uk energy scenarios 2006
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crossing the fossil and nuclear bridge to a safe, sustainable, economically viable energy futureTRANSCRIPT
Society Energy Environment SEE 1
UK ENERGY SCENARIOS
crossing the fossil and nuclear bridge to a safe, sustainable, economically viable energy future
Preliminary scenarios for discussion and development only
Mark Barrett [email protected]
Complex Built Environment SystemsUniversity College London
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Scenario development process
Introduction
Models used
Demand drivers
End use sectors
Supply sectors
Discussion• energy• emissions• economics
System dynamics and spatial issues
More international aspects
Energy security
Please note that some of the slides are animated (they have animated in the
title). View these slides for a few moments and the animation should start and keep looping back to the
beginning.
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Introduction 1
This outline of UK energy and environment scenarios has been developed with the intention of identifying the main problems the UK will face in meeting future energy needs and environmental objectives, and to describe possible policy options for resolving these problems. The approach here is to assume policy options and estimate the energy, emission and microeconomic impacts of these policy options. It is not claimed that the scenarios are optimum in that more robust and cost-effective solutions may be found. The aim is to illustrate a development path that is incremental, flexible, and secure, with no undue reliance on fuels or technologies having substantial risks.
The aims are to identify energy and environment strategies that:• enhance the security of UK energy services by reducing imported fuel dependence and technology risk• meet energy needs with safe, sustainable energy systems• limit environmental impact, with an emphasis here on:
– the greenhouse gas, carbon dioxide, – atmospheric pollutants; sulphur dioxide, nitrogen oxides, particulate matter and carbon monoxide
• are technically feasible and economically viable• give a practical development path leading from finite fuels to renewable energy
A broader aim is to consider temporal and spatial aspects of energy demand and supply, within the UK and at the international scale, to ensure technical feasibility and take account of the international context
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Introduction 2
The scenarios are designed to be practical, feasible, but are not necessarily ‘best.’ It is not possible to objectively define the best scenario because:
• although there is some agreement about goals concerning the environment, consumption, technology risk and irreversibility, market cost, subsidies, etc., the weights attached to these goals are subjective and differ between individuals and groups
• there are aspects which it will never be possible to accurately quantify, such as: what is the probability of an accident or terrorist attack on current or future nuclear facilities, and what would be its impact on the UK, even if radioactive release were negligible?
• the future evolution of technologies in the long term is uncertain; half a century ago, the UK had negligible nuclear power or natural gas supply.
Some observations:• Developments of social structure, attitudes, demand, supply, technology, etc. are all, to some extent,
determined by national policies.• Planning UK energy futures can not be done in isolation from Europe and the rest of the world, because of
global energy resources, energy trade, and international politics.• As yet there are no supply options which score highest on all criteria and therefore these must balanced
according to present knowledge. The further into the future, the greater the uncertainties with respect to demand, technology development, and the international context. As solar electricity (e.g. photovoltaic), electricity storage and long distance transmission become cheaper, then there may be agreement that other options are inferior and the ‘energy problem’ will perhaps be ‘solved.’.
No consideration is made here of how policy options would be implemented with statutory, fiscal or other instruments. A presumption is made that these would be developed and applied as necessary to secure the UK’s future energy services and economy, and to protect the environment.
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Policy options
The policy aims are to be met using five classes of option:• Behavioural change: demand, and choice and use of technologies
– demand substitution, less air travel– modal shift from car and truck to bus and rail, lower motorway speeds, building temperatures– smaller cars
• Demand management– insulation, ventilation control, recycling, efficient appliances...
• Energy efficient conversion– cogeneration...
• Fuel switching– to low/zero emission renewable and other sources
• Emission control technologies– flue gas desulphurisation, catalytic converters, particulate traps...
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Policy options
In the scenarios, technologies are excluded according to criteria of irreversibility, exposure to risk of large scale hazards, the lack of clear market costs, or if they do not work. Accordingly:
• new nuclear capacity is excluded because of irreversibility, lack of market cost because of insurance, and risk of large scale hazard.
• carbon sequestration through pumping CO2 underground is not deployed because it an irreversible technique that increases primary CO2 emissions, and the risks of accidental release in the long term are impossible to quantify reliably. It also may be argued that sequestration will diminish efforts towards energy efficiency and renewables.
• fusion is excluded because it does not work and would produce radioactive wastes.
The challenge is to construct scenarios that do not use these options.
Currently, hydrogen is not included in any scenario. This is primarily because of the low overall efficiency of producing hydrogen from electricity or gas and then converting it into motive power or heat: it wastes more primary fossil or renewable energy than using electricity as a vector. In the stationary sectors, it is better to use electricity, renewable and fossil fuels directly. In surface transport vehicles, an increasing fraction of demand can be met with electricity in hybrid electric/fossil fuelled vehicles. Hydrogen as a fuel for aircraft is a distant prospect. If the production and utilisation efficiency of hydrogen improve, or other difficulties, such as electric vehicle refuelling are insurmountable, then hydrogen would be reviewed.
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Scenarios
With these classes of options and exceptions, the aim is to show that commonly agreed social, environmental and economic objectives can be achieved with low risk.
Five scenarios combining the five classes of policy option in different ways have been simulated. Proceeding from scenario 1 to 5 results in decreased emissions and use of technologies or fuels that have irreversible impacts.
1. Base/Kyoto: base scenario2. Carbon15: medium levels of technical change3. Behaviour: behavioural change only4. Tech High: high levels of technical change5. Tech Beh: technical and behavioural change
The scenarios presented here are preliminary and for discussion because:• recent historic data were not available at the time of scenario development• many technical and economic aspects of the scenarios need a thorough review
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The energy system: demand and supply options
PRIMARY ENVIRONMENTAL IMPACT
ENERGY DEMAND ENERGY CONVERSION PRIMARY ENERGY
Finite energyFossil
Income energy
Finite energy
Fission
Geothermal
Sun
Moon
GasOil
Coal
Heat
Kinetic
Heat
Electricity
Kinetic
Light
Chemical
Cool
Generator
Waste heat
Heat pump
Chemical
Heater
Nuclear
Transport
Waste heat
ENVIRONMENTAL HEAT
Tidal
Wave
Wind
HydroHeat
Biomass
LightDomestic
Services
Industry
Heat engine
Impact Impact
Fusion
Motor
Fuel cell E
Energy demands and sources can be linked in many ways. The appropriate linkage depends on a complex of their distribution in space and time, and the economics of the technologies used.
