Wind Energy as an Alternative Energy Source for Australia
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This research paper evaluates wind energy as an alternative source of energy in Australia. It discusses the advantages and disadvantages of renewable and nonrenewable sources of energy, factors affecting wind power output, wind farms in Australia, wind energy storage, and future prospects of wind energy sources in Australia.
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WIND ENERGY AS AN ALTERNATIVE ENERGY SOURCE FOR AUSTRALIA
A Research Paper on Energy By
Student’s Name
Name of the Professor
Institutional Affiliation
City/State
Year/Month/Day
WIND ENERGY AS AN ALTERNATIVE ENERGY SOURCE FOR AUSTRALIA
A Research Paper on Energy By
Student’s Name
Name of the Professor
Institutional Affiliation
City/State
Year/Month/Day
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ABSTRACT
In order to generate sufficient electricity to satisfy the demand within the country, there is
need of increasing the generation but majorly focusing on the renewable sources which are
environmentally friendly. The selected renewable energy option for this research is the wind
energy source as an alternative source of electricity generation in Australia. The hydroelectric
capacity in the country is not fully deployed since the shortage of ground water in the country is
a primary constraint for the further establishment. The growth of wind power energy source is
rapidly increasing in numerous geographical locations within the country, this is the major
reason for selecting the wind energy as an alternative energy source for Australia for this
research.
There have been numerous steps put in place to reduce the emission of carbon dioxide in
the country such as in 2012, there was the establishment of the carbon tax and carbon price so as
to make it more practical for the companies to minimize their emission of carbon dioxide. Some
of the factors that affect the output of wind power generated in Australia include rotor area, wind
velocity, air density, rotation of the earth, the heat from the sun, the cooling effect of the polar
ice caps and oceans, temperature gradient between sea and land, and the physical effects of the
mountains and other obstacles
ABSTRACT
In order to generate sufficient electricity to satisfy the demand within the country, there is
need of increasing the generation but majorly focusing on the renewable sources which are
environmentally friendly. The selected renewable energy option for this research is the wind
energy source as an alternative source of electricity generation in Australia. The hydroelectric
capacity in the country is not fully deployed since the shortage of ground water in the country is
a primary constraint for the further establishment. The growth of wind power energy source is
rapidly increasing in numerous geographical locations within the country, this is the major
reason for selecting the wind energy as an alternative energy source for Australia for this
research.
There have been numerous steps put in place to reduce the emission of carbon dioxide in
the country such as in 2012, there was the establishment of the carbon tax and carbon price so as
to make it more practical for the companies to minimize their emission of carbon dioxide. Some
of the factors that affect the output of wind power generated in Australia include rotor area, wind
velocity, air density, rotation of the earth, the heat from the sun, the cooling effect of the polar
ice caps and oceans, temperature gradient between sea and land, and the physical effects of the
mountains and other obstacles
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ACKNOWLEDGEMENT
I would wish to sincerely thank the important departments and organizations that assisted me
with numerous information which was used in compiling this research paper. These departments
include Transport and Regional Economics, the Bureau of Infrastructure, the Australian Bureau
of Statistics, the Clean Energy Regulator, Department of Environment, Geoscience Australia,
and Innovation and Science.
ACKNOWLEDGEMENT
I would wish to sincerely thank the important departments and organizations that assisted me
with numerous information which was used in compiling this research paper. These departments
include Transport and Regional Economics, the Bureau of Infrastructure, the Australian Bureau
of Statistics, the Clean Energy Regulator, Department of Environment, Geoscience Australia,
and Innovation and Science.
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Contents
ABSTRACT....................................................................................................................................................2
CHAPTER 1...................................................................................................................................................6
INTRODUCTION...........................................................................................................................................6
BACKGROUND.........................................................................................................................................6
RESEARCH OBJECTIVES............................................................................................................................7
CHAPTER 2...................................................................................................................................................7
LITERATURE REVIEW....................................................................................................................................7
Energy System in Australia..........................................................................................................................7
Global Warming and Climate Change in Australia.......................................................................................9
Nonrenewable Energy Sources..................................................................................................................11
Disadvantages of Nonrenewable Energy Sources..................................................................................13
Renewable Energy Sources........................................................................................................................13
Advantages of Renewable Energy Sources............................................................................................15
Disadvantages of Renewable Energy Sources........................................................................................16
CHAPTER 3.................................................................................................................................................18
METHODOLOGY.........................................................................................................................................18
WIND ENERGY IN AUSTRALIA................................................................................................................18
Components of Wind Power.................................................................................................................19
Factors Affecting Wind Power Output...................................................................................................22
Generation of Electricity by Wind Turbines...........................................................................................22
GENERATED WIND ENERGY IN AUSTRALIA................................................................................................24
WIND FARMS IN AUSTRALIA..................................................................................................................25
WIND ENERGY STORAGE...........................................................................................................................28
ADVANTAGES OF WIND ENERGY SOURCES...............................................................................................29
Disadvantages of Wind Energy Sources.................................................................................................31
Future Prospect of Wind Energy Sources in Australia...............................................................................31
PROGRAM OF WORK.................................................................................................................................33
CHAPTER 4.................................................................................................................................................33
CONCLUSION.............................................................................................................................................33
BIBLIOGRAPHY...........................................................................................................................................35
Appendix 1: Price of Electricity..................................................................................................................38
Appendix 2: Levelized Cost of Energy for Different Energy Resources......................................................39
Appendix 3: Wind Power Generation, top 10 countries............................................................................40
Contents
ABSTRACT....................................................................................................................................................2
CHAPTER 1...................................................................................................................................................6
INTRODUCTION...........................................................................................................................................6
BACKGROUND.........................................................................................................................................6
RESEARCH OBJECTIVES............................................................................................................................7
CHAPTER 2...................................................................................................................................................7
LITERATURE REVIEW....................................................................................................................................7
Energy System in Australia..........................................................................................................................7
Global Warming and Climate Change in Australia.......................................................................................9
Nonrenewable Energy Sources..................................................................................................................11
Disadvantages of Nonrenewable Energy Sources..................................................................................13
Renewable Energy Sources........................................................................................................................13
Advantages of Renewable Energy Sources............................................................................................15
Disadvantages of Renewable Energy Sources........................................................................................16
CHAPTER 3.................................................................................................................................................18
METHODOLOGY.........................................................................................................................................18
WIND ENERGY IN AUSTRALIA................................................................................................................18
Components of Wind Power.................................................................................................................19
Factors Affecting Wind Power Output...................................................................................................22
Generation of Electricity by Wind Turbines...........................................................................................22
GENERATED WIND ENERGY IN AUSTRALIA................................................................................................24
WIND FARMS IN AUSTRALIA..................................................................................................................25
WIND ENERGY STORAGE...........................................................................................................................28
ADVANTAGES OF WIND ENERGY SOURCES...............................................................................................29
Disadvantages of Wind Energy Sources.................................................................................................31
Future Prospect of Wind Energy Sources in Australia...............................................................................31
PROGRAM OF WORK.................................................................................................................................33
CHAPTER 4.................................................................................................................................................33
CONCLUSION.............................................................................................................................................33
BIBLIOGRAPHY...........................................................................................................................................35
Appendix 1: Price of Electricity..................................................................................................................38
Appendix 2: Levelized Cost of Energy for Different Energy Resources......................................................39
Appendix 3: Wind Power Generation, top 10 countries............................................................................40
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LIST OF FIGURES
Figure 1: Production and consumption of energy-mix in Australia …………………………… 8
Figure 2: Energy sources distribution in Australia …………………………………………….. 9
Figure 3: Emission of green gas in every sector in Australia ……………………………..….. 11
Figure 4: Electricity generation from renewable energy sources in Australia ……………...... 13
Figure 5: Schematics of a typical wind turbine ………………………………………….…… 21
Figure 6: Wind energy generation in Australia ………………………………………............ 24
Figure 7: Wind generation, wind penetration, rooftop PV, and demand in South Australia….26
Figure 8: Wind Energy installed capacity by Australian states ………………………….…...28
Figure 9: Lithium-ion battery system of wind power storage ………………………………...30
LIST OF FIGURES
Figure 1: Production and consumption of energy-mix in Australia …………………………… 8
Figure 2: Energy sources distribution in Australia …………………………………………….. 9
Figure 3: Emission of green gas in every sector in Australia ……………………………..….. 11
Figure 4: Electricity generation from renewable energy sources in Australia ……………...... 13
Figure 5: Schematics of a typical wind turbine ………………………………………….…… 21
Figure 6: Wind energy generation in Australia ………………………………………............ 24
Figure 7: Wind generation, wind penetration, rooftop PV, and demand in South Australia….26
Figure 8: Wind Energy installed capacity by Australian states ………………………….…...28
Figure 9: Lithium-ion battery system of wind power storage ………………………………...30
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CHAPTER 1
INTRODUCTION
BACKGROUND
Electricity has become one of the basic human wants in the current society. The demand
for electricity by the consumers is increasing on a daily basis due to the increase in the number of
electrical devices and also the rise in the number of people who are potential consumers of
electricity. The distribution, transmission, and generation of electricity have been researched on
by numerous researchers. The rise in the electricity generation by sources that are non-renewable
has degraded the environment resulting to the government resolving to the use of renewable
energy sources for the generation of electricity. The major reason for the selection of this
research topic of the renewable energy sources is due to the worsening of the climatic conditions
as well as the global environment without serious considerations being taken regarding the
alternative sources of electricity.
There is currently a crisis in the supply of sufficient and reliable electric energy in
Australia and also other countries. In order to generate sufficient electricity to satisfy the demand
within the country, there is need of increasing the generation but majorly focusing on the
renewable sources with are environmentally friendly. The selected renewable energy option for
this research is the wind energy source as an alternative source of electricity generation in
Australia. There have been numerous research done regarding the renewable sources of energy in
Australia, however, the most effective and beneficial solutions is to move towards the renewable
energy sources and stop electricity generation from non-renewable sources of energy. The
energy crisis in the country can be solved by switching to solar energy source as the primary
source of energy and the wind energy source as an alternative energy source (APAIS, 2009).
