Background
Introduction
2.1
This chapter begins with a brief outline of Australia's warming climate
and the extreme weather events associated with climate change. It then looks at
the implications of climate change and extreme weather events for Australia's
electricity infrastructure. Australia's commitments under the Paris Climate
Agreement are outlined, followed by a summary of the emissions in Australia's
electricity sector. This is followed by a section on the main generation
technologies currently used in Australia. The chapter then examines the
National Electricity Market (NEM) and its regulatory framework, before
concluding with a summary of the challenges facing the NEM as it moves towards
a low and ultimately zero emissions energy future.
A warming world
2.2
Australia's climate is warming. The average air temperature has increased
by around 0.9 degrees Celsius since national records began in 1910. Since the
1950s, each decade has been warmer than the preceding decade.[1]
2.3
The Australian Academy of Science explains that human activities are
amplifying the 'greenhouse effect' that is causing global warming:
Human activities are increasing greenhouse gas concentrations
in the atmosphere. This increase is extremely likely to have caused most of the
recent observed global warming, with CO2 being the largest
contributor. Some observed changes in Australia's climate, including warming
throughout the continent and drying trends in the southwest, have been linked
to rising greenhouse gas concentrations.[2]
2.4
The Australian government recognises the scientific evidence that the
warming climate is predominantly due 'to the observed increases in human
activities such as the burning of fossil fuels (coal, oil, and natural gas), agriculture
and land clearing'.[3]
2.5
Nevertheless, during the course of the inquiry, witnesses were required
to explain that the scientific academies of the world, including the United
States, Britain, Germany, France, all the countries of Europe, Russia, China
and India, as well as Australia, are 'clearly of the view that the link between
carbon dioxide and other greenhouse gas emissions and climate is a real one,
and that humans have contributed the major part of the increase in greenhouse
gases in the atmosphere over recent times'.[4]
2.6
Australia's warming climate has brought an increase in the severity of
extreme weather events such as flooding, fire and drought. Indeed, Australia
has already experienced the effects of climate change, particularly 'increases
in extreme weather including longer and more severe heatwaves, increased
bushfire weather, increased intensity of extreme rainfall events'.[5]
2.7
According to the Commonwealth Scientific and Industrial Research
Organisation (CSIRO) and the Bureau of Meteorology, under all future emissions
scenarios, Australia will experience, amongst other effects of climate change,
more heat extremes, more intense extreme rainfall events, a greater proportion
of high intensity storms, more extreme fire-related weather in southern and
eastern Australia, and a greater frequency of extreme drought.[6]
Committee view
2.8
The overwhelming weight of scientific evidence from around the world
indicates that human activities are, in large measure, driving climate change.
Furthermore, the scientific evidence indicates that climate change has already
caused an increase in extreme weather events in Australia and will do so to an
even greater extent in the future.
2.9
That the committee feels compelled to reiterate these basic facts about the
scientific evidence is a damning indictment of the dire state of political
discourse on the science of climate change in this country.
Implications of climate change for electricity networks
2.10
The economic consequences of extreme weather events are already
substantial, and these negative impacts and economic costs are predicted to
become vastly larger as the effects of climate change intensify. The committee
received evidence from a range of submitters and witnesses, including
electricity network providers, that a warming world poses significant challenges
to the security and resilience of Australia's electricity infrastructure.