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Integrated planning
Energy planning should be integrated across all segments of demand and supply. If this is not done, the system may be technically dysfunctional or economically suboptimal. Energy supply requirements are dependent on the sizes and variations in demands, and this depends on future social patterns and demand management. For example:
• In 2040, what will electricity demand be at 4 am? If it is small, how will it affect the economics of supply options with large inflexible units, such as nuclear power?
• The output from CHP plants depends on how much heat they provide, so the contribution of micro-CHP in houses to electricity supply depends on the levels of insulation in dwellings.
• Solar collection systems produce most energy at noon, and in the summer. The greater the capacity of these systems, the greater the need for flexible back-up supplies and storage for when solar input is low.
• The scope for electric vehicles depends on demand details such as average trip length. Electric vehicles will add to electricity demand, but they reduce the need for scarce liquid fuels and add to electricity storage capacity which aids renewable integration.
• Electricity supply systems with a large renewable component require flexible demand management, storage, electricity trade and back-up generation; large coal or nuclear stations do not fit well into such systems because their output cannot easily be varied over short time periods.
• The amount of liquid biofuels that might available for air transport depends on how much biomass can be supplied, and demands on it for other uses, such as road transport.
• Is it better to burn biomass in CHP plants and produce electricity for electric vehicles, or inefficiently convert it to biofuels for use in conventional engines?
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Models used for constructing scenarios
Some description and sample outputs are presented for the following models:
• SEEScen: Society, Energy and Environment Scenario model used for basic national energy scenarios across all sectors
• EleServe : Electricity system model used to study detailed operation of electricity system
• EST Energy Space Time model used to illustrate issues concerning time varying demands and renewable sources at geographically distant locations
• InterEnergy Energy trade model used to study potential for international exchanges of energy to reduce costs and facilitate the integration of renewable energy
More on the models may be found at:http://www.sencouk.co.uk/Energy/Energy.htm
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Technical basis: SEEScen: Society, Energy, Environment Scenario model
SEEScen is applicable to any large country having IEA energy statistics
SEEScen calculates energy flows in the demand and supply sectors, and the microeconomic costs of demand management and energy conversion technologies and fuels
SEEScen is a national energy model that does not address detailed issues in any demand or supply sector.
Method• Simulates system over years, or
hours given assumptions about the four classes of policy option
• Optimisation under development
HISTORY
FUTURE
COSTS
INPUTS / ASSUMPTIONS
IMPACTSENERGY
IEA dataEnergyPopulation, GDP
Other dataClimate, insulation...
Delivered fuel
End use fuel mix
End use efficiency
Delivered fuel by end use
Useful energy
Socioeconomic
Useful energy
Delivered energy
Lifestyle change
Demand
End use fuel mix
End use efficiency
Conversion
Primary energy
Supply efficiency
Emissions
Capital
Running Distribution losses
Supply mix
Trade
Conversion
Society Energy Environment SEE
Energy services and demand driversDemands for energy services are determined by human
needs, these include• food• comfort, hygiene, health• culture
Important drivers of demand include:• Population increases• Households increase faster because of smaller
households• Wealth, but energy consumption and impacts
depend on choices of expenditure on goods and services which are somewhat arbitrary
The drivers are assumed to be the same in all scenarios.
The above drivers are simply accounted for in the model, but others are not, for example:
• Population ageing, which will result in increases and decreases of different demands
• Changes in employment• Environmental awareness• Economic restructuring
More on consumption at:http://www.sencouk.co.uk/Consumption/Consumption.htm
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GBR: TechLifestyle: Population
SHHPop_M
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GBR: TechLifestyle: Households
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Energy demand: food
Food consumption increases with population. Therefore:• More biowaste for energy supply• Less land for energy crops, depending on import fraction• Land and energy use for food depends on food trade and factors such as the fraction of meat in the diet
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GBR: TechHigh: Food
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Future demand: general considerationsPredicting the activities that drive the demands for energy is fundamentally important, but uncertain, not least because
activities are partially subject to policy.
• Some demands may stabilise or decrease, for example:– commuting travel as the population ages and telecommunications develop– space heating as maximum comfort temperature levels are achieved
• Demands may increase because of the extension of current activities:– heating might extend to conservatories, patios, swimming pools– air conditioning may become more widespread– cars might become heavier and more powerful– as the population enjoys more wealth and a longer retirement, more leisure travel might ensue
• Or because new activities are invented, these being difficult to predict:– new ways of using energy might arise; witness home computers, cinemas, mass air travel in the past; the
future we may see space tourism
Basic activity levels are assumed to be the same in all scenarios, although in reality they are scenario dependent. For example, many activities are influenced by scenario dependent fuel prices - the purchase and use of cars, air travel, home heating.
Furthermore, energy consumption in the services sector and industrial sectors are themselves dependent on basic energy service demands. For example: energy consumption for administering public transport or aviation is dependent on the demands for those services; the energy consumed in the iron and steel or vehicle manufacturing industry depends on how many cars are made, which is scenario dependent; the energy consumption of manufacturing industry depends on how much loft insulation there is houses. The effects of energy demands on economic structure and its energy consumption are not considered here. (This is rarely analysed in energy scenarios because the effects of these structural changes may be relatively small; and it is difficult to calculate them.)
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Future demand: activity projectionsIn these scenarios, the activity growth in all sectors is assumed to follow from population, household and wealth
drivers. The activity projections are shown in the chart. The outstanding growth is in international aviation, a service the UK mainly exports.
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1419
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Inde
x199
0
Ind:Iron and steel
Ind:Chem/petrochem(inc feed)Ind:Heavy
Ind:Light
Agr:
Oth:
Ser:
Res:
Tra:Nat passenger
Tra:Nat freight
Tra:Int passenger
Tra:Int freight
GBR: TechBeh: Activity
Society Energy Environment SEE
Domestic sector
The main options exercised:
• Clothing, heating system control and thermostat setting• High levels of insulation and ventilation control • Efficient lights and appliances• Solar water heating, micro gas CHP and electric heat pumps are the main supply options• Zoned heating and clothing to reduce average house temperature
Note that solar electricity production (e.g photovoltaic) is included under central supply, even though much of it would be installed at end users’ premises.
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Comfort temperature, clothing and activityAppropriate clothing reduces energy demand and emissions. A slight improvement in clothing could reduce
building temperatures. A degree reduction in average building temperature could reduce space heating needs by about 10%.