CHAPTER 1
INTRODUCTION
BACKGROUND
Electricity has become one of the basic human wants in the current society. The demand
for electricity by the consumers is increasing on a daily basis due to the increase in the number of
electrical devices and also the rise in the number of people who are potential consumers of
electricity. The distribution, transmission, and generation of electricity have been researched on
by numerous researchers. The rise in the electricity generation by sources that are non-renewable
has degraded the environment resulting to the government resolving to the use of renewable
energy sources for the generation of electricity. The major reason for the selection of this
research topic of the renewable energy sources is due to the worsening of the climatic conditions
as well as the global environment without serious considerations being taken regarding the
alternative sources of electricity.
There is currently a crisis in the supply of sufficient and reliable electric energy in
Australia and also other countries. In order to generate sufficient electricity to satisfy the demand
within the country, there is need of increasing the generation but majorly focusing on the
renewable sources with are environmentally friendly. The selected renewable energy option for
this research is the wind energy source as an alternative source of electricity generation in
Australia. There have been numerous research done regarding the renewable sources of energy in
Australia, however, the most effective and beneficial solutions is to move towards the renewable
energy sources and stop electricity generation from non-renewable sources of energy. The
energy crisis in the country can be solved by switching to solar energy source as the primary
source of energy and the wind energy source as an alternative energy source (APAIS, 2009).
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RESEARCH OBJECTIVES
The major objective of this research paper is to evaluate the wind energy as an alternative source
of energy in Australia. The other objectives of this research include:
To create awareness among people regarding the advantages and disadvantages of the use
of renewable and nonrenewable sources of energy in the generation of electricity.
To attain an eco-friendly electricity generation units
To solve the energy crisis in Australia and other countries
To gain advantage using the price reduction of renewable energy production cost
To reduce the emission of greenhouse gases through nonrenewable energy sources that
are currently changing the environmental weather conditions (Acton, 2013).
CHAPTER 2
LITERATURE REVIEW
Energy System in Australia
Australia energy consumption and production majorly depends on the fossil fuels and the
country is one of the largest contributors to emission of carbon dioxide in the whole world. The
crude oil and coal have dominated the energy market of the country in the past decade. The
renewable sources only make up to 2% of the total primary production of energy whereas coal
dominated the production of energy with 61% of the total generation and crude oil accounted for
only 6% of the total energy generated between the period of 2009 and 2010 (Ahmed, 2011). The
figure below shows the production and consumption of energy-mix in the country:
RESEARCH OBJECTIVES
The major objective of this research paper is to evaluate the wind energy as an alternative source
of energy in Australia. The other objectives of this research include:
To create awareness among people regarding the advantages and disadvantages of the use
of renewable and nonrenewable sources of energy in the generation of electricity.
To attain an eco-friendly electricity generation units
To solve the energy crisis in Australia and other countries
To gain advantage using the price reduction of renewable energy production cost
To reduce the emission of greenhouse gases through nonrenewable energy sources that
are currently changing the environmental weather conditions (Acton, 2013).
CHAPTER 2
LITERATURE REVIEW
Energy System in Australia
Australia energy consumption and production majorly depends on the fossil fuels and the
country is one of the largest contributors to emission of carbon dioxide in the whole world. The
crude oil and coal have dominated the energy market of the country in the past decade. The
renewable sources only make up to 2% of the total primary production of energy whereas coal
dominated the production of energy with 61% of the total generation and crude oil accounted for
only 6% of the total energy generated between the period of 2009 and 2010 (Ahmed, 2011). The
figure below shows the production and consumption of energy-mix in the country:
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Figure 1: Production and consumption of energy-mix in Australia (Apostol, 2016)
The composition of consumed energy in the country is different from the generated
energy since more than to thirds of the energy generated in the country is exported. The country
has greatly established the use of wind energy and hydroelectric energy sources. However, the
potential of other renewable energy sources such as geothermal, tidal, wave, and solar have been
proved high since their technologies are still not well established. In case the economic and
technological issues are overcome, then these energy sources may be used as alternative source
of electricity to assist the country minimize the emissions of greenhouse gases (Baldick, 2017).
The shift towards renewable energy sources will require the expansion of infrastructure since
majority of the energy is consumed on the Australian east coast as shown in the figure below:
Figure 1: Production and consumption of energy-mix in Australia (Apostol, 2016)
The composition of consumed energy in the country is different from the generated
energy since more than to thirds of the energy generated in the country is exported. The country
has greatly established the use of wind energy and hydroelectric energy sources. However, the
potential of other renewable energy sources such as geothermal, tidal, wave, and solar have been
proved high since their technologies are still not well established. In case the economic and
technological issues are overcome, then these energy sources may be used as alternative source
of electricity to assist the country minimize the emissions of greenhouse gases (Baldick, 2017).
The shift towards renewable energy sources will require the expansion of infrastructure since
majority of the energy is consumed on the Australian east coast as shown in the figure below:
Wind Energy 9
Figure 2: Energy sources distribution in Australia (Apostol, 2016)
A huge part of the renewable energy generation is based on the hydroelectric energy
source. However, the hydroelectric capacity in the country is not fully deployed since the
shortage of ground water in the country is a primary constraint for further establishment. The
growth of in wind power energy source is rapidly increasing in numerous geographical locations
within the country, this is the major reason for selection of wind energy as an alternative energy
source for Australia. From the figure above, it is clear that the wind power source has potential
along the southern coast and also the inland regions. Solar energy source has also potential in the
country since the radiation in majority of the state are considered among the highest level of
radiation globally (Boxwell, 2010).
Huge plants of solar power are still not fully developed and the energy sources are
currently used by the residential small-scale and off-grid installations. Tidal and wave energy
sources are still under the stage of research but are believed to the future energy sources for the
production of energy. Australia is one of the largest energy consumers globally and is ranked in
the 8th position in the worlds largest energy consumers. The rate of growth in energy
consumption has however slowed gradually in the past decade. This decline in the amount of
energy consumed in the country can be explained by the economic crises and oil price shocks
during the past few years. The demand for energy is expected to continue increasing and the
future distribution of these energy sources will be determined by numerous factors such as
energy price and government policies (Brewer, 2013).
Global Warming and Climate Change in Australia
Figure 2: Energy sources distribution in Australia (Apostol, 2016)
A huge part of the renewable energy generation is based on the hydroelectric energy
source. However, the hydroelectric capacity in the country is not fully deployed since the
shortage of ground water in the country is a primary constraint for further establishment. The
growth of in wind power energy source is rapidly increasing in numerous geographical locations
within the country, this is the major reason for selection of wind energy as an alternative energy
source for Australia. From the figure above, it is clear that the wind power source has potential
along the southern coast and also the inland regions. Solar energy source has also potential in the
country since the radiation in majority of the state are considered among the highest level of
radiation globally (Boxwell, 2010).
Huge plants of solar power are still not fully developed and the energy sources are
currently used by the residential small-scale and off-grid installations. Tidal and wave energy
sources are still under the stage of research but are believed to the future energy sources for the
production of energy. Australia is one of the largest energy consumers globally and is ranked in
the 8th position in the worlds largest energy consumers. The rate of growth in energy
consumption has however slowed gradually in the past decade. This decline in the amount of
energy consumed in the country can be explained by the economic crises and oil price shocks
during the past few years. The demand for energy is expected to continue increasing and the
future distribution of these energy sources will be determined by numerous factors such as
energy price and government policies (Brewer, 2013).
Global Warming and Climate Change in Australia
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Global warming and climate change are blamed for the increased number of natural
disasters, rising of sea levels, and extinction of species. These two factors have also impacted the
global economy negatively since it will be expensive to minimize the costs of global warming
causes in the future. In Australia, the changes in climatic conditions will lead to more frequent
dry seasons in some sections of the country. Since the dry seasons are already a major problem in
the country, the future may be devastating for these regions as the risk for huge bushfires will be
high. The climate change will also result in the risk of tropical cyclones. The general weather
will be more extreme and difficult to predict (Brown, 2015).
Figure 3: Emission of green gas in every sector in Australia (Chambers, 2010)
There have been numerous steps put in place to reduce the emission of carbon dioxide
such as in 2012, there was the establishment of the carbon tax and carbon price so as to make it
more practical for the companies to minimize their emission of carbon dioxide. The average
price of electricity has increased after the implementation of the carbon price. The increased
price is anticipated to benefit the establishment of energy generation from renewable energy
sources (Chambers, 2011). The government has also established the Renewable Energy Target
which denotes that 20% of the generated electricity should come from renewable energy sources
Global warming and climate change are blamed for the increased number of natural
disasters, rising of sea levels, and extinction of species. These two factors have also impacted the
global economy negatively since it will be expensive to minimize the costs of global warming
causes in the future. In Australia, the changes in climatic conditions will lead to more frequent
dry seasons in some sections of the country. Since the dry seasons are already a major problem in
the country, the future may be devastating for these regions as the risk for huge bushfires will be
high. The climate change will also result in the risk of tropical cyclones. The general weather
will be more extreme and difficult to predict (Brown, 2015).
Figure 3: Emission of green gas in every sector in Australia (Chambers, 2010)
There have been numerous steps put in place to reduce the emission of carbon dioxide
such as in 2012, there was the establishment of the carbon tax and carbon price so as to make it
more practical for the companies to minimize their emission of carbon dioxide. The average
price of electricity has increased after the implementation of the carbon price. The increased
price is anticipated to benefit the establishment of energy generation from renewable energy
sources (Chambers, 2011). The government has also established the Renewable Energy Target
which denotes that 20% of the generated electricity should come from renewable energy sources
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by 2020. The aim of this initiative is to speed up the transition towards a cleaner supply of
electricity within the country. The energy sector accounts for a huge part of the total emission of
greenhouse gases in the country and also the emission from the generation of electricity has
continuously increased at a faster rate compared to other sectors in the country as shown in
figure 3 above (Chandra, 2009).