2.11
The CSIRO set out the enormous increase in the damage wrought on
critical infrastructure by the rise in extreme weather events:
About $450 million has been spent each year by governments on
critical infrastructure restoration, which could rise to $17 billion by
2050...the total economic costs...of natural disasters in Australia in 2015
exceeded $9 billion, which is expected to double by 2030 and reach $33
billion per annum by 2050...Both historical climate observations and climate
projections into the future indicate that the frequency and intensity of many
extreme weather events are on the rise. For this reason, there are likely to be
significant benefits in directing investments towards mitigation efforts
including improving infrastructure resilience to extreme weather events.[7]
2.12
The Electrical Trades Union drew attention not only to the impact of
extreme weather events on electricity infrastructure, but also to the
interdependency of electrical and other critical infrastructure:
The economic threat posed by the impacts of natural disasters
to the Australian economy is staggering. More than a fifth of Australia's
economic output is at high or extreme risk of disruption from cyclones, while
more than a quarter of national gross domestic output is located in areas with
high to extreme risk of flooding. Analysis undertaken by SGS Economics &
Planning found that 11 per cent, or $175 billion of national GDP, is located in
areas subject to bushfire. Natural disasters and other large scale events that
impact on electricity networks affect not only the electrical infrastructure in
communities, but also many other infrastructure sectors, which are all
interdependent with the electrical system...and often span several states and/or
regions.[8]
2.13
Energy Networks Australia is the association that represents Australia's
energy grid, supporting over 900,000 kilometres of electricity transmission and
distribution lines. Mr John Bradley, Chief Executive Officer of Energy Networks
Australia told the committee that:
Implications of climate change for our networks are
significant, with potential for sea level rise, increased frequency and
severity of extreme weather events and related events, including storms, cyclones,
heat waves and bushfires. Given the long life of energy network assets,
investment decisions made today must incorporate risk assessments from a whole
diverse range of factors, including future climate change.[9]
2.14
Professor Ross Garnaut reminded the committee that the impact of extreme
temperatures on electricity infrastructure can have disastrous consequences:
In the state of Victoria, the formal conclusions of the
inquiry into the bushfires noted not only the role of extreme heat but also
that developments through the interactions of extreme heat with electricity
transmission contributed to the bushfires themselves.[10]
2.15
The Northern Alliance for Greenhouse Action pointed out that higher
temperatures would place a greater burden on electricity networks as they work to
meet a projected increase in peak demand:
...the cost to energy networks from climate change is estimated
to be $2.5bn over the next five years...the largest proportion of this cost
arises from the requirement to augment networks to accommodate the increase in
peak demand largely associated with air-conditioning use [although] this is
likely to be a conservative estimate as the past few years have seen increased
bushfire activity, increased intensity of storm events, and hotter and drier
conditions.[11]
Paris Climate Agreement
2.16
There is now global recognition of the catastrophic effects that will
result without concerted efforts to dramatically reduce greenhouse gas
emissions resulting from human activity.
2.17
The Paris Climate Conference (COP21) in December 2015 involved 195
countries signing the 'first-ever universal, legally binding global climate
deal' setting out a global action plan to limit global warming to below 2°C.[12]
2.18
For the Paris Agreement to enter into force, at least 55 countries
representing at least 55 per cent of global emissions were required to deposit
their instruments of ratification. This was achieved when the European Union formally
ratified the agreement, and it entered into force on 4 November 2016.[13]
2.19
Following a recommendation by the Joint Standing Committee on Treaties,[14]
the Prime Minister the Hon Malcolm Turnbull MP announced on 10 November 2016 that
Australia would ratify the Paris Agreement:
The negotiation of the Paris Agreement was a turning point in
the global transition to a lower emission future. Australia was one of more
than 170 countries to sign the Agreement when opened for signature at the
United Nations in New York in April 2016
...
Ratification of the Agreement confirms Australia's ambitious
and responsible target to reduce emissions by 26 to 28 per cent below 2005
levels by 2030. This target is comparable with other advanced economies and
will halve our per capita emissions making it one of the highest targets in the
G20 on that basis.[15]
Emissions in Australia's electricity
sector
2.20
Australia's obligations under the Paris Agreement have a direct impact
on the electricity sector because Australia's fossil fuel electricity
generators, coal in particular, are a major source of greenhouse gas emissions.
2.21
In its 2016 report on policy options for Australia's electricity supply
sector, the Climate Change Authority noted that coal-fired power accounted for
88 per cent of the emissions from electricity generation:
Of the generation sources that produce emissions, brown coal
is the most emissions-intensive—that is, it produces the most greenhouse gas
emissions per unit of generation—followed by black coal and gas...The total
emissions from each fuel depend on the emissions intensity of the fuel itself
and what share of total generation it makes up...Coal produces around 88 per cent
of generation emissions, 35 per cent from brown coal and 53 per cent from black
coal.[16]
2.22
Australia has an ageing fleet of high emissions coal-fired electricity
generators. There are currently 24 coal-fired power stations operating in
Australia. Nine coal-fired power stations were closed between 2010 and 2016 across
the following states: New South Wales (three closures), Queensland (two
closures), Victoria (two closures) and South Australia (two closures).[17]
In addition, Australia's oldest and most polluting power station, Hazelwood in
the La Trobe Valley in Victoria, closed its doors at the end of March 2017.[18]
Australia's Electricity Generation
2.23
The following sections outline the main sources of power generation
currently used in Australia, and the issues that the various generation technologies
face as Australia and the rest of the world shifts to a low-emissions future.
