HUMAN ACTIVITY DRIVING CLIMATE
CHANGE
DATA SOURCE: CLIMATE CHANGE 2021: THE PHYSICAL SCIENCE BASIS (PDF). CONTRIBUTION OF WORKING GROUP TO
THE SIXTH ASSESSMENT REPORT OF THE INTERGOVERNMENTAL PANEL ON CLIMATE CHANGE
HUMAN ACTIVITY DRIVING CLIMATE
CHANGE
DATA SOURCE: THE GLOBAL CARBON PROJECT
THE
IMPACT
OF
WARMIN
G
DATA SOURCE:
BASED ON CMIP6 MULTI-
MODEL MEAN CHANGES.
THE
IMPACT
OF
WARMING
DATA SOURCE:
U.S. GLOBAL CHANGE
RESEARCH PROGRAM
2017
THE IMPACT OF WARMING
DATA SOURCE: "CHAPTER 19: EMERGENT RISKS AND KEY VULNERABILITIES" (PDF). IPCC AR5 WG2 A
2014. PP. 1039–1099.
THE CLIMATE CHANGE PERFORMANCE INDEX RANKS
COUNTRIES BY GREENHOUSE GAS EMISSIONS
(40% OF SCORE), RENEWABLE ENERGY (20%), ENERGY USE (20%), AND CLIMATE POLICY (20%).
THE NEED FOR RENEWABLE ENERGY
Over 95% of actively publishing climate
scientists agree that the earth is warming and
that human activity is the cause.
Debate is over the causes, not the evidence
itself – i.e. the data shows a massive change
in climate.
Renewable Energy is about sustainable
sources and reducing the carbon emissions
(and greenhouse gasses)
Energy Independence is important for small
countries like Ireland
SOLAR ENERGY & SOLAR PANELS
A FEW FACTS (USA)
Every day the earth receives thousands of times
more energy from the sun than is consumed in all
other resources.
If a 140x140 mile parcel of land in Arizona was
covered with solar cells, the electricity needs of the
entire United States could be met.
The sunlight falling on a typical house can provide
from 1/3 to 1/2 of the heating needs of that house.
Today solar energy accounts for only 1% of the total
renewable energy consumed in the United States
CHARACTERISTICS OF ISOLATION
Isolation is the amount of
solar radiation reaching the
earth. Also called Incident
Solar Radiation.
The sun’s energy is created
from the fusion of hydrogen
nuclei into helium nuclei.
Components of Solar
Radiation:
 Direct radiation
 Diffuse radiation
 Reflect radiation
FLAT PLATE COLLECTORS
A thin flat metal plate
is used to absorb the
sun’s radiation.
Tubes carry water into
the absorber plate
where it is heated by
the sun and sent to a
pump or fan into
storage and
distributed from there
to the living space.
PHOTOVOLTAIC (PV) CELLS
Conversion Efficiency – the percentage of
solar energy shining on a device that is
converted into electrical energy
Typical Efficiencies
Single Crystalline Silicon = 14%
Thin Film = 7%
Innovators at NASA's Glenn Research Center have
developed a high efficiency multi-junction solar cell that
uses a thin interlayer of selenium as the bonding
material between wafers.
Selenium is a unique semiconductor in that its
transparent to light at photon energies below the band
gap (infrared), enabling light to pass from the multi-
junction top cell to the silicon-based bottom cell = 40%
Efficiencies.
PHOTOVOLTAIC CELLS
 SINGLE-CRYSTAL SILICON CELL
CONSTRUCTION
The majority of PV cells in use are the single-crystal
silicon type.
Silica (SiO2) is the compound used to make the cells. It
is first refined and purified, then melted down and re-
solidified so that it can be arranged in perfect wafers
for electric conduction. These wafers are very thin.
The wafers are doped with either a negative type layer
or a positive type layer respectively. Used together
these two types treated of crystalline silicon form the
p-n junction which is the heart of the solar– electrical
reaction.
Many of these types of cells are joined together to
make arrays, the size of each array is dependent upon
the amount of sunlight in a given area.
HOW DOES A CELL BECOME A
MODULE?
A solar cell is the basic building
block of a PV system.
A typical cell produces.5 to 1V
of electricity.
Solar cells are combined
together to become modules or
if large enough, known as an
array.
A structure to point the modules
towards the sun is necessary, as
well as electricity converters,
which convert DC power to AC.
All of these components allow
the system to power a water
pump, appliances, commercial
sites, or even a whole
community.
THE PHOTOELECTRIC EFFECT

The photoelectric effect
relies on the principle
that whenever light
strikes the surface of
certain metals electrons
are released.
In the p-n junction the n-
type wafer treated with
phosphorus has extra
electrons which flow into
the holes in the p-type
layer that has been
treated with boron.
Connected by an external
circuit electrons flow
from the n-side to create
electricity and end up in
the p-side.
SOLAR CELLS
SOLAR CELL P-N JUNCTION.
PHOTOELECTRIC EFFECT
MODERN MATERIALS
Photovoltaic materials used in thin film technology
include:

Amorphous Silicon - amorphous (non-
crystalline) silicon was used in the first thin film
to be developed, suffers from low efficiency
levels and high production costs.
P-TYPE LAYER: Cadmium Telluride - has
potential problems with the high toxicity of
Cadmium and the limited availability (at present)
of Tellurium. This method is in current use, with
the thin film encapsulated in glass, which will
seal in the Cadmium in the event of a fire.
N-TYPE LAYER Cadmium Sulphide or Copper
https://www.youtube.com/watch?v=1gta2I
IN THE HOME
Solar cells produce direct current (DC), therefore they are only
used for DC equipment.
If alternating current (AC) is needed for AC equipment or backup
energy is needed, solar photovoltaic systems require other
components in addition to solar modules.
IN THE HOME

The components of a solar photovoltaic
system are:
Solar Module is the essential component of any
solar PV system that converts sunlight directly into
DC electricity.
Solar Charge Controller regulates voltage and
current from solar arrays, charges the battery,
prevents battery from overcharging and also
performs controlled over discharges.
Battery stores current electricity that produces from
solar arrays for using when sunlight is not visible,
night-time or other purposes.
Inverter converts DC power output of solar arrays
into AC for AC appliances.
 PROS AND CONS OF SOLAR
ELECTRICITY
Expensive to produce because of the high cost of semi-
conducting materials, which could be avoided by reducing
manufacturing costs. The PV Manufacturing Research and
Development Project focuses on increasing manufacturing
capacity so that the cost of manufacturing will decrease. They
aim to achieve break even costs.
However, solar energy contributes positively to the nation’s
energy security because it is produced domestically, reducing
reliance on energy imports.
The industry is still relatively new and extremely hi tech
allowing for the creation of more jobs in the American market.
The government has many incentives programs to encourage
investment in forms of alternative energy.
Does not require the transportation of hazardous materials
across country.
Sunlight is a free abundant source!
 PROS AND CONS (CONT.)

PV can be designed for a variety of
applications
No noise or air pollution
Require minimal maintenance and have
long service life.
Power can be either centralized in
individual homes or distributed by
electrical companies.
NUCLEAR FUSION AND FISSION

 Nuclear Fission
 Nuclear Fusion
Large nuclei into
Small nuclei into
small
large
Critical mass to
Immense
sustain
temperature and
pressure Two isotopes we
235 239
Core of stars U
use Pu

Iron is the “dead end” of both fusion
and fission – it is the lowest energy
nucleus and cannot be split or fused.
NUCLEAR ENERGY – NATURAL URANIUM
atomic number:
The number of protons
in an atom.

atomic weight/mass:
The average mass of
an atom, taking into
account all its
naturally occurring
isotopes.

The sum of the
number of protons
and the number of
neutrons in an atom
URANIUM 235 ISOTOPE

Uranium-235 (235U) is
an isotope of uranium
making up about
0.72% of naturally
occouring uranium.

Unlike the predominant
isotope uranium-238, it
is fissile, i.e., it can
sustain a fission chain
reaction.

It is the only fissile
isotope that is
primordial and found in
relatively significant
quantities in nature.
NUCLEAR ENERGY - FISSION

Chain Reaction
ANATOMY OF A NUCLEAR POWER PLANT

Source: NRC
FUEL PROCESSING
U235

Source: NRC
NUCLEAR ENERGY - FISSION
NUCLEA
R
ENERGY
–
FISSION
In reality what a
reactor core looks
like
ANATOMY OF A NUCLEAR POWER PLANT
Fuel: The fissionable material used in the reactor is called as fuel. The commonly
used fuels are Uranium, Plutonium or Thorium. It can be U-235, U-238, Pu-236 or
Th-232. Uranium is mostly preferred as it has high melting point.

Moderators: Only neutrons of a fairly low speed should be used to have
controlled chain reaction. To slow down the speed fast moving neutrons produced
during the fission process, moderators are used. Moderator reduces the speed of
the neutron by absorbing its energy but not absorb neutron. Graphite, Heavy
water and Beryllium are common moderators.

Control Rods: These rods absorb neutrons and stop the chain reaction to
proceed further. These are made up of steel containing a high percentage of
material like cadmium or boron which can absorb neutrons. When control rods are
completely inserted into the moderator block then all the neutrons is absorbed and
reaction comes to halt.

Source: NRC
ANATOMY OF A NUCLEAR POWER PLANT
Shielding: Shielding prevents radiations to reach outside the reactor. Lead blocks
and concrete enclosure that is strong enough of several meters thickness are
used for shielding.

Coolant: The coolant is substance in a pipe to the steam generator where water
is boiled. This is where heat-exchange process occurs. Heat is absorbed by the
coolant that is produced in the reactor. Typical coolants are water, carbon dioxide
gas or liquid sodium.

Turbines: Steam produced in the boiler is now passes to a turbine. The force of
the steam jet causes the turbine to rotate. Heat energy (steam) is converted to
mechanical energy (moving turbine).