Nonrenewable Energy Sources
The production of electricity has normally been through non-renewable sources from the
past decade. The non-renewable sources are known for their environmental degradation
specifically in terms of melting of glaciers, depletion of ozone layer, or change in the climatic
conditions. There has been depletion of the ozone layer as a result of greenhouse gases in the
atmosphere which is released during the generation of electricity by nonrenewable sources of
energy. There are changes in the climatic condition in the whole world and the prediction of the
environmental condition has always been characterized by inaccuracies (Council, 2009). The
nonrenewable source can be defined as those sources that do not renew themselves as a
satisfactory rate for sustainable economic extraction. Some of the non-renewable sources of
energy in Australia include:
Uranium: Australia has more than a third of the total world economy of uranium resources. The
major deposits of Uranium are in Western Australia, Northern Territory, and South Australia.
The production of Uranium in Australia is majorly for the purposes of exportation.
Crude Oil: The major sources of crude oil in Australia is located in Gippsland and Carnarvon. It
takes numerous years for these resources to form naturally and cannot be replaced after
by 2020. The aim of this initiative is to speed up the transition towards a cleaner supply of
electricity within the country. The energy sector accounts for a huge part of the total emission of
greenhouse gases in the country and also the emission from the generation of electricity has
continuously increased at a faster rate compared to other sectors in the country as shown in
figure 3 above (Chandra, 2009).
Nonrenewable Energy Sources
The production of electricity has normally been through non-renewable sources from the
past decade. The non-renewable sources are known for their environmental degradation
specifically in terms of melting of glaciers, depletion of ozone layer, or change in the climatic
conditions. There has been depletion of the ozone layer as a result of greenhouse gases in the
atmosphere which is released during the generation of electricity by nonrenewable sources of
energy. There are changes in the climatic condition in the whole world and the prediction of the
environmental condition has always been characterized by inaccuracies (Council, 2009). The
nonrenewable source can be defined as those sources that do not renew themselves as a
satisfactory rate for sustainable economic extraction. Some of the non-renewable sources of
energy in Australia include:
Uranium: Australia has more than a third of the total world economy of uranium resources. The
major deposits of Uranium are in Western Australia, Northern Territory, and South Australia.
The production of Uranium in Australia is majorly for the purposes of exportation.
Crude Oil: The major sources of crude oil in Australia is located in Gippsland and Carnarvon. It
takes numerous years for these resources to form naturally and cannot be replaced after
Wind Energy 12
extraction. These sources of carbon are considered to be nonrenewable and their rate of
replenishment or formation on the floor of the seal is not known.
Gas: There are significant sources of gas in Australia which are majorly located in the basins of
Bonaparte, Browse, and Carnarvon. Just like other hydrocarbons, the gas resources are
considered to be nonrenewable and their rate of replenishment or formation on the floor of the
seal is not known (Devine, 2011).
Coal: Coal is combustible brownish-black or black sedimentary rock normally occurring in the
strata in veins or layers known as coal seams or coal bed. Coal is generally used as a source of
energy through burning it to produce heat and electricity. The most significant source of black
coal is located in the Sydney bans and Bowen-Surat. Some of the advantages of these non-
renewable energy sources include the creation of jobs, cost-effective, profitable, and also there is
a generation of the high amount of energy (Diesendorf, 2011).
Figure 4: Electricity generation from renewable energy sources in Australia (Droege, 2012)
extraction. These sources of carbon are considered to be nonrenewable and their rate of
replenishment or formation on the floor of the seal is not known.
Gas: There are significant sources of gas in Australia which are majorly located in the basins of
Bonaparte, Browse, and Carnarvon. Just like other hydrocarbons, the gas resources are
considered to be nonrenewable and their rate of replenishment or formation on the floor of the
seal is not known (Devine, 2011).
Coal: Coal is combustible brownish-black or black sedimentary rock normally occurring in the
strata in veins or layers known as coal seams or coal bed. Coal is generally used as a source of
energy through burning it to produce heat and electricity. The most significant source of black
coal is located in the Sydney bans and Bowen-Surat. Some of the advantages of these non-
renewable energy sources include the creation of jobs, cost-effective, profitable, and also there is
a generation of the high amount of energy (Diesendorf, 2011).
Figure 4: Electricity generation from renewable energy sources in Australia (Droege, 2012)
Wind Energy 13
Disadvantages of Nonrenewable Energy Sources
The burning of natural gas, oil and coal releases huge quantities of carbon monoxide and
carbon dioxide in the atmosphere which are the major contributing factors to global warming.
This gas reacts with other compounds in the environment resulting in the acidity of oceans,
depletion of ozone layer, and saturation of carbon. These gases also cause greenhouse effect by
the creation of mantle of rich air in the atmosphere, these compounds trap the rays of the sun and
make the atmosphere around the earth to be warmer. These energy sources also contribute to acid
rain especially when the fossil fuels are burnt to result to release of sulfur oxides which causes
rain to become acidic. The acid rains a dangerous to the environment and also corrodes the
metallic parts of buildings (Edenhofer, 2011).
The nonrenewable source of energy also dangerous to the health of human beings since
they emit carbon monoxide which can be dangerous to human beings. These gases cause
respiratory problems when inhaled or even death. These energy sources are also quite dirty and
leave dirt and soot on furnishing in homes. When these energy sources are used in factories, they
release soot and other substances into the air which coats the pavements and buildings and make
these parts of construction to look grimy and dirty. The non-renewable energy sources are also
not viable for a future generation since humans cannot base their lives entirely on these sources
forever since they will eventually run out (Edenhofer, 2011).
Renewable Energy Sources
Renewable energy is produced by the generation of electricity using renewable sources such as
geothermal, hydro, solar, and wind. Of all the sources of renewable energy in Australia, 0.002%
of the energy is generated by geothermal, 0.147% of the energy is generated by solar PV, 8.1%
Disadvantages of Nonrenewable Energy Sources
The burning of natural gas, oil and coal releases huge quantities of carbon monoxide and
carbon dioxide in the atmosphere which are the major contributing factors to global warming.
This gas reacts with other compounds in the environment resulting in the acidity of oceans,
depletion of ozone layer, and saturation of carbon. These gases also cause greenhouse effect by
the creation of mantle of rich air in the atmosphere, these compounds trap the rays of the sun and
make the atmosphere around the earth to be warmer. These energy sources also contribute to acid
rain especially when the fossil fuels are burnt to result to release of sulfur oxides which causes
rain to become acidic. The acid rains a dangerous to the environment and also corrodes the
metallic parts of buildings (Edenhofer, 2011).
The nonrenewable source of energy also dangerous to the health of human beings since
they emit carbon monoxide which can be dangerous to human beings. These gases cause
respiratory problems when inhaled or even death. These energy sources are also quite dirty and
leave dirt and soot on furnishing in homes. When these energy sources are used in factories, they
release soot and other substances into the air which coats the pavements and buildings and make
these parts of construction to look grimy and dirty. The non-renewable energy sources are also
not viable for a future generation since humans cannot base their lives entirely on these sources
forever since they will eventually run out (Edenhofer, 2011).
Renewable Energy Sources
Renewable energy is produced by the generation of electricity using renewable sources such as
geothermal, hydro, solar, and wind. Of all the sources of renewable energy in Australia, 0.002%
of the energy is generated by geothermal, 0.147% of the energy is generated by solar PV, 8.1%
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of the energy is generated by the bioenergy, 26% of the energy is generated by wind, and 53% of
the energy is generated by the hydroelectricity. These renewable energies in Australia are
discussed below:
Geothermal Energy: The geothermal energy produces energy by the use of molten core which is
composed of very high-temperature liquid in a rock. This geothermal heat circulating inside the
rock is transferred to the water reservoirs located underground which can then be used to
produce electricity. There have been explorations of geothermal wells in Australia so as to test
the presence of high-temperature geothermal activities. It has been proven that Australia has
adequate geothermal energy which has the ability to supply electricity for approximately 450
years. South Australia is expected to dominate in the sector of geothermal energy production
since 12 companies have already applied for exploration of geothermal energy in the region
(Ehrlich, 2013).
Solar Energy Source: The solar energy is produced when energy from the sunlight is directed to
the photovoltaic cells. These cells convert light into electric current by the use of the
photovoltaic effect. The solar energy is also used for the purposes of heating water in addition to
its role in the generation of electric energy through the photovoltaic effect. There is a low
generation of electricity by the use of solar power in Australia due to the high cost of per kW
compared to the other sources of power. There has been improved innovation of the technology
of PV by the use of building integrated PV where the PV cells function as structural and
architectural functions and incorporating a system of concentration which focuses the solar
energy to a smaller section of cells with high efficiency (Fox, 2009).
Hydroelectric Power: Hydroelectric power is produced by hydropower acquired from
conventional dams, pumped storage, run of the river or tide. The power extracted from the water
of the energy is generated by the bioenergy, 26% of the energy is generated by wind, and 53% of
the energy is generated by the hydroelectricity. These renewable energies in Australia are
discussed below:
Geothermal Energy: The geothermal energy produces energy by the use of molten core which is
composed of very high-temperature liquid in a rock. This geothermal heat circulating inside the
rock is transferred to the water reservoirs located underground which can then be used to
produce electricity. There have been explorations of geothermal wells in Australia so as to test
the presence of high-temperature geothermal activities. It has been proven that Australia has
adequate geothermal energy which has the ability to supply electricity for approximately 450
years. South Australia is expected to dominate in the sector of geothermal energy production
since 12 companies have already applied for exploration of geothermal energy in the region
(Ehrlich, 2013).
Solar Energy Source: The solar energy is produced when energy from the sunlight is directed to
the photovoltaic cells. These cells convert light into electric current by the use of the
photovoltaic effect. The solar energy is also used for the purposes of heating water in addition to
its role in the generation of electric energy through the photovoltaic effect. There is a low
generation of electricity by the use of solar power in Australia due to the high cost of per kW
compared to the other sources of power. There has been improved innovation of the technology
of PV by the use of building integrated PV where the PV cells function as structural and
architectural functions and incorporating a system of concentration which focuses the solar
energy to a smaller section of cells with high efficiency (Fox, 2009).
Hydroelectric Power: Hydroelectric power is produced by hydropower acquired from
conventional dams, pumped storage, run of the river or tide. The power extracted from the water
Wind Energy 15
depends on the height between the outflow of water and the source and also the volume of water.