Coal
2.24
Coal produced around 63 per cent of Australia's electricity in 2014–15,
with black coal providing around 43 per cent and brown coal around 20 per cent.[19]
2.25
Within the NEM, coal accounts for 78 per cent of electricity generation
and gas 9.9 per cent.[20]
Coal-fired power is in structural
decline
2.26
The imperative to address climate change by reducing greenhouse gas
emissions has meant that the generation of electricity from coal-fired power
stations is in structural decline as the world moves rapidly towards an
economic transformation underpinned by clean energy sources.
2.27
It is crucial to recognise that the shift away from coal is being driven
by the major energy players in the market. The committee received a raft of
evidence that coal-fired generation has no future. Indeed, Australia's largest
energy companies were quite clear that they have no intention of investing in
coal-fired generation.
2.28
For example, Mr Jim Kouts, Head of Corporate Affairs at ENGIE in
Australia, told the committee that 'we are moving out of coal'.[21]
2.29
Similarly, AGL Energy Limited's (AGL) Greenhouse Gas Policy states that
AGL will not build, finance or acquire new conventional coal-fired power
stations in Australia, nor extend the operating life of any of its existing
coal-fired power stations.[22]
2.30
When asked whether some gas-fired stations could be replaced with
coal-fired stations as a way of dealing with the current domestic gas shortage,
Mr Richard Wrightson, General Manager of Wholesale Markets at AGL, told the
committee that AGL had no interest in developing further coal-fired power:
The issue is: can you then build coal to replace them in any
meaningful time frame? It is not an area AGL, from a policy perspective, is
interested in developing. Obviously we will use our existing coal assets to
their maximum so that we can cover off our risk and exposures, but it is not an
area that we see longer term being the key. It is about how you can develop
renewables into that space and how you can firm up renewables and make them
reliable for the system so that we can use those to support our customer base.[23]
2.31
AGL called for 'a market rule that suitably telegraphs the phase-out of
legacy power plants' after 50 years.[24]
They explained to the committee that:
This will enable market participants to plan and invest in
the necessary generation and associated infrastructure. It will also minimise
the impacts of short-notice periods for closure on wholesale electricity
supplies, such as those experienced with the impending closure of the Hazelwood
power station and the recent closures of the Northern and Playford coal power
stations in South Australia.[25]
2.32
AGL explained that a 50 year lifespan is being applied to their own
facilities:
...at 50 years of age we say the end of tactical life has been
achieved and you should shut down the unit. That is the process that we have
established as part of our greenhouse gas policy that in 2022 will shut down
the Liddell facility, in 2035 our Bayswater facility and in 2048 our Loy Yang
facility.[26]
Lack of investment prospects for
coal fired power projects
2.33
Not only are the electricity generators getting out of coal, but
investors have also deserted coal because it is simply uneconomic and the risks
of investing in what will become stranded assets are too high.
2.34
For example, the Clean Energy Finance Corporation explained why it is
highly unlikely to follow the Commonwealth government's suggestion to fund new
coal-fired power stations, explaining that:
...in a market of such volatility it would be very difficult to
find a private sector or a commercial investor making a decision to invest in a
coal-fired power station in the Australian market today. So we, like a
commercial investor, are very unlikely to find circumstances in which that
would be an appropriate investment to expose the taxpayers to. Remember, we are
investing the taxpayers' money. They are expecting us to operate commercially
and carefully with that money, and we have to assess all of the investments
appropriately.[27]
2.35
Mr John Grimes, Chief Executive Officer of the Australian Solar Council,
expressed similar views, telling the committee that banks are almost
universally pulling out of coal, and that many large proposed coal projects
will not be financed.[28]
2.36
The corollary of the move away from coal by energy companies is an
increase in the use of other energy technologies to generate electricity.
However, gas-fired power generation faces significant obstacles as set out
below. Renewable energy technologies are summarised in subsequent sections, and
the solutions to issues of intermittency are covered in chapter 3.