Activity & Metabolic Rate (W/m2)
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15
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30
0.0 Naked
.3 Light
.5 Light
.8 Typical
1. Typical
1.3 Warm
1.5 Warm
1.8 Special
2. Special
Clothing level
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Building useBetter control heating systems in terms of time control and zoning of heating can reduce average internal
temperature and energy use.
3
8
13
18
23
28
Amb. Temp
Tt :Sitting
Tt :Kitchen
Tt :Bedrooms
Tr :Sitting
Tr :Kitchen
Tr :Bedrooms
Society Energy Environment SEE
Domestic sector: house heat loss factorsImplementation of space heat demand management (insulation, ventilation control) depends on housing needs
and stock types, replacement rates, and applicability of technologies. Insulation of the building envelope and ventilation control can reduce house heat losses to minimal levels.
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W/o
C
Vent loss
Roof
Window
Wall opaque
Floor
GBR: TechBeh: W/oC : Elements
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House: monthly space heating and cooling loads
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1.0
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GJ/
mon
th
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oC
Gross
Incidental gain
Solar
Heat
Cool
Ambient temperature
Equilibrium temperature, noheating/coolingThermostat temperature
United Kingdom 2005 : TechLifestyle Scenario : House temperatures and heat flows
-2.0
-1.5
-1.0
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mon
th
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oC
Gross
Incidental gain
Solar
Heat
Cool
Ambient temperature
Equilibrium temperature, noheating/coolingThermostat temperature
United Kingdom 2050 : TechLifestyle Scenario : House temperatures and heat flows
Energy conservation technologies have these effects:
• Space heating demand is greatly reduced by insulation and other measures
• The potential growth in air conditioning depends on detailed house design and temperature control
• There is less seasonal variation in total heat demand
Society Energy Environment SEE
Domestic sector: useful energy services per household• Space heating reduced, but not comfort• Other demands eventually grow because of basic drivers• Water heating becomes a large fraction of total, demand management requires further analysis
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GJu
/h
Cool
Space AC
Space H
Water H
Cooking
Light
El equip
GBR: TechBeh: Residential : Useful
Society Energy Environment SEE
Domestic sector: electricity useElectricity demand is reduced because of more efficient appliances, including heat pumps for space heating.
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AirCon_EH
HeatOff_EH
Heater_EH
Heater_EH
Cooker_EH
CWash_EW
Freezer_EH
Refrig_EH
Refrig_EH
DishW_EW
CWash_EW
Light_EL
Equip_E
GBR: TechBeh: Residential : Electricity
Society Energy Environment SEE
End use sectors: energy delivered to services sector
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H_Solar
H_Pipe
E_
S_CHP
L_CHP
G_CHP
S_
L_
G_
GBR: TechBeh: Services : fuel by sector
More commentary to follow.
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End use sectors: energy delivered to industry sector
More commentary to follow.
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L_CHP
G_CHP
S_
L_
G_
GBR: TechBeh: Industry : fuel by sector
Society Energy Environment SEE
Transport
Options exercised:• Demand management, especially in aviation sector• Reduction in car power and top speed• Increase in vehicle efficiency
– light, low drag body– improved motor efficiency
• Implentation of speed limits• Shift to modes that use less energy per passenger or freight carried:
– passengers from car to bus and train– freight from truck to train and ship
• Increased load factor in the aviation sector• Some penetration of vehicles using alternative fuels:
– electricity for car and vans– biofuels principally for longer haul trucks and aircraft
Society Energy Environment SEE
Passenger transport: carbon emission by purpose
Education2%Shopping
10%Medical (pers)
1%
Other personal5%
Eat/drink2%
To friends15%
Social2%
Entertain4%
Sport (do)2%
Holiday 4%
Day trip4%
Other0%
Escort6%
Carbon emissionby purpose
To work 30%
In work 13%
Commuting and travel in work account for 40-50% of emissions
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Passenger transport: carbon emission purpose and by trip length
Stage length (km)
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10%
20%
30%
40%
50%
60%
70%
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100%
Non-work
In workTo and from work
Carbon dioxide emission (MtC)
% to work
Cumulative proportion
% Non work% in work
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Passenger transport use by mode trip length
Stage Length (km)
Car
bon
Emis
sion
(Mt)
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Car/van T axi Motorcycle Bus
Coach Underground T rain Other public
Short distance car trips account for bulk of emissions.
Society Energy Environment SEE
Passenger transport : potential effect of teleworking
Minimum stage length of te leworking substitution (miles)
Red
ucti
on in
car
bon
emiss
ion
0%
1%
2%
3%
4%
5%
0 5 10 15 20 25
Reduction on total carbon emissionfrom UK passenger transport
Reduction on emissionof commuting
Reduction on emissionof in work travel
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Passenger transport: carbon emission by mode of travel
Load factor
Roa
d &
Rai
l GW
E (g
Ceq
/p.k
m)
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raft
GW
E (g
Ceq
/p.k
m)
M/cycle
Moped
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Bus
T rain
Aircraft
Car average
Aircraft
Charter
Scheduled
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Passenger transport: mode of travel by distance
Stage Le ngth (Miles)
Prop
ortio
n of
Dis
tanc
e by
Mod
e
0%
20%
40%
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100%
1 2 3 5 10 15 25 35 50 75 100
150
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ove
r
Walk Bicycle Car/van T axi Motorcycle
Bus Coach Underground BR Other public1985/6
Society Energy Environment SEE
Passenger transport: carbon emission by car performance
grammes Carbon per km
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100
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200
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300Acceleration
Fuel
Speed
UKspeedlimit
Petrol
DieselMicrocars
Car carbon emissions are strongly related to top speed, acceleration and weight. Most cars sold can exceed the maximum legal speed limit by a large margin. Switching to small cars would reduce car carbon emissions by about 40% in ten years. Switching to micro cars and the best liquid fuelled cars would reduce emissions by about 90% in the longer term.
Society Energy Environment SEE
Passenger transport: Risk of injury to car drivers involved in accidents between two cars
Cars that are big CO2 emitters are most dangerous because of their weight, and because they are usually driven faster. In a collision between a small and a large car, the occupants of the small car are much more likely to be injured or killed. The most benign road users (small cars, cyclists, pedestrians) are penalised by the least benign.
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CO
2 g/
km
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inju
ry %
CO2%serious
Society Energy Environment SEE
Transport: road speed and CO2 emission
Energy use and carbon emissions increase strongly with speed. Curves for other pollutants generally similar, because emission strongly related to fuel consumption.