The cost of hydroelectric energy source is relatively low, making it a competitive renewable
energy source. In Australia, the Snowy Mountains Scheme which was established in 1974 is the
major hydroelectric energy source and is composed of 7 major power stations and 16 major dams
and produces a total of 3800MW generation capacity (Hansen, 2010).
Wind Power: This is the proposed alternative source of energy in Australia for this research
paper. Wind energy source uses the flow of air through the turbines to the electric generators of
mechanical power wind farms are composed of numerous individual wind turbines which are
joined to the network of electric power transmission. Onshore wind an electric power source that
is cheaper and also very competitive compared with other nonrenewable energy sources such as
gas and coal plants. Offshore winds are stronger and steadier compared to the onshore, however,
the maintenance and construction of the offshore wins are higher. In Australia, wind farms
generate 30% of the clean energy of the country which has a total of 71 wind farms (Healey,
2013).
Advantages of Renewable Energy Sources
One of the major advantages of the renewable sources of energy is that they are
renewable sources. This denotes that they do not get depleted over a given duration and hence
there is no possibility of running out. Fossil energy sources can easily get depleted since they are
considered limited resources and there are possibilities that these fuels will run out in future.
These energy sources are also eco-friendly since they are characterized by zero or low carbon
emission and greenhouse effects (Hepburn, 2015). Non-renewable sources emit carbon
monoxide and also greenhouse gases which are hugely responsible for the degradation of quality
depends on the height between the outflow of water and the source and also the volume of water.
The cost of hydroelectric energy source is relatively low, making it a competitive renewable
energy source. In Australia, the Snowy Mountains Scheme which was established in 1974 is the
major hydroelectric energy source and is composed of 7 major power stations and 16 major dams
and produces a total of 3800MW generation capacity (Hansen, 2010).
Wind Power: This is the proposed alternative source of energy in Australia for this research
paper. Wind energy source uses the flow of air through the turbines to the electric generators of
mechanical power wind farms are composed of numerous individual wind turbines which are
joined to the network of electric power transmission. Onshore wind an electric power source that
is cheaper and also very competitive compared with other nonrenewable energy sources such as
gas and coal plants. Offshore winds are stronger and steadier compared to the onshore, however,
the maintenance and construction of the offshore wins are higher. In Australia, wind farms
generate 30% of the clean energy of the country which has a total of 71 wind farms (Healey,
2013).
Advantages of Renewable Energy Sources
One of the major advantages of the renewable sources of energy is that they are
renewable sources. This denotes that they do not get depleted over a given duration and hence
there is no possibility of running out. Fossil energy sources can easily get depleted since they are
considered limited resources and there are possibilities that these fuels will run out in future.
These energy sources are also eco-friendly since they are characterized by zero or low carbon
emission and greenhouse effects (Hepburn, 2015). Non-renewable sources emit carbon
monoxide and also greenhouse gases which are hugely responsible for the degradation of quality
Wind Energy 16
or air, climatic change, and global warming. The wind and solar power are known to be
environmentally friendly since they do not emit toxic gases to the environment. The use of these
renewable energy sources can drastically reduce the dependence on fossil fuels as an energy
source (Hossain, 2014).
The renewable sources of energy are also reliable energy sources, unlike fossil fuel
whose use has increased sharply due to over-reliance on these energy sources leading to a spike
in energy prices, political instabilities, trade dispute, and negative effects of the energy policies
of the nation. The renewable energy sources are largely distributed over diverse geographical
locations where there are low interruptions during electricity generation. These renewable energy
sources have also resulted in the creation of jobs in the world economies compared to the fossil
fuels sources which are normally capital intensive and mechanized hence requiring only a small
number of employees for maintenance (Hossain, 2014).
Apart from the jobs created directly in the sector of renewable energy sources, the growth
in clean energy has also resulted in positive ripple effect to the economy. This is because the
industries in the supply chain of renewable energy sources benefit from increased business
income and increase household income. These energy sources have also resulted in stable energy
prices since by providing affordable electricity across the nation can assist in stabilization of
energy prices in the future. Despite the facilities of renewable energy sources need upfront
investment during construction, these energy sources can operate at low cost resulting instability
in prices of energy after a certain duration (IBP, 2015).
Disadvantages of Renewable Energy Sources
or air, climatic change, and global warming. The wind and solar power are known to be
environmentally friendly since they do not emit toxic gases to the environment. The use of these
renewable energy sources can drastically reduce the dependence on fossil fuels as an energy
source (Hossain, 2014).
The renewable sources of energy are also reliable energy sources, unlike fossil fuel
whose use has increased sharply due to over-reliance on these energy sources leading to a spike
in energy prices, political instabilities, trade dispute, and negative effects of the energy policies
of the nation. The renewable energy sources are largely distributed over diverse geographical
locations where there are low interruptions during electricity generation. These renewable energy
sources have also resulted in the creation of jobs in the world economies compared to the fossil
fuels sources which are normally capital intensive and mechanized hence requiring only a small
number of employees for maintenance (Hossain, 2014).
Apart from the jobs created directly in the sector of renewable energy sources, the growth
in clean energy has also resulted in positive ripple effect to the economy. This is because the
industries in the supply chain of renewable energy sources benefit from increased business
income and increase household income. These energy sources have also resulted in stable energy
prices since by providing affordable electricity across the nation can assist in stabilization of
energy prices in the future. Despite the facilities of renewable energy sources need upfront
investment during construction, these energy sources can operate at low cost resulting instability
in prices of energy after a certain duration (IBP, 2015).
Disadvantages of Renewable Energy Sources
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Wind Energy 17
One if the major shortcoming of renewable energy sources is they lack reliability in
supply. These energy sources normally rely on the weather for their source of power. Solar
energy source require sunshine and clear skies to gather heat and electricity generated, wind
turbines need wind its blades to turn, and hydro generators require rain to fill the dams so as to
produce water that is used in turning the blades coupled with the generators which produce
electricity. In case these natural resources are not available, there will be no capacity of these
energy sources to produce energy. This can be inconsistent and unpredictable (Jennings, 2009).
Numerous types of the renewable energy sources must be collected at a specific point,
this means that there is need of distribution network from this location of generation to the final
consumers. In most cases, setting up of these distribution networks require a huge quantity fossil
fuels which can take the entire generation to neutralize with the quantity of energy produced by
the particular energy source. This commercial viability of the renewable sources is brought about
by the fact that the renewable sources of energy are location-specific and their potential is only
limited to a specific location (Johansson, 2012).
These renewable energy sources also require storage capabilities so that they can be any
time and day. When using these energy sources, storage in businesses or homes, storage and
backup resources must be incorporated into the generation of power. The speed of wind is
always inconsistent and there are times when the wind supply is high such that the amount of
energy generated is more than the demanded, this surplus energy can be stored and used when
the speed of wind is low to sufficiently generate the required amount of energy. The same also
happens in solar energy source since during snow seasons or at night, there is no supply of
sunlight to be used by the solar panels to generate electricity. The major challenge in the
One if the major shortcoming of renewable energy sources is they lack reliability in
supply. These energy sources normally rely on the weather for their source of power. Solar
energy source require sunshine and clear skies to gather heat and electricity generated, wind
turbines need wind its blades to turn, and hydro generators require rain to fill the dams so as to
produce water that is used in turning the blades coupled with the generators which produce
electricity. In case these natural resources are not available, there will be no capacity of these
energy sources to produce energy. This can be inconsistent and unpredictable (Jennings, 2009).
Numerous types of the renewable energy sources must be collected at a specific point,
this means that there is need of distribution network from this location of generation to the final
consumers. In most cases, setting up of these distribution networks require a huge quantity fossil
fuels which can take the entire generation to neutralize with the quantity of energy produced by
the particular energy source. This commercial viability of the renewable sources is brought about
by the fact that the renewable sources of energy are location-specific and their potential is only
limited to a specific location (Johansson, 2012).
These renewable energy sources also require storage capabilities so that they can be any
time and day. When using these energy sources, storage in businesses or homes, storage and
backup resources must be incorporated into the generation of power. The speed of wind is
always inconsistent and there are times when the wind supply is high such that the amount of
energy generated is more than the demanded, this surplus energy can be stored and used when
the speed of wind is low to sufficiently generate the required amount of energy. The same also
happens in solar energy source since during snow seasons or at night, there is no supply of
sunlight to be used by the solar panels to generate electricity. The major challenge in the
Wind Energy 18
implementation of these back-up or storage resources, there will be a push in the cost of a new
renewable energy source beyond what can be afforded by many individuals (Jones, 2014).
Pollution is also produced by some of the renewable energy sources since energy sources
such as biomass still burn waste products and release harmful gasses into the atmosphere. These
gases include methane and carbon which are known as greenhouse gases. The facilities and
technologies that are used during the construction of the renewable energy sources require fossil
fuels and also during distribution and transportation networks. In many cases, it is the renewable
energy sources that rely on the non-renewable sources, whereas the fossil fuels do not depend on
the renewable energy sources. Some of the types of renewable energy sources require a massive
space for installation compared to others. The current solar energy source needs acres of space to
produce megawatts of energy (Kharchenko, 2018).
CHAPTER 3
METHODOLOGY
WIND ENERGY IN AUSTRALIA
Australia depends on both renewable and nonrenewable energy sources for the electricity
generation. In the past, the electricity generation was majorly from nonrenewable sources of
energy, however, the use of renewable and natural energy sources has increased over the years.
The country has greatly established the use of wind energy and hydroelectric energy sources.
However, the potential of other sources of renewable energy such as tidal, geothermal, wave, and
solar have been proved high since their technologies are still not well established. In case the
economic and technological issues are overcome, then these energy sources may be used as
implementation of these back-up or storage resources, there will be a push in the cost of a new
renewable energy source beyond what can be afforded by many individuals (Jones, 2014).