Gas
2.37
Gas fired power stations accounted for approximately 21 per cent of
Australia's total electricity generation in 2014–15.[29]
2.38
The role of gas in Australia's future energy mix is a matter of
significant debate at the current time, due to its potential as a replacement
for coal-fired baseload generation, and shortage and price issues in the
Australian domestic gas market. The committee heard diverse evidence about the
future role of gas in Australia's energy future.
2.39
Professor Garnaut noted that back in 2008 the Garnaut Climate Change
Review saw a significant role for gas as a transition fuel that could be
used to balance the intermittent sources of electricity provided by renewables.
However, he explained that developments since then have reduced the potential
for gas to fulfil that transition role:
Since then the price of gas has increased several fold,
incidentally at a time when there has been a dramatic reduction in the price of
gas in the rest of the world—roughly a falling by half to two-thirds in the
United States at time when there has been trebling or more of domestic gas
prices in Australia. That is a challenge for keeping down the cost of the transition
to renewables. It means that the economically efficient role of gas is smaller
than it would have been.[30]
2.40
AGL told the committee that they 'see natural gas as being a necessary
transition fuel over the next 10 to 20 years'.
[31]
2.41
Similarly, ENGIE told the committee that gas-fired generation will continue
to play a key role in the transition to a renewable energy economy:
Five to 10 years ago gas was often referred to as a
transitional fuel. I think gas-fired generation is the transitional fuel.
Looking at the technology that is before us, whether you are out at solar
thermal, solar PV or wind, I think gas has a big part to play as we transition...
Most experts agree that gas is the transitional fuel as we work our way through
the technology.[32]
2.42
However, the committee heard that the move away from a carbon price
signal has reduced the advantage that natural gas would have over coal as a
lower-emissions fuel source:
The challenge for gas has been exacerbated by the move away
from carbon pricing. Carbon pricing recognises the advantage of gas over coal.
It penalises coal more heavily than gas... I note that, as with the old
Australian form of carbon pricing, a carbon intensity scheme would restore the
differential treatment of gas and higher-emissions sources of fossil energy.[33]
Problems with the domestic
east-coast gas market
2.43
Despite the views expressed above by the energy companies that gas has a
role as a transition fuel, the committee heard a raft of evidence that the domestic
east-coast gas market faces significant problems. These problems have been highlighted
in South Australia. AGL argued that:
South Australia is heavily reliant on gas now with the
closure of Northern [coal-fired] power station, and I would claim there is a
fair dysfunction in the gas market, which has created most of the systemic
problems we are seeing in South Australia.[34]
2.44
AGL told the committee that there is limited access to flexible gas
contracts in South Australia:
So one of the major reasons the contract market has become so
illiquid in South Australia, which is a sure sign that you have problems at a
competition level, is the inability to source gas flexibly so that we can make
decisions to come in and come out of that market and to contract or not. We
would love to be able to contract more in that marketplace. One of the main
restrictors on being able to do that is access to flexible gas contracts that
we are able to trade in and out of.[35]
2.45
AGL told the committee that building new power stations in South
Australia is not feasible because access to gas remains limited:
AGL would love to build a new power station to replace TIPSA
[Torrens Island Power Station near Adelaide]. We want to maintain our customer
base in South Australia and we would like to build a new power station. But if
you cannot access gas to run it, it is not a feasible opportunity, and that is
basically why you have had no new power stations announced in South Australia.
People are trying to resolve how they access fuel to run those power stations
on a consistent basis. There will be a way, and we will work it through, but
access to gas is critical to that.[36]
2.46
Beyond the supply problems in the east-coast gas market, AGL outlined a second
dilemma facing energy companies, namely that battery prices may fall rapidly
enough to render investment in new gas-fired generation redundant:
Do you develop gas fast enough to beat battery technology in?