Generator: The generator consists of coils that change the mechanical energy
into electric energy. The turbine moves and the change in magnetic flux cause
electricity. This is transmitted to substations for distribution of
electric power. Source: NRC
CAPACITY FACTOR (POWER GENERATION)
CAPACITY FACTOR (RENEWABLE SOURCES)
 GLOBAL TOTAL PRIMARY ENERGY SUPPLY, 2012
Nuclear provides about 10.8% of global electricity generation.

Natural Gas Coal
21.27% 29.01%

Petroleum Nuclear
31.45% 4.80%
Hydropowe
r
2.36%
Geothermal
Biofuels , Solar, etc.
and Waste 1.06%
Data: International Energy Agency 10.05%
 TOP 10 NUCLEAR GENERATING
COUNTRIES, 2013
800

700

600
Billion kiloWatt-hours

500

400

300

200

100

0
s ce ia y
e s th ina da an ine o m en
at a n
us o u h a a
gd
d
t
Fr S C an m kr
e
d
S R
a, C er U K
in S
w
e G
te or d
ni K te
U ni
U
Data: Energy Information Administration
 U.S. ELECTRICITY PRODUCTION 2013
Geotherma
Petroleum l
0.41% Solar
0.66% 0.23%
Hydroelectric Other
6.52% 0.61%
Nuclear
19.44% Biomass
1.48%
Wind
4.13%

Coal
Natural 39.08%
Gas
27.44%

Data provided by US EIA Net Generation by Energy Source

The NEED Project
 GLOBAL ELECTRICITY PRODUCTION
"GLOBAL CARBON BUDGET 2019". EARTH SYSTEM SCIENCE DATA

Data provided by US EIA Net Generation by Energy Source
NUCLEAR ENERGY PRODUCTION

Percent Electricity Generated
by Nuclear Power
VT 73.76% MN 20.52%
NH 56.72% NE 20.06%
SC 56.07% MS 19.91%
NJ 51.15% AR 18.38%
IL 49.16% WI 18.32%
CT 47.29% LA 16.40%
VA 41.46% KS 16.14%
MD 37.73% OH 12.43%
TN 36.66% FL 12.00%
PA 35.23% MA 11.96%
NC 34.49% IA 9.39%
NY 32.97% MO 9.11%
AZ 28.34% CA 8.98%
GA 26.90% TX 8.91%
MI 26.74% WA 7.24%
AL 26.70%

Data: Nuclear Energy Institute
ADVANTAGES & DISADVANTAGES OF NUCLEAR POWER

 Clean
  Initial construction
Plentiful Supply
costs
 High energy content in
 Radioactive waste
uranium
byproduct
Small fuel pellet
 Storage
Can provide base load
power  Natural disasters
Energy savings in  Public perception
transportation
 Operating cost is low after
construction

The NEED Project
NEW (FISSION) NUCLEAR TECHNOLOGIES

 Breeder reactors are a
type of nuclear reactor
which produce more fissile
materials than they
consume.
 They are designed to
extend the nuclear fuel
supply for the generation
of electricity
 Mistakenly called a
potential renewable
energy source, but
Breeder Reactors have the
ability to make nuclear
fuels quite sustainable
Image courtesy of Department of Energy

The NEED Project
BREEDER REACTOR

Image courtesy of Department of Energy
FUSION REACTORS (THEORETICAL)
TOKAMAK FUSION DEVICES
 FUSION REACTORS (THEORETICAL)

Wendelstein 7-X (W7-X) reactor
An experimental stellarator (nuclear fusion
reactor) built in Greifswald, Germany, by the Max
Planck Institute of Plasma Physics 2015

National Ignition Facility (NIF)
Reactor
NIF uses lasers to heat and compress
a small amount of hydrogen fuel with
the goal of inducing nuclear fusion
reactions.
It rapidly collapses a small amount of
fuel so the pressure and temperature
reach fusion-relevant conditions. NIF
does this by heating the outer layer
of a small plastic sphere with the
 FUSION REACTORS (THEORETICAL)

MIT Sparc Reactor

The Sparc reactor proposed by MIT isn’t
dramatically different than other tokamak
fusion devices from previous experiments. It
starts with deuterium and tritium, both isotopes
of hydrogen.
When heated to high temperatures, it forms a
plasma that the reactor confines within a
magnetic field encircling the toroidal chamber
of the reactor.
The high heat and pressure cause some of the
atoms to undergo fusion and release energy.

https://www.extremetech.com/extreme/280265-mit-plans-new-fusion-
reactor-that-could-actually-generate-power
OTHER FORMS OF RENEWAL ENERGY

Wind Energy
Tidal Energy
Hydroelectric Energy
Geothermal
WIND ENERGY
HYDROELECTRIC
TIDAL
NEW TECHNOLOGIES….
THE ORBITAL O2

Electricity to meet
the demand of
around 2,000 UK
homes – 2 Mega
Watts of Power
Generation from the
Tides
GEOTHERMAL
 Clean (mostly releases water
vapor)
Renewable (core heat is mostly
from decay
of radioactive isotopes, such as
potassium-40 and thorium-232)

Can release hydrogen
sulfide and carbon
dioxide
In certain areas, drilling
is needed (large set up
costs)
Can “dry up” over time.
Shown to cause “Micro-
Quakes”
ANY QUESTIONS?