Pollution is also produced by some of the renewable energy sources since energy sources
such as biomass still burn waste products and release harmful gasses into the atmosphere. These
gases include methane and carbon which are known as greenhouse gases. The facilities and
technologies that are used during the construction of the renewable energy sources require fossil
fuels and also during distribution and transportation networks. In many cases, it is the renewable
energy sources that rely on the non-renewable sources, whereas the fossil fuels do not depend on
the renewable energy sources. Some of the types of renewable energy sources require a massive
space for installation compared to others. The current solar energy source needs acres of space to
produce megawatts of energy (Kharchenko, 2018).
CHAPTER 3
METHODOLOGY
WIND ENERGY IN AUSTRALIA
Australia depends on both renewable and nonrenewable energy sources for the electricity
generation. In the past, the electricity generation was majorly from nonrenewable sources of
energy, however, the use of renewable and natural energy sources has increased over the years.
The country has greatly established the use of wind energy and hydroelectric energy sources.
However, the potential of other sources of renewable energy such as tidal, geothermal, wave, and
solar have been proved high since their technologies are still not well established. In case the
economic and technological issues are overcome, then these energy sources may be used as
Wind Energy 19
alternative source of electricity to assist the country to minimize the emissions of greenhouse
gases (Lund, 2014).
The growth of in power energy source is rapidly increasing in numerous geographical
locations within the country, this is the major reason for selection of wind energy as an
alternative energy source for Australia and not any other renewable energy source such as
hydroelectricity or solar power energy sources. The government in different territories in the
country has set a diverse target for the electricity generation from renewable sources. The
expected target for the electricity generation for Victoria is as 25% and for New South Wales is
at 20% of the total energy generated by the year 2020 (Lyster, 2011). The setting of targets in
different territories has led to the installation of wind, solar, and hydropower plants in different
territories. Wind energy source is a rapidly expanding mode of renewable energy generation in
Australia with an average yearly installed capacity growth rate of 35% over the last 5 years up to
2011. There were 4455 MW of installed capacity and another 18823 megawatts committed or
proposed capacity as at December 2017. The wind farms in Australia generates an average of 30
to 35% of the capacity factor which makes wind energy source an attractive alternative energy
source (Mahmud, 2012).
Components of Wind Power
The wind turbines are devices that are involved in the conversion of kinetic energy of the
wind into electrical power. The outcome of over decades of modern engineering and windmill
development, the present wind turbines are made in a wide range of horizontal axis and vertical
axis types. The smaller turbines can be applied in auxiliary power as battery charging. Slightly
greater turbines can be applied in domestic power supply for making small contributions to the
alternative source of electricity to assist the country to minimize the emissions of greenhouse
gases (Lund, 2014).
The growth of in power energy source is rapidly increasing in numerous geographical
locations within the country, this is the major reason for selection of wind energy as an
alternative energy source for Australia and not any other renewable energy source such as
hydroelectricity or solar power energy sources. The government in different territories in the
country has set a diverse target for the electricity generation from renewable sources. The
expected target for the electricity generation for Victoria is as 25% and for New South Wales is
at 20% of the total energy generated by the year 2020 (Lyster, 2011). The setting of targets in
different territories has led to the installation of wind, solar, and hydropower plants in different
territories. Wind energy source is a rapidly expanding mode of renewable energy generation in
Australia with an average yearly installed capacity growth rate of 35% over the last 5 years up to
2011. There were 4455 MW of installed capacity and another 18823 megawatts committed or
proposed capacity as at December 2017. The wind farms in Australia generates an average of 30
to 35% of the capacity factor which makes wind energy source an attractive alternative energy
source (Mahmud, 2012).
Components of Wind Power
The wind turbines are devices that are involved in the conversion of kinetic energy of the
wind into electrical power. The outcome of over decades of modern engineering and windmill
development, the present wind turbines are made in a wide range of horizontal axis and vertical
axis types. The smaller turbines can be applied in auxiliary power as battery charging. Slightly
greater turbines can be applied in domestic power supply for making small contributions to the
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Wind Energy 20
domestic use. Arrays of huge turbines which are also known as wind farms have become a
significant renewable energy source in the country as part of the strategy to minimize the
reliance of fossil fuels (Michael, 2010). The figure below shows the components of a typical
wind turbine:
Figure 5: Schematics of a typical wind turbine (Michalena, 2013)
The rotor blades: These are fundamentally the turbine system sails and acts as obstructions to the
wind the flow of win. When the blades are forced to move by the wind, majority of its energy is
transferred to the rotor. The attack angle with respect to the direction of the wind and rotor’s
shape of the rotor blade determines the functionality of the turbines. The rotor blades possess a
distinct curved figure just like the airfoil wings of the plane such that when there is blowing of
wind past a plane, the wings of the plane force them up with a force known as lift (Morgan,
2010). Similarly, when there is blowing of wind past the blades, the blades spin them around and
the kinetic energy is lost by the wind while the kinetic energy is gained by the turbine. The
quantity of energy that the turbine produces is proportional to the area swept by the rotating rotor
blades. Numerous wind turbines have plastic blades reinforced with three glass and their
domestic use. Arrays of huge turbines which are also known as wind farms have become a
significant renewable energy source in the country as part of the strategy to minimize the
reliance of fossil fuels (Michael, 2010). The figure below shows the components of a typical
wind turbine:
Figure 5: Schematics of a typical wind turbine (Michalena, 2013)
The rotor blades: These are fundamentally the turbine system sails and acts as obstructions to the
wind the flow of win. When the blades are forced to move by the wind, majority of its energy is
transferred to the rotor. The attack angle with respect to the direction of the wind and rotor’s
shape of the rotor blade determines the functionality of the turbines. The rotor blades possess a
distinct curved figure just like the airfoil wings of the plane such that when there is blowing of
wind past a plane, the wings of the plane force them up with a force known as lift (Morgan,
2010). Similarly, when there is blowing of wind past the blades, the blades spin them around and
the kinetic energy is lost by the wind while the kinetic energy is gained by the turbine. The
quantity of energy that the turbine produces is proportional to the area swept by the rotating rotor
blades. Numerous wind turbines have plastic blades reinforced with three glass and their
Wind Energy 21
mechanical design and properties determine the beneficial service life of the blades (Morgan,
2009).
Generator: The generator uses the principles of electromagnetic induction to generate electrical
voltage. This generator is coupled to the main support frame and attached to the high-speed
terminal of the transmission shaft. This voltage which is the difference in pressure is the force
that moves electrical current or electricity from the point of production to another point.
Generally, a simple generator is composed of a magnet and a conductor which is basically a
coiled wire. Inside the generator, the shaft is coupled with permanent magnets assembly that
surrounds the wire coil. During the spinning of the shaft by the rotor, the shaft spins the magnetic
assembly, producing a voltage in the wire coil. The voltage drives electricity out through power
lines for the purposes of distribution to the consumers (Moseley, 2014).
Shaft: The shaft of the wind turbine is coupled to the centre of the rotor. During the spinning of
the rotor, the shaft concurrently spins. Through this, the rotor conveys to the shaft its rotational
and mechanical energy, which gets into an electrical generator on the other terminal (Nelson,
2011).
Gearbox: This device is involved in the conversion of relatively slow rotation of the spinning
blades into higher velocity motion resulting in high rate of shaft rotation so as to power the
electricity generator. This is one of the technologies that have been incorporated in the wind
energy sources so as to ensure sufficient harvest of kinetic energy in the wind even when there is
low wind speed at that moment (Nelson, 2013).
mechanical design and properties determine the beneficial service life of the blades (Morgan,
2009).
Generator: The generator uses the principles of electromagnetic induction to generate electrical
voltage. This generator is coupled to the main support frame and attached to the high-speed
terminal of the transmission shaft. This voltage which is the difference in pressure is the force
that moves electrical current or electricity from the point of production to another point.
Generally, a simple generator is composed of a magnet and a conductor which is basically a
coiled wire. Inside the generator, the shaft is coupled with permanent magnets assembly that
surrounds the wire coil. During the spinning of the shaft by the rotor, the shaft spins the magnetic
assembly, producing a voltage in the wire coil. The voltage drives electricity out through power
lines for the purposes of distribution to the consumers (Moseley, 2014).
Shaft: The shaft of the wind turbine is coupled to the centre of the rotor. During the spinning of
the rotor, the shaft concurrently spins. Through this, the rotor conveys to the shaft its rotational
and mechanical energy, which gets into an electrical generator on the other terminal (Nelson,
2011).
Gearbox: This device is involved in the conversion of relatively slow rotation of the spinning
blades into higher velocity motion resulting in high rate of shaft rotation so as to power the
electricity generator. This is one of the technologies that have been incorporated in the wind
energy sources so as to ensure sufficient harvest of kinetic energy in the wind even when there is
low wind speed at that moment (Nelson, 2013).
Wind Energy 22
Inverter: This device is involved in the conversion of direct current electricity to the
conventional household alternating current electricity or even supply the excess electricity
generated to the main grid (Nelson, 2013).
Factors Affecting Wind Power Output
Some of the factors that affect the output of wind power generated include rotor area,
physical effects of obstacles such as mountains, wind velocity, air density, earth rotation, the
cooling effect of the polar ice caps and oceans, the heat from the sun, temperature gradient
between sea and land. The win is the first factor that affects the output of the generated power
since more wind speed results in greater amount of power that will be generated by the wind
turbines. The rotor area is the area swept by the blades of the wind turbines. When the area of the
blades is doubled, then the output power of the wind turbines will also be doubled (Philander,
2012).
Wind speed is also another significant factor that affects the output power generated by
the wind turbines. In case the speed of the wind is doubled, the generated power becomes eight
times greater. Different regions have different speeds of wind. The more the wind speed and the
force generated, the more the amount of power generated by the turbines. The air density also
affects the amount of power generated by the wind turbines. The wind power is directly
proportional to the density of air. This is the reason why the majority of the wind farms are
situated near or in the oceans or seas. At higher altitudes, there is a significant decrease in the air
density, hence the wind farms cannot be made near mountains or any other obstacles such as tall
constructions (Plunkett, 2009).
Generation of Electricity by Wind Turbines
Inverter: This device is involved in the conversion of direct current electricity to the
conventional household alternating current electricity or even supply the excess electricity
generated to the main grid (Nelson, 2013).