These curves are only applicable to current internal combustion vehicles. Characteristics of future vehicles (e.g. urban internal combustion and electric powered) would be different. Minimum emission would probably be at a lower speed, and the fuel consumption and emissions at low speeds would not show the same increase.
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600%
5 25 45 65 85 105 125 145
kph
Car (D,> 2.0 l, EURO IV) Car (P,< 1.4 l, EURO IV)Car (P,1.4 - 2.0 l, EURO IV) Car (P,> 2.0 l, EURO IV)HGV (D,Rigid, EURO IV) HGV (D,Artic, EURO IV)Bus (D,0, EURO IV) Van (D,medium, EURO IV)Van (D,large, EURO IV) Mcycle (P,250-750cc 4-s, pre)Mcycle (P,>750cc 4-s, pre)
Motorway
Fraction of minimum CO2 g/km
Low speed emission
Average conceals start/ stop congestion
And car design dependent
Society Energy Environment SEE
Transport: road speed and PM emission
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5 25 45 65 85 105 125 145
kph
Car (D,< 2.0 l, EURO IV) Car (P,> 2.0 l, EURO III)Car (P,< 1.4 l, EURO IV) Car (P,1.4 - 2.0 l, EURO IV)HGV (D,Artic, EURO III) HGV (D,Rigid, EURO IV)Bus (D,0, EURO III) Van (D,small, EURO IV)Van (D,medium, EURO IV) Mcycle (P,<250cc 4-s, pre)Mcycle (P,250-750cc 4-s, pre)
Motorway
Fraction of minimum PM g/km
Society Energy Environment SEE
Transport: road speed and NOx emission
0%
100%
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600%
5 25 45 65 85 105 125 145
kph
Car (D,< 2.0 l, 83/351) Car (P,< 1.4 l, 91/441)Car (P,1.4 - 2.0 l, 91/441) Car (P,> 2.0 l, 91/441)Car (P,> 2.0 l, EURO IV) HGV (D,Rigid, 88/77)HGV (D,Artic, 91/542 II) Van (D,medium, 93/59)Van (D,large, 93/59) Van (P,large, EURO III)Van (P,small, EURO IV)
Motorway
Fraction of minimum NOx g/km
Society Energy Environment SEE
Transport: road speeds
0102030405060708090
100
Mcycle
sCars
Cars to
wing
Light g
oods
Buses/c
oach
es2 a
xle
3/4 ax
le
Articula
ted
4 axle
s
5+ ax
les
Bre
akin
g lim
it %
Motorways Dual carriagewaySingle cariageway 30 mph roads40 mph roads
A large fraction (40-50%) of vehicles break the speed limits on all road types. This law-breaking increases carbon and other emissions, and death and injury due to accident. Enforcing the existing limits, and reducing them, would significantly reduce emissions and injury.
Society Energy Environment SEE
Transport: aviation
Aviation is a special sector because:• There is no near physical limit to growth as for land transport• It has the most rapid growth in demand of any major sector• Its emissions have particular impacts because of altitude• Aircraft are already relatively energy efficient
For these reasons, aviation is projected to become a dominant cause of global warming over the next few decades. The UK is a large exporter of aviation services, and fuelling this export will become perhaps the major problem in UK energy policy. Currently there is no proven alternative to liquid fuels for aircraft.
Most aviation is international with special legal provisions, and so aviation (and shipping) can not be analysed in isolation from other countries.
Aviation is discussed in detail in reports that may be downloaded at:http://www.sencouk.co.uk/Transport/Air/Aviation.htm
Society Energy Environment SEE
Demand management
Freight
Passenger
Business
Leisure
Technology
AirframeEngine
Aircraft size
Operation Traffic control
Load factor
Altitude
Speed
Route length
CONTROL MEASURES
Aviation: control measures
Aviation emission control measures can be classed under demand management, technology and operations.
Society Energy Environment SEE
Aviation: effects of technical and operational measures
30%
40%
50%
60%
70%
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100%
600 650 700 750 800 850 900 950 1000
Cruise speed (kph)
Fuel
use
per
pas
seng
er k
ilom
etre
CurrentDecreased design cruise speed
Turboprop/propfan replaces turbofan
Improve airframe
Increase load factor
Improve existingturbofan engine
Propfan
Technologicalimprovement
Operationalchange
Behavioural measures (other than reducing basic demand) such as increasing aircraft load factor and reducing cruising speed are as important as technological improvement. These measures can be implemented faster than technological change, as the average aircraft operating life is about 30 years.
Society Energy Environment SEE
Aviation scenarios
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1991 1996 2001 2006 2011 2016 2021 2026 2031 2036 2041
Demand
Business as usual
Operational
Technology
All except demand
All measures
Load factor
Carbon emission (MtC)
Aviation emissions can only be stabilised if all technical and operational measures are driven to the maximum, and the demand growth rate is cut by half. To reduce aviation emissions by 60% would require further demand reduction.
Society Energy Environment SEE
Transport: passenger demand by mode and vehicle typeDemand depends on complex of factors: demographics, wealth, land use patterns, employment, leisure travel.
National surface demand is limited by time and space, but aviation is not so limited by these factors.
0
500
1000
1500
2000
2500
1990
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
Gpk
m
Int:Pas:Plane
Int:Pas:Ship
Nat:Pas:Ship
Nat:Pas:Plane
Nat:Pas:Rail
Nat:Pas:Bus
Nat:Pas:Car
Nat:Pas:MCycle
Nat:Pas:Bike
GBR: TechBeh: Passenger : Load distance
Society Energy Environment SEE
Transport: freight demand by mode and vehicle typeThe scope for load distance reduction through logistics and local production is not assessed. International
freight is estimated.
0
100
200
300
400
500
600
700
800
90019
90
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
Gtk
m
Int:Fre:Plane
Int:Fre:Ship
Nat:Fre:Plane
Nat:Fre:Ship
Nat:Fre:Pipe
Nat:Fre:Rail
Nat:Fre:LDV
Nat:Fre:Truck
GBR: TechBeh: Freight : Load distance
Society Energy Environment SEE
Transport, national: passenger modeA shift from car to fuel efficient bus and train for commuting and longer journeys is assumed. The scope for
modal shift from air to surface transport is very limited without the development of alternative long distance transport technologies.
0
0.2
0.4
0.6
0.8
1
1.219
90
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
%
Nat:Pas:Ship
Nat:Pas:Plane
Nat:Pas:Rail
Nat:Pas:Bus
Nat:Pas:Car
Nat:Pas:MCycle
Nat:Pas:Bike
GBR: TechBeh: National : Passenger : Mode
Society Energy Environment SEE
Transport: national : freight modeShift from truck to rail. Currently, no assumed shift to inland and coastal shipping.