I do not know the answer to that question, but that will be one of the key
things. Can we develop enough gas to make building fast-start gas peakers, an
answer to intermittency—or given the gas restrictions in Australia will battery
costs beat that through? I do not know the answer.[37]
2.47
Finally, Mr Simon Corbell, the Victorian Renewable Energy Advocate, drew
attention to a third issue relevant to any decision on developing new gas-fired
generating capacity. He warned that any new investment in gas generation risks
repeating the experience of coal with stranded assets:
...any policy setting that provides for support for gas-fired
generation should have regard to the fact that you do not want to create a
situation where you have stranded assets in gas-fired generation in 20, 30 or
40 years time in the same way that we currently experience in relation to
coal-fired generation. [38]
Solar
2.48
Australia has a high capacity for solar power generation. According to
Geoscience Australia:
The Australian continent has the highest solar radiation per
square metre of any continent and consequently some of the best solar energy
resource in the world.[39]
2.49
Solar power is generated when sunlight is converted into electricity or
used to heat air, water or other materials and is usually generated using one
(or both) of two major technologies:
-
solar thermal, which converts solar radiation into heat (thermal
energy); and
-
solar photovoltaic (PV), which converts sunlight into electricity
directly by using photovoltaic cells.[40]
2.50
Solar thermal electricity is often used for space heating, to generate
electricity using steam (as the water is heated with solar heat), and for hot
water heaters.[41]
2.51
The vast majority of the electricity generated from solar PV comes from
small-scale rooftop installation. As at 20 March 2017, there were over 1.6
million solar PV panel systems in Australia with a rated output of just over
5500 MW, and over 1 million solar hot water heaters.[42]
2.52
The Australian Bureau of Statistics (ABS) notes that the average size of
roof top solar PV has increased as the price of panels has come down:
The average size of an installed roof-top solar PV system in
Australia is currently just under 4 kW in capacity. In recent years, driven
largely by falling prices for solar PV panels, the average size of systems has
increased and are often over 5 kW in capacity.[43]
2.53
However, solar PV can be scaled up to megawatt scale power plants. At
the end of 2015, Australia had 17 solar PV farms larger than 1 MW in size with
the two largest being the 102 MW facility in Nyngan, New South Wales (NSW) and
the 53 MW facility in Broken Hill, NSW.[44]
Wind
2.54
According to the Australian Energy Resource Assessment, Australia has
some of the best wind resources in the world, in the south-western, southern
and south-eastern margins and extending inland, and including highland areas in
south-eastern Australia.[45]
2.55
In contrast to solar PV, the vast majority of electricity generated by
wind comes from large-scale wind farms. In 2015, there were 76 wind farms in
Australia, with a combined capacity of 4187 MW from more than 2000 turbines.[46]
In addition to this large-scale infrastructure, as at 20 March 2017, more than
400 small-scale wind systems have been installed in Australia, with a rated
output of approximately 1.4 MW.[47]
2.56
Wind resources are currently prioritised within the NEM because wind
energy is automatically dispatched. This means that electricity generated from
wind is used before other, more controllable, sources are dispatched.[48]
Hydroelectricity
2.57
As at 2014, Australia had 124 operating hydroelectricity plants, with a
total installed capacity of 8500 MW. The main hydro resources in Australia are
in NSW and Tasmania.[49]
2.58
Hydroelectricity provided around 40 per cent of renewable energy in
2014–15.[50]
Although hydroelectricity currently accounts for the largest share of
Australia's renewable electricity, the potential for future growth of hydroelectricity
generation in Australia is limited by issues of water availability:
Climate models suggest long-term drying over southern areas
of Australia during autumn and winter, which will be superimposed on larger
natural rainfall variability, resulting in Australia having variable surface
water resources.[51]
2.59
The future growth of hydroelectricity is likely to be limited to 'the
development of small-scale hydroelectricity plants and efficiency gains from
the refurbishment of large-scale hydroelectricity plants'.[52]
2.60
Similarly, the Australian Renewable Energy Agency (ARENA) has stated
that 'most major hydropower opportunities in Australia have already been
realised' and:
In the future there may be some growth in use of 'mini-hydro'
schemes—which can be 'run-of-river', with no dam or water storage, or developed
using existing or new dams whose primary purpose is local water supply, river
and lake water-level control, or irrigation.[53]
The National Electricity Market (NEM)
2.61
The NEM is the wholesale electricity market for the eastern and southern
Australian states and includes Queensland, NSW (including the Australian
Capital Territory(ACT)), South Australia, Victoria and Tasmania.[54]
2.62
Western Australia and the Northern Territory are the only Australian
state and territory not connected to the NEM, largely due to the distances that