Factors Affecting Wind Power Output
Some of the factors that affect the output of wind power generated include rotor area,
physical effects of obstacles such as mountains, wind velocity, air density, earth rotation, the
cooling effect of the polar ice caps and oceans, the heat from the sun, temperature gradient
between sea and land. The win is the first factor that affects the output of the generated power
since more wind speed results in greater amount of power that will be generated by the wind
turbines. The rotor area is the area swept by the blades of the wind turbines. When the area of the
blades is doubled, then the output power of the wind turbines will also be doubled (Philander,
2012).
Wind speed is also another significant factor that affects the output power generated by
the wind turbines. In case the speed of the wind is doubled, the generated power becomes eight
times greater. Different regions have different speeds of wind. The more the wind speed and the
force generated, the more the amount of power generated by the turbines. The air density also
affects the amount of power generated by the wind turbines. The wind power is directly
proportional to the density of air. This is the reason why the majority of the wind farms are
situated near or in the oceans or seas. At higher altitudes, there is a significant decrease in the air
density, hence the wind farms cannot be made near mountains or any other obstacles such as tall
constructions (Plunkett, 2009).
Generation of Electricity by Wind Turbines
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Wind Energy 23
The process of electricity generation by a wind turbine begins when the wind containing
kinetic energy blows past the rotor blades of the turbine. The rotor rotates around, acquiring
extra kinetic energy from the wind, and rotating the drive shaft at the center that supports them.
In the turbine, the gearbox converts the low-velocity rotation of the drive shaft which may be
approximately 20 rpm into high-velocity rotation which may be approximately 1500 rpm. This
velocity is sufficient to drive the efficiently drive the generator. The generator located behind the
gearbox immediately takes the kinetic energy from the rotating drive shaft and transforms into
electricity. The electrical energy generated by the generator streams through the cable running
down inside of the turbine tower (Quaschning, 2009).
Wind energy source uses the flow of air through the turbines to the electric generators of
mechanical power Win farms are composed of numerous individual wind turbines which are
joined to the network of electric power transmission. Onshore wind an electric power source that
is cheaper and also very competitive compared with other nonrenewable energy sources such as
gas and coal plants. Offshore winds are stronger and steadier compared to the onshore, however,
the maintenance and construction of the offshore wins are higher. In Australia, wind farms
generate 30% of the clean energy of the country which has a total of 71 wind farms (Quaschning,
2010).
The process of electricity generation by a wind turbine begins when the wind containing
kinetic energy blows past the rotor blades of the turbine. The rotor rotates around, acquiring
extra kinetic energy from the wind, and rotating the drive shaft at the center that supports them.
In the turbine, the gearbox converts the low-velocity rotation of the drive shaft which may be
approximately 20 rpm into high-velocity rotation which may be approximately 1500 rpm. This
velocity is sufficient to drive the efficiently drive the generator. The generator located behind the
gearbox immediately takes the kinetic energy from the rotating drive shaft and transforms into
electricity. The electrical energy generated by the generator streams through the cable running
down inside of the turbine tower (Quaschning, 2009).
Wind energy source uses the flow of air through the turbines to the electric generators of
mechanical power Win farms are composed of numerous individual wind turbines which are
joined to the network of electric power transmission. Onshore wind an electric power source that
is cheaper and also very competitive compared with other nonrenewable energy sources such as
gas and coal plants. Offshore winds are stronger and steadier compared to the onshore, however,
the maintenance and construction of the offshore wins are higher. In Australia, wind farms
generate 30% of the clean energy of the country which has a total of 71 wind farms (Quaschning,
2010).
Wind Energy 24
Figure 6: Wind energy generation in Australia (Quaschning, 2010)
GENERATED WIND ENERGY IN AUSTRALIA
Wind energy is rapidly expanding the type of renewable energy in Australia. The
southern coastline lies in the forties with an average speed of wind of approximately 8 m/s at
50m beyond the ground surface. Some of the regions in Australia that have good wind resource
include southern South Australia, western Victoria, New South Wales, and southwest of Western
Australia. There were 4455 MW of installed capacity and another 18823 megawatts committed
or proposed capacity as at December 2017. The wind farms in Australia generates an average of
30 to 35% of the capacity factor which makes wind energy source an attractive alternative
energy source. The wind energy accounted for 30% of the total supply of renewable energy and
5.3% of the total electricity demand in Australia (Rahman, 2017).
By 2016, the total number of a wind farm in the country was 19 win farms and the
majority of them possess turbines ranging between 1.5 MW and 3 MW. A total of 16 wind
energy projects are either under construction or almost starting to operate by 2017 after reaching
Figure 6: Wind energy generation in Australia (Quaschning, 2010)
GENERATED WIND ENERGY IN AUSTRALIA
Wind energy is rapidly expanding the type of renewable energy in Australia. The
southern coastline lies in the forties with an average speed of wind of approximately 8 m/s at
50m beyond the ground surface. Some of the regions in Australia that have good wind resource
include southern South Australia, western Victoria, New South Wales, and southwest of Western
Australia. There were 4455 MW of installed capacity and another 18823 megawatts committed
or proposed capacity as at December 2017. The wind farms in Australia generates an average of
30 to 35% of the capacity factor which makes wind energy source an attractive alternative
energy source. The wind energy accounted for 30% of the total supply of renewable energy and
5.3% of the total electricity demand in Australia (Rahman, 2017).
By 2016, the total number of a wind farm in the country was 19 win farms and the
majority of them possess turbines ranging between 1.5 MW and 3 MW. A total of 16 wind
energy projects are either under construction or almost starting to operate by 2017 after reaching
Wind Energy 25
the financial closure and their combines installed capacity will be 1861 MW. South Australia has
win energy capacity of 36.9% which accounts for the 40% of the electricity requirements in the
entire country as of 2016. This was the first year in which the wind energy was the leading
electricity source in the country. The wind energy attained 26% of the generated electricity in the
country by the end of 2011which is almost equivalent to the power from coal-fired (Rashid,
2014). The figure below shows a typical generation of wind power, wind penetration, rooftop
PV, and demand in South Australia:
Figure 7: Wind generation, wind penetration, rooftop PV, and demand in South
Australia (Rasmussen, 2012).
Victoria has a substantial system of wind energy sources which contribute to 30% of the total
energy capacity in the country. The government of Victoria announced the financial backing for
new wind farms in August 2015 as part of a plan to promote renewable energy sources in the part
of the country. This plan is expected to establish 100 MW of new energy from wind resource in
the country and the investment is worth $200 million (Salameh, 2014).
WIND FARMS IN AUSTRALIA
the financial closure and their combines installed capacity will be 1861 MW. South Australia has
win energy capacity of 36.9% which accounts for the 40% of the electricity requirements in the
entire country as of 2016. This was the first year in which the wind energy was the leading
electricity source in the country. The wind energy attained 26% of the generated electricity in the
country by the end of 2011which is almost equivalent to the power from coal-fired (Rashid,
2014). The figure below shows a typical generation of wind power, wind penetration, rooftop
PV, and demand in South Australia:
Figure 7: Wind generation, wind penetration, rooftop PV, and demand in South
Australia (Rasmussen, 2012).
Victoria has a substantial system of wind energy sources which contribute to 30% of the total
energy capacity in the country. The government of Victoria announced the financial backing for
new wind farms in August 2015 as part of a plan to promote renewable energy sources in the part
of the country. This plan is expected to establish 100 MW of new energy from wind resource in
the country and the investment is worth $200 million (Salameh, 2014).
WIND FARMS IN AUSTRALIA
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Wind Energy 26
There are an aggregate of 68 wind farms in Australia with 100kW operating capacity as
at December 2013. There are an aggregate of 79 wind farms in Australia with 4327 MW
operating capacity of 4327 MW at the end of 2016. The wind farms in Australia include
Musselroe, Waubra, Portland, Collgar, Ararat, Lake Bonney, Hornsdale, Hallett, Snowtown, and
Macarthur (Sayigh, 2018). These wind energy farms are explained below:
Macarthur Wind Farm: This is the largest wind farm in the entire country and is located in
Victoria with a capacity of 420 MW. It is a 5500 ha site and based on the speeds of wind that are
prevailing, the estimated generation is 1250 GWh annually. This energy source provides power
for approximately 220000 homes after it began operating in 2013.
Snowtown Wind Farm: This wind farm is located on the Hummocks and Barunga ranges in the
north of South Australia and has a capacity of 369 MW. The initial 47 turbines for this wind
farm was completed in 2008 and extra 90 turbines started operating in 2014 (Science, 2011).
Hallett Wind Farm: This is a collective name of four wind farms in Hallet which are operated
and owned by AGL Energy. These wind farms include Bluff Range, North Brown Hill, Hallet
Hill, and Brown Hill. The total energy capacity generated in 351 MW.
Hornsdale Wind Farm: This wind farm is situated in Hornsdale in South Australia and is
composed of 99 wind turbines with a capacity of generation of 351 MW. The wind farm is
operated and owned by Neoen renewable energy company (Spellman, 2016).
Lake Bonney Wind Farm: This wind farm is situated in South Australia and was constructed in
three different phases. The first phase was composed of 46 turbines having a total of 80.5 MW
capacity and the second and last phase was composed of 53 turbines with an overall generation
capacity of 159 MW.
There are an aggregate of 68 wind farms in Australia with 100kW operating capacity as
at December 2013. There are an aggregate of 79 wind farms in Australia with 4327 MW
operating capacity of 4327 MW at the end of 2016. The wind farms in Australia include
Musselroe, Waubra, Portland, Collgar, Ararat, Lake Bonney, Hornsdale, Hallett, Snowtown, and
Macarthur (Sayigh, 2018). These wind energy farms are explained below:
Macarthur Wind Farm: This is the largest wind farm in the entire country and is located in
Victoria with a capacity of 420 MW. It is a 5500 ha site and based on the speeds of wind that are
prevailing, the estimated generation is 1250 GWh annually. This energy source provides power
for approximately 220000 homes after it began operating in 2013.