0
0.2
0.4
0.6
0.8
1
1.219
90
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
%
Nat:Fre:Plane
Nat:Fre:Ship
Nat:Fre:Pipe
Nat:Fre:Rail
Nat:Fre:LDV
Nat:Fre:Truck
GBR: TechBeh: National : Freight : Mode
Society Energy Environment SEE
Transport: passenger vehicle load factor• Load factors of vehicles, especially aircraft, assumed to increase through logistical change.• Vehicle load capacities (passengers/vehicle; tonnes/truck) assumed unchanged.
0
0.2
0.4
0.6
0.8
1
1.219
90
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
%
Nat:Pas:Bike
Nat:Pas:MCycle
Nat:Pas:Car
Nat:Pas:Bus
Nat:Pas:Rail
Nat:Pas:Plane
Nat:Pas:Ship
Int:Pas:Ship
Int:Pas:Plane
GBR: TechBeh: Passenger : Load factor
Society Energy Environment SEE
Further analysis: electric vehiclesElectric (EV) or hybrid electric/liquid fuelled (HELV) vehicles are a key option for the future
because liquid (and gaseous) fossil fuels emit carbon, will become more scarce and expensive and are technically difficult to replace in transport, especially in aircraft.
Electric vehicles such as trams or trolley-buses draw energy whenever required but they are restricted to routes with power provided by rails or overhead wires. Presently there are no economic and practical means for providing power in a more flexible way to cars, consequently electric cars have to store energy in batteries. The performance in terms of the range and speed of EVs and HELVs is improving steadily such that EVs can meet large fraction of typical car duties; the range of many current electric cars is 100-200 miles. A major difficulty with EVs is recharging them. At present, car mounted photovoltaic collectors are too expensive and would provide inadequate energy, particularly in winter, although they may eventually provide some of the energy required.
Because of these problems it may be envisaged that HELVs will first supplant liquid fuelled vehicles, with an increasing fraction of electric fuelling as technologies improve.
Hydrogen is much discussed as a transport fuel, but the overall efficiency from renewable electricity to motive power via hydrogen is perhaps 50%, whereas via a battery it might be 70%. For this reason, it is not currently included as an option. If the efficiency difference were narrowed, and the refuelling and range problems of EVs are too constraining, then hydrogen should be considered further.
Society Energy Environment SEE
Transport: passenger vehicle distance
A large reduction in road traffic reduces congestion which gives benefits of less energy, pollution and travel time.
0
50
100
150
200
250
300
350
400
450
1990
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
Gv.
km
Int:Pas:Plane_LB
Int:Pas:Plane_KInt:Pas:Ship_D
Nat:Pas:Ship_DNat:Pas:Plane_K
Nat:Pas:Rail_E
Nat:Pas:Rail_LBNat:Pas:Rail_D
Nat:Pas:Bus_E
Nat:Pas:Bus_H2Nat:Pas:Bus_CNG
Nat:Pas:Bus_LBNat:Pas:Bus_D
Nat:Pas:Car_E
Nat:Pas:Car_H2Nat:Pas:Car_LB
Nat:Pas:Car_LPG
Nat:Pas:Car_DNat:Pas:Car_G
Nat:Pas:MCyc_GNat:Pas:Bike_S
GBR: TechBeh: Passenger : Vehicle distance
Society Energy Environment SEE
Transport: freight vehicle distance
Some growth in freight vehicle distance. Vehicle capacities and load factors important assumptions
0
20
40
60
80
100
120
14019
90
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
Gv.
km
Int:Fre:Plane_K
Int:Fre:Ship_LB
Int:Fre:Ship_D
Nat:Fre:Pipe_E
Nat:Fre:Ship_D
Nat:Fre:Plane_K
Nat:Fre:Rail_E
Nat:Fre:Rail_D
Nat:Fre:Truck_LB
Nat:Fre:Truck_D
Nat:Fre:LDV_E
Nat:Fre:LDV_H2
Nat:Fre:LDV_LB
Nat:Fre:LDV_D
Nat:Fre:LDV_G
GBR: TechBeh: Freight : Vehicle distance
Society Energy Environment SEE
Transport: passenger: fuel per passenger kmReductions in fuel use because of technical improvement, better load factors, lower speeds, and less
congestion.
0
2
4
6
8
10
1219
90
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
MJf
uel/p
km
Nat:Pas:Bike_SNat:Pas:MCyc_GNat:Pas:Car_G
Nat:Pas:Car_DNat:Pas:Car_LPG
Nat:Pas:Car_LB
Nat:Pas:Car_H2Nat:Pas:Car_ENat:Pas:Bus_DNat:Pas:Bus_LBNat:Pas:Bus_CNG
Nat:Pas:Bus_H2Nat:Pas:Bus_E
Nat:Pas:Rail_DNat:Pas:Rail_LBNat:Pas:Rail_ENat:Pas:Plane_K
Nat:Pas:Ship_DInt:Pas:Ship_DInt:Pas:Plane_KInt:Pas:Plane_LB
GBR: TechBeh: Passenger : Fuel per load km
Society Energy Environment SEE
Transport: passenger: delivered energy
Future passenger energy use dominated by international air travel.
0
500
1000
1500
2000
2500
1990
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
PJ
Int:Pas:Plane_LB
Int:Pas:Plane_KInt:Pas:Ship_D
Nat:Pas:Ship_DNat:Pas:Plane_K
Nat:Pas:Rail_E
Nat:Pas:Rail_LBNat:Pas:Rail_D
Nat:Pas:Bus_ENat:Pas:Bus_H2Nat:Pas:Bus_CNG
Nat:Pas:Bus_LBNat:Pas:Bus_D
Nat:Pas:Car_ENat:Pas:Car_H2Nat:Pas:Car_LBNat:Pas:Car_LPG
Nat:Pas:Car_DNat:Pas:Car_GNat:Pas:MCyc_GNat:Pas:Bike_S
GBR: TechBeh: Passenger : Delivered
Society Energy Environment SEE
Transport: freight delivered energy
Freight energy use is dominated by trucks. The potential for a further shift to rail needs investigation.