would be involved in their connection to the network. These areas have their
own electricity systems and regulatory arrangements. Power in WA is supplied by
the Wholesale Electricity Market (WEM) which has been operated by the Australian
Energy Market Operator (AEMO) since 2016.[55]
2.63
The NEM is described as follows:
The NEM facilitates the exchange of electricity between
generators and retailers. Retailers resell the electricity to business and
households. Some large consumers also purchase electricity directly from the
market. High voltage transmission lines transport electricity from generators
to electricity distributors, who deliver it to homes and businesses on lower
voltage 'poles and wires'.[56]
2.64
There are more than 100 registered participants in the NEM, including
market generators, transmission network service providers, distribution network
service providers, and market customers.[57]
2.65
One of the issues raised by witnesses was the vulnerability brought
about by having a long, thin grid. The Australian Academy of Science,
Technology and Engineering (ATSE) stated:
Our view is that the Australian grid suffers particularly
because it is a long, thin grid and South Australia and Queensland are particularly
vulnerable to that because they are at the ends of a very long, thin line. In
South Australia's case there are only a few interconnections into Victoria.[58]
2.66
The committee heard that ATSE has modelled improvements to the NEM based
on further interconnections:
...modelling that has been done by fellows of the academy that
looks at increased interconnections, either through New South Wales or indeed
through South Australia to Queensland, to create a loop of the NEM that would,
potentially, relieve some of those issues and then you can spread out the
weather variation across a larger area.[59]
Regulatory framework
2.67
The NEM is governed by a set of regulatory bodies—the Australian Energy
Market Operator (AEMO), the Australian Energy Market Commission (AEMC), and the
Australian Energy Regulator (AER)—established through the Australian Energy
Market Agreement, an intergovernmental agreement developed through the COAG
process and signed by the leaders of state, territory and Commonwealth
governments in its initial form in 2004.[60]
Australian Energy Market Operator
(AEMO)
2.68
AEMO is responsible for managing the power grid in the NEM and its
secure operation.[61]
Mr David Swift, Executive General Manager of Corporate Development at AEMO,
outlined its operational role as follows:
AEMO operates the National Electricity Market in eastern and
south-eastern Australia and manages the power system underpinning it. AEMO is
also the market and power system operator in Western Australia. In gas, we
operate a range of wholesale and retail gas markets and trading hubs around
Australia.[62]
2.69
The NEM works as a 'pool' or 'spot' market in which supply and demand of
power is matched in real time through a centrally coordinated dispatch process.
A generator of power offers to supply the market with a specified amount
of electricity at a specified price for a set time period, although they can
re-submit the offered amounts at any time. AEMO will decide from these bids
which generator will supply the electricity to the grid, with the cheapest
generator being used first.[63]
2.70
AEMO also has 'planning roles across both electricity and gas markets
that aim to inform market participants, regulators and policymakers'.[64]
Significantly, AEMO is responsible for the development of national forecasts of
electricity and gas demand. Mr Swift stated:
Electricity demand is forecast annually, down to the
transmission connection point. We plan the Victorian transmission system and
publish material on that. We undertake national planning and produce a National
Transmission Network Development Plan. We also provide occasional papers from
time to time, looking at specific issues.[65]
2.71
Mr Swift pointed out that while 'AEMO operates the systems and markets,
it does not own any physical assets such as pipelines, transmission towers or wind
farms'.[66]
Australian Energy Market Commission
(AEMC)
2.72
Mr John Pierce, Chairman of the AEMC, explained the regulatory role of
the AEMC as follows:
We are the rule maker for the Australian energy markets,
which includes the rules that govern...the NEM, the transmission and distribution
networks, wholesale gas markets, natural gas pipelines and the retail sale of
energy to consumers.[67]
2.73
Mr Pierce described the process for changing the market rules made by
the AEMC as follows:
Anyone except the Australian Energy Market Commission itself
can propose to us a change in those rules, so those rules evolve over time in
response to proposals for changes that are put to the commission. In that
sense, the future development and evolution of the market framework is in the hands
of the market participants, the other market institutions, governments,
consumer groups, environment groups and various stakeholders within the sector.[68]
2.74
Mr Pierce advised that since the AEMC was established in 2005, there
have been 'about 214 different changes in the rules'.[69]
2.75
The AEMC's review function was described by Mr Pierce as follows:
[W]e also undertake reviews that are normally under terms of
reference issued by the COAG Energy Council where they are seeking advice on
how improvements to the regulatory and energy market arrangements may be made.