Snowtown Wind Farm: This wind farm is located on the Hummocks and Barunga ranges in the
north of South Australia and has a capacity of 369 MW. The initial 47 turbines for this wind
farm was completed in 2008 and extra 90 turbines started operating in 2014 (Science, 2011).
Hallett Wind Farm: This is a collective name of four wind farms in Hallet which are operated
and owned by AGL Energy. These wind farms include Bluff Range, North Brown Hill, Hallet
Hill, and Brown Hill. The total energy capacity generated in 351 MW.
Hornsdale Wind Farm: This wind farm is situated in Hornsdale in South Australia and is
composed of 99 wind turbines with a capacity of generation of 351 MW. The wind farm is
operated and owned by Neoen renewable energy company (Spellman, 2016).
Lake Bonney Wind Farm: This wind farm is situated in South Australia and was constructed in
three different phases. The first phase was composed of 46 turbines having a total of 80.5 MW
capacity and the second and last phase was composed of 53 turbines with an overall generation
capacity of 159 MW.
Wind Energy 27
Collgar Wind Farm: This wind farm is located in Western Australia approximately 25 km from
Merredin. This farm has an overall of 111 wind turbines with the generation capacity of 206
MW. The far became fully operational on 2011 October with an average of 792000 MWh
annually (Sørensen, 2010).
Portland Wind Farm: This is one of the largest wind farms situated in the coastal region of
South-west Victoria and is composed of four different sites. This project was completed in 2011
and the generation capacity is 195MW.
Waubra Wind Farm: This win farm is situated in Ballarat in Victoria and is the fourth largest
wind farm with a total of 128 wind turbines and generation capacity of 192 MW. This farm
serves a total of 143000 households (Tasneem, 2011).
Musselroe Wind Farm: This wind farm is situated in Tasmania and is the operated and owned by
Hydro Tasmania. The farm is composed of 56 wind turbines with 168 MW generation capacity.
The total projects of wind farms in Australia for every state are as shown in the figure below:
Figure 8: Wind Energy installed capacity by Australian states (Tiwari, 2012)
Collgar Wind Farm: This wind farm is located in Western Australia approximately 25 km from
Merredin. This farm has an overall of 111 wind turbines with the generation capacity of 206
MW. The far became fully operational on 2011 October with an average of 792000 MWh
annually (Sørensen, 2010).
Portland Wind Farm: This is one of the largest wind farms situated in the coastal region of
South-west Victoria and is composed of four different sites. This project was completed in 2011
and the generation capacity is 195MW.
Waubra Wind Farm: This win farm is situated in Ballarat in Victoria and is the fourth largest
wind farm with a total of 128 wind turbines and generation capacity of 192 MW. This farm
serves a total of 143000 households (Tasneem, 2011).
Musselroe Wind Farm: This wind farm is situated in Tasmania and is the operated and owned by
Hydro Tasmania. The farm is composed of 56 wind turbines with 168 MW generation capacity.
The total projects of wind farms in Australia for every state are as shown in the figure below:
Figure 8: Wind Energy installed capacity by Australian states (Tiwari, 2012)
Wind Energy 28
The major wind power companies in Australia include Infigen Energy, Windlab, Wind Prospect,
Trust Power, Suzlon, Hydro Tasmania, Pacific Hydro, and Meridian Energy.
WIND ENERGY STORAGE
The variations in the higher intermittency and production of wind energy generation
make it difficult to incorporate conventional procedures of scheduling, planning, and operations
of power systems. In the past decade, the installed capacity of wind energy has significantly
expanded in Australia and is expected to rapidly grow in the coming years. This progressive
integration scale has resulted in serious concerns regarding the impacts of such a wind power
generation scale on the power system security, reliability, and stability. One of the major
concerns regarding the high-level penetration of wind energy is their impact on the stability of
the power system and is concerned with voltage stability and frequency regulation (Zachary
Smith, 2009).
The active generation of power from the wind turbines is influenced by the design of
wind turbine generator and also the wind flow while the reactive power demand is influenced by
the devices of conversion. The wind farms are generally installed in rural regions and the
reactive power have to be conveyed over long distances hence resulting in power loss. The wind
farms joined to the grid results in redistribution of reactive power and power fluctuations which
normally cause voltage unbalancing. This poses a serious threat to securing and grid stability.
This can be prevented by the installation of Lithium-ion batteries. The battery storage is
normally used in solar energy application for the purposes of storing the power generated by the
wind turbines (Williams, 2010).
The major wind power companies in Australia include Infigen Energy, Windlab, Wind Prospect,
Trust Power, Suzlon, Hydro Tasmania, Pacific Hydro, and Meridian Energy.
WIND ENERGY STORAGE
The variations in the higher intermittency and production of wind energy generation
make it difficult to incorporate conventional procedures of scheduling, planning, and operations
of power systems. In the past decade, the installed capacity of wind energy has significantly
expanded in Australia and is expected to rapidly grow in the coming years. This progressive
integration scale has resulted in serious concerns regarding the impacts of such a wind power
generation scale on the power system security, reliability, and stability. One of the major
concerns regarding the high-level penetration of wind energy is their impact on the stability of
the power system and is concerned with voltage stability and frequency regulation (Zachary
Smith, 2009).
The active generation of power from the wind turbines is influenced by the design of
wind turbine generator and also the wind flow while the reactive power demand is influenced by
the devices of conversion. The wind farms are generally installed in rural regions and the
reactive power have to be conveyed over long distances hence resulting in power loss. The wind
farms joined to the grid results in redistribution of reactive power and power fluctuations which
normally cause voltage unbalancing. This poses a serious threat to securing and grid stability.
This can be prevented by the installation of Lithium-ion batteries. The battery storage is
normally used in solar energy application for the purposes of storing the power generated by the
wind turbines (Williams, 2010).
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Wind Energy 29
Figure 9: Lithium-ion battery system of wind power storage (Tiwari, 2012)
Lithium-ion batteries are batteries that are rechargeable in which Lithium ions move from
the negative electrode to positive electrode during discharge and Lithium ions move from
positive electrode to negative electrode during charging by the wind energy source. This battery
is composed of two electrodes and an electrolyte which enables the movement of ions. The types
of electrolytes that are commonly used in the Lithium-ion batteries include diethyl carbonate,
dimethyl carbonate, and ethylene carbonate. During charging of the Lithium-ion batteries when
there is a generation of electricity by the wind power source, there is an application of a higher
voltage of similar polarities, compelling the charging current to flow within the battery to the
negative terminal from the positive terminal (Valentine, 2014).
ADVANTAGES OF WIND ENERGY SOURCES
Environmental friendly: Wind power is one of the environmental friendly sources of energy
currently available. After the installation and manufacture of the wind turbines, no or little
pollution is also expected produced due to the wind turbine operations.
Figure 9: Lithium-ion battery system of wind power storage (Tiwari, 2012)
Lithium-ion batteries are batteries that are rechargeable in which Lithium ions move from
the negative electrode to positive electrode during discharge and Lithium ions move from
positive electrode to negative electrode during charging by the wind energy source. This battery
is composed of two electrodes and an electrolyte which enables the movement of ions. The types
of electrolytes that are commonly used in the Lithium-ion batteries include diethyl carbonate,
dimethyl carbonate, and ethylene carbonate. During charging of the Lithium-ion batteries when
there is a generation of electricity by the wind power source, there is an application of a higher
voltage of similar polarities, compelling the charging current to flow within the battery to the
negative terminal from the positive terminal (Valentine, 2014).
ADVANTAGES OF WIND ENERGY SOURCES
Environmental friendly: Wind power is one of the environmental friendly sources of energy
currently available. After the installation and manufacture of the wind turbines, no or little
pollution is also expected produced due to the wind turbine operations.
Wind Energy 30
Sustainable and Renewable: Wind power is known to be both sustainable and renewable since
the supply of wind in nature and cannot get depleted unlike non-renewable energy sources such
as fossil fuels. This makes the win energy source to be an ideal source of energy for a sustainable
supply of power (Tyagi, 2017).
Low Maintenance: Wind turbines are known to require low maintenance after their installation.
A newly installed wind turbine is likely to last some duration before any maintenance work can
be performed on it. However, after few years of operation, the turbines will require low
maintenance especially on the moving parts of the turbines.
Job creation: The wind energy sector has really boomed after the introduction of wind turbines
in the market. This has led to the creation of jobs in numerous wind farms and also for the
management and maintenance operations of the wind turbines. There is also the creation of jobs
for the wind turbine manufacturer, maintenance and installation of the wind turbines within the
country (Twidell, 2015).
Free: The wind energy is a free source of energy unlike some other source of energy. There is no
market for the demand and supply of wind energy. This resource is readily available for
everyone and will never get depleted. This makes the wind power to be a viable option for
generation of cheap electricity.
High Potential: The wind power has a high potential since it is both sustainable and renewable
and it is a resource that is found in numerous places. Despite a certain quantity of wind energy is
needed to make the installation of the wind turbine to be cost-effective, the technology is not
limited to locations such as in the case of the geothermal power source (Tyagi, 2017).
Sustainable and Renewable: Wind power is known to be both sustainable and renewable since
the supply of wind in nature and cannot get depleted unlike non-renewable energy sources such
as fossil fuels. This makes the win energy source to be an ideal source of energy for a sustainable
supply of power (Tyagi, 2017).
Low Maintenance: Wind turbines are known to require low maintenance after their installation.
A newly installed wind turbine is likely to last some duration before any maintenance work can
be performed on it. However, after few years of operation, the turbines will require low
maintenance especially on the moving parts of the turbines.
Job creation: The wind energy sector has really boomed after the introduction of wind turbines
in the market. This has led to the creation of jobs in numerous wind farms and also for the
management and maintenance operations of the wind turbines. There is also the creation of jobs
for the wind turbine manufacturer, maintenance and installation of the wind turbines within the
country (Twidell, 2015).
Free: The wind energy is a free source of energy unlike some other source of energy. There is no
market for the demand and supply of wind energy. This resource is readily available for
everyone and will never get depleted. This makes the wind power to be a viable option for
generation of cheap electricity.