0
100
200
300
400
500
600
700
80019
90
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
PJ
Int:Fre:Plane_K
Int:Fre:Ship_LB
Int:Fre:Ship_D
Nat:Fre:Pipe_E
Nat:Fre:Ship_D
Nat:Fre:Plane_K
Nat:Fre:Rail_E
Nat:Fre:Rail_D
Nat:Fre:Truck_LB
Nat:Fre:Truck_D
Nat:Fre:LDV_E
Nat:Fre:LDV_H2
Nat:Fre:LDV_LB
Nat:Fre:LDV_D
Nat:Fre:LDV_G
GBR: TechBeh: Freight : Delivered
Society Energy Environment SEE
End use sectors: useful energy services
• Useful energy supply and services increase• Growth in all end uses except space heating
0
500
1000
1500
2000
2500
3000
3500
4000
1990
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
PJ
Cool
Space AC
Space H
Water H
Cooking
H<12-C
H>120C
Light
Proc W
El equip
Mot W
GBR: TechBeh: Energy : Useful
Society Energy Environment SEE
Energy conversion: efficienciesPreliminary graph showing efficiencies of energy conversion. Efficiencies greater than one signify heat pumps.
Declining efficiencies are where the cogeneration heat fraction falls, and the electricity fraction increases
0
0.2
0.4
0.6
0.8
1
1.2
1.419
90
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
Effi
cien
cy
Mot WProc WH>120CH<12-CCookingWater HSpace HG_L_S_Auto:Pipe (DH)_HHG_BioL_BioS_BioG_FosL_FosS_FosG_FosL_FosS_FosG_L_S_G_FosL_FosS_FosG_L_S_G_FosL_FosS_FosTrans_EEPump_EE_WindE_TideE_WaveH_SolarH_GeotheE_HydroS_MunRefG_BioL_BioS_BioN_NucG_FosL_FueOilS_FosG_BioL_BioS_BioL_GasDieL_MotGasL_AviKjeL_FueOilL_FosNuc_NNG_FosL_CruOilS_FosS_Bio
GBR: TechBeh: Efficiency
Society Energy Environment SEE
End use sectors: energy delivered by sector
Delivered energy decreases because of demand management and energy conversion efficiency gains.
0
1000
2000
3000
4000
5000
6000
700019
90
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
PJ
Sea:Int
Air: Int
Other inland
Air: Dom
Rail
Road: Freight
Road: Pass
Residential
Services
other
Agriculture
Light
Met&Min
Chemical
Iron and steel
GBR: TechBeh: Delivered : by sector
Society Energy Environment SEE
End use sectors: energy delivered by fuel
Reduction in fossil fuel use through efficiency and shift to alternatives.
0
1000
2000
3000
4000
5000
6000
7000
800019
90
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
PJ
H_Solar
S_Bio
L_Bio
G_Bio
S_CHP
L_CHP
G_CHP
H_Pipe (DH)
E_Ele
S_Fos
L_AviKje
L_MotGas
L_GasDie
L_LiqPeG
L_Fos
G_Fos
GBR: TechLifestyle: Delivered : by fuel
Society Energy Environment SEE
Energy supply: electricity
Options exercised:
• Phase out of nuclear and coal generation– some fossil (coal, oil, gas) capacity may be retained for security
• Extensive installation of CHP, mainly gas, in all sectors• Utilisation of biomass waste and biomass crops• Large scale introduction of renewable electricity
– wind, solar, tidal, wave
Electricity supply in the scenarios requires more analysis of demand and supply technicalities and economics, particularly:
• future technology costs, particularly of solar-electric systems such as photovoltaic• demand characteristics including load management and storage• renewable supply mix and integration
Society Energy Environment SEE
Energy supply: electricity : generating capacityCapacity increases because renewables (especially solar) and CHP have low capacity factors. Some fossil
capacity would perhaps be retained for back-up and security.
0
20
40
60
80
100
120
140
160
180
1990
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
GW
e
S_Fos
L_FueOilG_Fos
N_NucS_Bio
L_Bio
G_BioS_MunRef
E_HydroH_GeotheH_Solar
E_WaveE_Tide
E_Wind
Pump_ES_Fos
L_FosG_FosS_
L_G_
GBR: TechBeh: Electricity : Capacity : GWe
Society Energy Environment SEE
Electricity: generationFinite fuelled electricity-only generation replaced by renewables and CHP. Proportion of fossil back-up
generation depends on complex of factors not analysed with SEEScen.
0
200
400
600
800
1000
1200
140019
90
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
PJe
S_Fos
L_FueOilG_Fos
N_NucS_Bio
L_Bio
G_BioS_MunRefE_Hydro
H_GeotheH_SolarE_WaveE_Tide
E_WindPump_ES_Fos
L_FosG_FosS_
L_G_
GBR: TechBeh: Electricity : Output : PJe
Society Energy Environment SEE
Electricity: generation costs (excluding distribution)Because of increased CHP and renewables, the fraction of capital and operation and maintenance costs
increases and the fraction of fuel costs decreases
0
2
4
6
8
10
12
14
16
1990
1995
2000
2005
2010
2015
2020
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2035
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2045
2050
€/G
J
CapPerYr
OMTotal
FuInCost
GBR: TechBeh: Generation unit cost
Society Energy Environment SEE
Electricity: scenario generation costs (excluding distribution)
Relative generation costs depend critically on future fuel prices, but in these scenarios the larger demand scenarios have higher electricity costs.
0
5
10
15
20
25
30
1990
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
€/G
J
Base/Kyoto
Behaviour
Carbon15
TechHigh
TechBeh
GBR: Scenarios: Generation unit cost
Society Energy Environment SEE
Energy: primary supply• Total primary energy consumption falls, and then increases• Fraction of renewable energy increases, then falls
0
1000
2000
3000
4000
5000
6000
7000
8000
9000
10000
1990
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
PJ
H_Solar
H_Geothe
E_Hydro
E_Wave
E_Tide
E_Wind
S_MunRef
Biomass
Nuclear
Solid
Liquid
Gas
GBR: TechBeh: Primary
Society Energy Environment SEE
Fuel extraction• Extraction of oil and gas tails off as reserves are depleted• Biomass extraction increases
0
1000
2000
3000
4000
5000
6000
7000
800019
90
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
PJc
S_Bio
S_Fos
L_CruOil
G_Fos
GBR: TechBeh: Fuel extraction : Output
Society Energy Environment SEE
Fuel reserves• Oil and gas reserves effectively consumed• Large coal reserves available for strategic security
0
20000
40000
60000
80000
100000
120000
140000
160000
18000019
90
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
PJ
Nuclear
Coal
Petroleum
Natural gas
GBR: TechBeh: Reserves
Society Energy Environment SEE
Energy tradeNuclear fuel imports decline; gas and oil imports increase and stabilise; some electricity export.