A short way to understand how this process works is that, if somebody thinks
that there is a problem and they think they also know what the solution is,
they will put a rule change to us. If governments think that there is an issue
and want potential solutions explored, that is when they tend to ask us to do a
review. Recently, in addition to our statutory functions, the commission has
been provided with terms of reference from the COAG Energy Council, requesting
what is referred to as 'targeted strategic advice to inform the council's
energy market strategy and priority setting process', so that will form part of
our work program for this year.[70]
2.76
All of the AEMC's work is governed by three national energy policy
objectives: the national electricity objective, the national gas objective and
the national energy retailer objective. Mr Pierce explained in relation to
these objectives:
They are three different objectives, but they all sort of
have a common theme, which is referred to as 'promoting the long-term interests
of consumers' but with respect to a very specific set of variables: price,
quality, reliability and security of those energy services as well as the
system as a whole.[71]
2.77
The AEMC currently has four suggested priority areas in terms of market
development, namely:
-
systems security;
-
the integration of the mechanisms used to achieve
emission-reduction policy objectives and energy policy objectives so that they
are aligned and work together;
-
redesigning the way in which gas is bought and sold in gas
markets; and
-
the promotion of a competitive retail energy services sector.[72]
Australian Energy Regulator (AER)
2.78
The AER regulates energy markets and networks under national energy
market legislation and rules, with functions including:
-
monitoring wholesale electricity and gas markets to ensure energy
businesses comply with the legislation and rules, and taking enforcement action
where necessary;
-
setting the amount of revenue that network businesses can recover
from customers for using networks (electricity poles and wires and gas
pipelines) that transport energy;
-
regulating retail energy markets in Queensland, NSW, South
Australia, Tasmania (electricity only) and the ACT; and
-
publishing information on energy markets, including the annual
State of the energy market report, to assist participants and the wider
community.[73]
2.79
Ms Michelle Groves, Chief Executive Officer of the AER, informed the
committee that it has been undertaking work in recent times aimed at ensuring
that the regulatory framework meets the challenges currently facing it. This
work includes:
-
developing new 'ringfencing' guidelines preventing networks from
favouring their own affiliates over other businesses offering competitive
energy services, such as rooftop solar, smart appliances and storage;
-
working to implement more cost reflective network tariffs, to
help consumers make informed decisions on how and when they should use
electricity as new technologies evolve; and
-
developing a new demand management incentive scheme and
innovation allowance which will provide electricity distribution businesses
with an incentive to undertake efficient expenditure on non-network options
relating to demand management.[74]
Clarity around responsibilities of
regulatory bodies
2.80
An issue of concern raised with the committee has been possible
uncertainty about the responsibilities of the different regulatory bodies
involved in the NEM, particularly during power outages. AEMO explained the
particular responsibilities of each body in relation to the South Australian
system failure event in 2016:
In terms of the real-time event and the behaviour on the day,
that is clearly our responsibility. In respect of the behaviours of parties and
whether they complied with the rules, that would be the AER's responsibility.
Then when we look at policies and rules that gets back to the COAG Energy
Council and the AEMC.[75]
Issues facing the NEM
2.81
Stakeholders to the inquiry identified various issues that have
seriously undermined the functioning of the NEM and that need to be resolved in
order for Australia's electricity market to function effectively into the
future. In addition to the physical impacts of a changing climate on electricity
infrastructure (discussed in earlier sections), major issues cited by
submitters and witnesses included:
-
reduced and changing patterns of electricity demand from the grid;
-
the integration of intermittent renewable energy into the grid;
-
the uptake of energy storage solutions and decentralised forms of
electricity generation without the necessary changes to the structure and rules
of the electricity market to facilitate this; and
-
a protracted period of policy uncertainty relating to carbon
issues, creating an environment where industry is unable to make long term
planning and investment decisions.
-
an inefficient and change-resistant regulatory authority which is
absurdly slow and has a strong bias towards incumbent players, and is
technically ignorant of modern trends in overseas markets and technology.
2.82
The changing patterns of electricity demand and usage, the integration
of intermittent renewable energy into the grid, and the uptake of energy
storage solutions and decentralised forms of electricity generation are covered
in chapter 3.
2.83
The issues arising from policy uncertainty and the need for a carbon
price signal, certainty around renewable energy targets, and necessary changes
to the structure and rules of the NEM to facilitate the uptake of storage technologies
are covered in chapter 4.
Recommendation 2
2.84
The committee recommends that the Finkel Review incorporate the
impacts of climate change on electricity security into its consideration and
recommendations.
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