High Potential: The wind power has a high potential since it is both sustainable and renewable
and it is a resource that is found in numerous places. Despite a certain quantity of wind energy is
needed to make the installation of the wind turbine to be cost-effective, the technology is not
limited to locations such as in the case of the geothermal power source (Tyagi, 2017).
Wind Energy 31
Disadvantages of Wind Energy Sources
Fluctuations: The wind energy is not a constant source of energy. Despite the wind energy being
renewable and sustainable, the wind is not always blowing at a required wind speed. This can
result in serious problems for developers of wind turbine who will normally spend substantial
money and time determining whether or not a given site is appropriate for wind power
generation. There is a need for a given location to have sufficient wind speed supply for the wind
turbines to be efficient. It is for this reason why the wind turbines are positioned out at the sea or
on top of hills where there are no obstacle to minimize the wind energy intensity (Trainer, 2010).
Noise Pollution: This is one of the most common shortcomings of the wind turbines. One wind
turbine can produce a sound that can be heard from hundreds of meters away. When numerous
wind turbines are combined, the audible effects may be much catastrophic. There are some steps
that have been taken to ensure that the noise pollution from wind turbines are greatly reduced,
such as relocation of people leaving around the site during the construction of a new wind farm
(Tiwari, 2012).
Expensive Installation: The installation of wind turbines is known to be expensive despite the
reduction in cost over time. The first step of installation involves site survey when entails
erection of a sample turbine to determine the speeds of the wind over a given duration. The wind
turbines will then need to be erected, transported, and manufactured on top of a foundation pre-
constructed. All these steps contribute to the entire cost of installation of wind turbines (Hansen,
2010).
Future Prospect of Wind Energy Sources in Australia
Disadvantages of Wind Energy Sources
Fluctuations: The wind energy is not a constant source of energy. Despite the wind energy being
renewable and sustainable, the wind is not always blowing at a required wind speed. This can
result in serious problems for developers of wind turbine who will normally spend substantial
money and time determining whether or not a given site is appropriate for wind power
generation. There is a need for a given location to have sufficient wind speed supply for the wind
turbines to be efficient. It is for this reason why the wind turbines are positioned out at the sea or
on top of hills where there are no obstacle to minimize the wind energy intensity (Trainer, 2010).
Noise Pollution: This is one of the most common shortcomings of the wind turbines. One wind
turbine can produce a sound that can be heard from hundreds of meters away. When numerous
wind turbines are combined, the audible effects may be much catastrophic. There are some steps
that have been taken to ensure that the noise pollution from wind turbines are greatly reduced,
such as relocation of people leaving around the site during the construction of a new wind farm
(Tiwari, 2012).
Expensive Installation: The installation of wind turbines is known to be expensive despite the
reduction in cost over time. The first step of installation involves site survey when entails
erection of a sample turbine to determine the speeds of the wind over a given duration. The wind
turbines will then need to be erected, transported, and manufactured on top of a foundation pre-
constructed. All these steps contribute to the entire cost of installation of wind turbines (Hansen,
2010).
Future Prospect of Wind Energy Sources in Australia
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Wind Energy 32
The rate of growth in energy consumption has however slowed gradually in the past
decade. This decline in the amount of energy consumed in the country can be explained by the
economic crises and oil price shocks during the past few years. The demand for energy is
expected to continue increasing and the future distribution of these energy sources will be
determined by numerous factors such as energy price and government policies. These are the
major reasons why the wind energy source has a future prospect in the country. The growth of
wind power energy source is rapidly increasing in numerous geographical locations within the
country, this is the major reason for selection of wind energy as an alternative energy source for
Australia and not any other renewable energy source such as hydroelectricity or solar power
energy sources (Healey, 2013).
The government in different territories in the country has set a diverse target for the
generation of electricity from wind energy to ensure its future prospects. The expected target for
the electricity generation for Victoria is has been set to be at 25% and for New South Wales is
set at 20% of the total energy generated by the year 2020. The setting of targets in different
territories has led to the installation of wind, solar, and hydropower plants in different territories.
Wind energy source is a rapidly expanding mode of renewable energy generation in Australia
with an average yearly installed capacity growth rate of 35% over the last 5 years up to 2011.
There were 4455 MW of installed capacity and another 18823 megawatts committed or proposed
capacity as at December 2017. The wind farms in Australia generates an average of 30 to 35% of
the capacity factor which makes wind energy source an attractive alternative energy source
(Johansson, 2012).
The rate of growth in energy consumption has however slowed gradually in the past
decade. This decline in the amount of energy consumed in the country can be explained by the
economic crises and oil price shocks during the past few years. The demand for energy is
expected to continue increasing and the future distribution of these energy sources will be
determined by numerous factors such as energy price and government policies. These are the
major reasons why the wind energy source has a future prospect in the country. The growth of
wind power energy source is rapidly increasing in numerous geographical locations within the
country, this is the major reason for selection of wind energy as an alternative energy source for
Australia and not any other renewable energy source such as hydroelectricity or solar power
energy sources (Healey, 2013).
The government in different territories in the country has set a diverse target for the
generation of electricity from wind energy to ensure its future prospects. The expected target for
the electricity generation for Victoria is has been set to be at 25% and for New South Wales is
set at 20% of the total energy generated by the year 2020. The setting of targets in different
territories has led to the installation of wind, solar, and hydropower plants in different territories.
Wind energy source is a rapidly expanding mode of renewable energy generation in Australia
with an average yearly installed capacity growth rate of 35% over the last 5 years up to 2011.
There were 4455 MW of installed capacity and another 18823 megawatts committed or proposed
capacity as at December 2017. The wind farms in Australia generates an average of 30 to 35% of
the capacity factor which makes wind energy source an attractive alternative energy source
(Johansson, 2012).
Wind Energy 33
PROGRAM OF WORK
Activities Wee
k 1
Wee
k 2
Wee
k 3
Wee
k 4
Wee
k 5
Wee
k 6
Wee
k 7
Wee
k 8
Wee
k 9
Wee
k 10
Wee
k 11
Wee
k 12
Wee
k 13
Wee
k 14
Selection
of project
superviso
r
Collection
of data
Outline of
project
Project
Proposal
Literature
review
Progress
Report
Presentati
on work
Analysis
of
statestics
Submissi
on of
Final
Report
Final
presentati
on of
project
CHAPTER 4
CONCLUSION
The major objective of this research paper is to evaluate the wind energy as an alternative
source of energy in Australia. The renewable sources only make up to 2% of the total primary
production of energy whereas coal dominated the production of energy with 61% of the total
generation and crude oil accounted for only 6% of the total energy generated between the period
of 2009 and 2010. The growth of wind power energy source is rapidly increasing in numerous
geographical locations within the country, this is the major reason for selection of wind energy as
an alternative energy source for Australia. Wind energy source uses the flow of air through the
PROGRAM OF WORK
Activities Wee
k 1
Wee
k 2
Wee
k 3
Wee
k 4
Wee
k 5
Wee
k 6
Wee
k 7
Wee
k 8
Wee
k 9
Wee
k 10
Wee
k 11
Wee
k 12
Wee
k 13
Wee
k 14
Selection
of project
superviso
r
Collection
of data
Outline of
project
Project
Proposal
Literature
review
Progress
Report
Presentati
on work
Analysis
of
statestics
Submissi
on of
Final
Report
Final
presentati
on of
project
CHAPTER 4
CONCLUSION
The major objective of this research paper is to evaluate the wind energy as an alternative
source of energy in Australia. The renewable sources only make up to 2% of the total primary
production of energy whereas coal dominated the production of energy with 61% of the total
generation and crude oil accounted for only 6% of the total energy generated between the period
of 2009 and 2010. The growth of wind power energy source is rapidly increasing in numerous
geographical locations within the country, this is the major reason for selection of wind energy as
an alternative energy source for Australia. Wind energy source uses the flow of air through the
Wind Energy 34
turbines to the electric generators of mechanical power wind farms are composed of numerous
individual wind turbines which are joined to the network of electric power transmission.
Some of the factors that affect the output of wind power generated include rotor area,
physical effects of obstacles such as mountains, wind velocity, air density, earth rotation, the
cooling effect of the polar ice caps and oceans, the heat from the sun, temperature gradient
between sea and land. Some of the wind farms in Australia include Musselroe Wind Farm,
Waubra Wind Farm, Portland Wind Farm, Collgar Wind Farm, Ararat Wind Farm, Lake Bonney
Wind Farm, Hornsdale Wind Farm, Hallett Wind Farm, Snowtown Wind Farm, and Macarthur
Wind Farm. Some of the advantages of the wind power source include renewable source, eco-
friendly, low operation cost, exponential growth, huge potential, job creation, low maintenance,
free resource, renewable and sustainable. Some of the disadvantages of the wind energy sources
include fluctuations of wind resource, expensive installation, and noise pollution.
turbines to the electric generators of mechanical power wind farms are composed of numerous
individual wind turbines which are joined to the network of electric power transmission.
Some of the factors that affect the output of wind power generated include rotor area,
physical effects of obstacles such as mountains, wind velocity, air density, earth rotation, the
cooling effect of the polar ice caps and oceans, the heat from the sun, temperature gradient
between sea and land. Some of the wind farms in Australia include Musselroe Wind Farm,
Waubra Wind Farm, Portland Wind Farm, Collgar Wind Farm, Ararat Wind Farm, Lake Bonney
Wind Farm, Hornsdale Wind Farm, Hallett Wind Farm, Snowtown Wind Farm, and Macarthur
Wind Farm. Some of the advantages of the wind power source include renewable source, eco-
friendly, low operation cost, exponential growth, huge potential, job creation, low maintenance,
free resource, renewable and sustainable. Some of the disadvantages of the wind energy sources
include fluctuations of wind resource, expensive installation, and noise pollution.
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Wind Energy 35
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Wind Energy 38
Appendix 1: Price of Electricity
Appendix 1: Price of Electricity
Wind Energy 39
Appendix 2: Levelized Cost of Energy for Different Energy
Resources
Appendix 2: Levelized Cost of Energy for Different Energy
Resources
Wind Energy 40
Appendix 3: Wind Power Generation, top 10 countries
Appendix 3: Wind Power Generation, top 10 countries
1 out of 40
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