-1000
-500
0
500
1000
1500
2000
250019
90
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
PJ
Gas
Liquid
Solid
Nuclear
Elec
GBR: TechBeh: Trade
Society Energy Environment SEE
Energy flow charts
The flow charts show basic flows in 1990 and 2050, and an animation of 1990-2050. The central part of the charts illustrate the relative magnitude of the energy flows through the UK energy system. The top section shows carbon dioxide emissions at each stage. The bottom section shows energy wasted and discharged to the environment.
Please note that the scale of these charts varies.
Observations:• Energy services:
– space heating decreases– other demands increase, especially motive power and transport
• Fuel supply– increase in efficiency (CHP)– increase in renewable heating, biomass and electricity– imports of gas and oil are required– electricity is exported
Society Energy Environment SEE
UK Energy flow chart: 1990SENCO GBR : TechBeh : Y1990
Trade Extraction Fuel processing Electricity and heat Delivered Sectors Useful energyEnvironment
Waste energy
Trd_E
Trd_N
Ext_G
Ext_S
Ext_L
Solid
Nuclear
Refinery Liq
Solid
Nuclear
L_FueOil
ElOnly
Gas
Solid
Elec
Liq
Biomass Food
Res_G_
Res_S_Res_E_Res_L_
Ser_G_Ser_S_Ser_E_Ser_L_
Ind_G_
Ind_S_Ind_E_
Ind_L_
Oth_G_Oth_L_
Tra(nat) E
Tra(nat) L
Tra(int) L
Mot W
Proc W
H>120C
H<12-C
Water H
Space H
Space ACCool
CO2 CO2
Society Energy Environment SEE
UK Energy flow chart: Animation 1990 to 2050
Society Energy Environment SEE
UK Energy flow chart: 2050SENCO GBR : TechBeh : Y2050
Trade Extraction Fuel processing Electricity and heat Delivered Sectors Useful energyEnvironment
Waste energy
Trd_G
Trd_E
Trd_L
Ext_G
Ext_S
Biomass
Solid
Wind
TideWave
Solar
Biowaste
Biomass Biomass proc
Refinery
S_BioL_Bio
Liq
Wind
TideWaveSolar
Waste
CHPDHFuI
ElOnly
Auto
CHPDH_H
Auto_H
Gas
G_CHP
H_Solar
Solid
Elec
Heat
L_CHP
Liq
Biomass Food
Res_G_CHPRes_H_SolarRes_E_
Ser_G_CHPSer_H_SolarSer_E_
Ind_G_Ind_G_CHPInd_H_SolarInd_S_
Ind_E_
Ind_L_Ind_L_CHP
Oth_G_
Tra(nat) ETra(nat) L
Tra(int) L
Mot W
El equipProc WLight
H>120C
H<12-C
Cooking
Water H
Space H
Space ACCool
CO2
Society Energy Environment SEE
Environment
Often, the energy and environment debate concerns itself with routine, relatively easily quantified emissions such as CO2, and ignores the many other impacts of energy demand and supply, even though they may as important economically or socially, if only in the shorter term.
There are particular problems concerning the environmental impacts of energy.• The definition and precision of calculation of many impacts are poor for technical reasons.• Future impacts depend on developments in technology, legislation and other controls.• Some impacts are routine, such as CO2 emission; others, such as a nuclear accident, are not routine and
have probabilities of occurrence and consequences that are impossible to calculate with any certainty.• Some impacts are physical; others, such as the threat of attack on a nuclear facility, are not physical but can
still have impacts.• Some impacts are not directly associated with technical energy processes. For example, in the low emission
scenarios, road traffic injuries and deaths would be reduced through measures such as less car travel and enforced speed limits. There would be further social benefits such as more equal access to transport, and disbenefits such as less car driving.
• The impacts are different in kind: gaseous, liquid, solid, radioactive, biological, visual, land take, etc. There is no objective method to weigh these against each other except through political processes.
SEEScen presently calculates:• Atmospheric emissions of CO2, and of SO2, NOx, PM and CO although these are imprecise• Some other impacts such as the number of aerogenerators and the fraction of land area used for biomass
production
Society Energy Environment SEE
Environment: carbon dioxideNote the historical emission inaccuracy because of data. The TechBeh scenario has a decline in CO2 emission
of about 80%, and then an increase, primarily because of aviation growth.
0
100
200
300
400
500
600
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1995
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2010
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2040
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Mt
Fue:ExtFue:ProEle:GenEle:PumEle:TraHea:PubHea:AutTra(int):Sea:IntTra(int):Air: InTra(nat):Other iTra(nat):Air: DoTra(nat):RailTra(nat):Road: FTra(nat):Road: PRes:ResSer:SerOth:othInd:AgrInd:LigInd:MetInd:CheInd:Iro
GBR: TechBeh: Environment : Air : CO2
Society Energy Environment SEE
Environment: CO2 emission by scenario
There is an eventual upturn in emissions as assumed demand growth overtakes technology and behavioural options.
0
100
200
300
400
500
60019
90
1995
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2020
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Mt
Base/Kyoto
Behaviour
Carbon15
TechHigh
TechBeh
GBR: Scenarios: Environment : Air : CO2
Society Energy Environment SEE
Environment: nitrogen oxides
0
200
400
600
800
1000
1200
1400
1600
180019
90
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
kt
Fue:ExtFue:ProEle:GenEle:PumEle:TraHea:PubHea:AutTra(int):Sea:IntTra(int):Air: InTra(nat):Other iTra(nat):Air: DoTra(nat):RailTra(nat):Road: FTra(nat):Road: PRes:ResSer:SerOth:othInd:AgrInd:LigInd:MetInd:CheInd:Iro
GBR: TechBeh: Air : NOx
Society Energy Environment SEE
Environment: particulate matter
0
20
40
60
80
100
120
140
160
18019
90
1995
2000
2005
2010
2015
2020
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2030
2035
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2045
2050
kt
Fue:ExtFue:ProEle:GenEle:PumEle:TraHea:PubHea:AutTra(int):Sea:IntTra(int):Air: InTra(nat):Other iTra(nat):Air: DoTra(nat):RailTra(nat):Road: FTra(nat):Road: PRes:ResSer:SerOth:othInd:AgrInd:LigInd:MetInd:CheInd:Iro
GBR: TechBeh: Air : PM10
Society Energy Environment SEE
Economics
In SEEScen, the direct annual costs of fuel, and the annuitised costs of conversion technologies and demand management are calculated. The model does not account for anything unrelated to fuels or technologies, including:
• indirect costs and benefits, such as the economic savings following a shift away from cars leading to reduced health damage because of accidents, toxic air pollution, and the value of reduced travel time
• macroeconomic issues relating to the energy trade imbalance or exposure to fluctuating international fuel prices
Such economic impacts of energy scenarios can be of greater importance than direct costs. For example, the value of traffic related health injury and time lost in congestion is generally much greater than the costs of controlling noxious emissions from vehicles.
International fuel prices are critical to the relative cost effectiveness of measures. It is probable that the UK would follow a ‘low energy emission’ path in parallel with other countries, at least in Europe. In such an international scenario, finite fossil and nuclear fuel prices will be lower than in a higher demand scenario. Thus the implementation of options affects the cost-effectiveness of those options - a circularity:
– the more renewable energy deployed, the cheaper the fossil fuels leading to an increase in the relative cost of renewables
– the more the consumption of fossil and nuclear fuels, the higher the prices for those, leading to an increase in the relative cost of fossil and nuclear energy
Society Energy Environment SEE
International contextFuel availability and price will depend on
global and regional demand levels.SEEScen was used to model the five
scenarios for the four largest energy consumers near the UK: France, Germany, Spain and Italy.
Because the measures exercised are the same, the primary energy consumption of these countries varies in similar ways in the scenarios, although there are differences in detail.
This illustrates how regional energy demand might vary according to policies, and it has consequences for energy prices.
0
5000
10000
15000
20000
25000
30000
35000
40000
45000
50000
1990
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2005
2010
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2020
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2035
2040
2045
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PJ
GBR
ESP
ITA
DEU
FRA
ALL COUNTRIES: Base/Kyoto : Primary
0
5000
10000
15000
20000
25000
30000
35000
40000
45000
50000
1990
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
2045
2050
PJGBR
ESP
ITA
DEU
FRA
ALL COUNTRIES: TechBeh : Primary
Society Energy Environment SEE
Economics: fuel pricesInternational fuel prices are critical inputs
to the economic analysis of scenarios.
Fundamentally, costs in the long term are determined by the remaining amounts and marginal extraction costs of the reserves of finite fossil and nuclear fuels. Prices depend on costs and future demand-supply markets.
It may be argued that if the UK pursues a ‘low finite energy’ path then it is likely that other countries will be doing the same, at least within Europe.
The top chart shows a ‘high demand’ price projection, the bottom a ‘low demand’ projection.
These merely illustrate possible differences in trends. It may that the relative prices of gas, oil and coal will change.
This requires further analysis.
0
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4
6
8
10
12
14
16
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€/G
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Society Energy Environment SEE
Economics: TechBeh scenario annual costs of fuel, conversion and demand management
The annuitised costs of each fuel, technology and demand management option are calculated for each of the end use and supply sectors. In the low demand scenario, the fraction of total cost due to converters (boilers, power stations, etc.) and demand management increases as compared to fuels.
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GBR: TechBeh: Economics : Country
Society Energy Environment SEE
Economics: Base scenario annual costs of fuel, conversion and demand management
In higher energy supply scenarios, the fraction of costs due to fuel increases because renewable energy and CHP constitute smaller fractions. One implication of this, in comparison with a lower demand scenario, is that economic security is degraded because of the sensitivity to prices and availability of imported, globally traded fuels.
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Society Energy Environment SEE
Economics: total cost by scenarioThe more secure, lower impact systems for providing energy services may not have higher costs than high
demand and emission scenarios because more cost effective demand management is taken up. Also, fossil fuel prices will be lower because European/global demand will be lower (the UK will not, or cannot act alone).
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GBR: Scenarios: Economics : Country
Society Energy Environment SEE
Economics: energy trade costsThe cost of increased imports of fossil fuels is partially balanced by electricity exports.Note that the costs of imports are positive and exports, negative.
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Society Energy Environment SEE
Economics: scenarios: energy trade total cost balanceThe energy trade cost deficit increases in higher energy consumption scenarios because imports are greater
and fuel prices are higher
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Society Energy Environment SEE
Observations on scenarios: national energyThe scenarios are preliminary and could be improved with more recent data and sectoral analysis. However,
the relative magnitudes of energy flows, emissions and costs are illustrative of the main problems, and possible solutions.
The scenarios show that:• Large reductions in carbon dioxide and other emissions are possible without utilising irreversible
technologies with potential large scale risks - nuclear power and carbon sequestration.• Transport fuel supply is a more difficult problem than fuelling electricity supply or the stationary sectors
which have many potential fuel sources. Transport is the most difficult sector to manage, because:– demand management options are limited as compared to the stationary sector– of growth, especially in aviation– limited efficiency improvement potential as efficiency is already a strong driver in freight transport
and aviation– lack of alternatives to liquid fuels, especially for aviation
• The potential for the direct use of electricity as a transport fuel rather than the inefficient production and use of secondary fuels such as biofuels or hydrogen needs more exploration
In all scenarios, under the assumption of continued growth in energy service demand, emissions increase in the longer term as the effects of known technologies are absorbed. Behavioural options are important, especially if nascent technologies do not become technically and economically feasible. Therefore analysis and speculation on the following might be useful:
– possible future socioeconomic changes and impact on energy service demands– long term technology development
Society Energy Environment SEE
Observations on scenarios: economics and environment
Economics• The total cost of energy services may be less in low emission scenarios because of the cost
effectiveness of demand management and efficiency as compared to supply. This assumes that in the future, as now, the UK energy system is not optimal in economic terms because of market imperfections which lead to inadequate investment in demand management and energy efficiency.
• The more the application of demand management and renewable energy, the less is the UK exposed to international fuel price fluctuations.
• Demand management and renewables reduce the UK balance of payments deficit for energy trade.
Energy use and emissions increase when presumed growth overtakes implementation of current technology options. In the long term, therefore demand management, service and renewable energy technologies will require further implementation. A particular need is to find substitutes for liquid fuelled aircraft for long distance transport.
Society Energy Environment SEE
Observations on scenarios: national and international
The TechBeh scenario has a surplus of electricity; should• less be generated?• the surplus be used to substitute for fossil resources, e.g.
– to make transport fuels even if the process is wasteful?– for heating and other uses not requiring electricity?
• the surplus be exported as trade for other fuels?
It is not possible to develop a robust and economic UK energy strategy for the long term without consideration of international developments, for a number of reasons:
• the UK has transmission linkage with other countries; this is especially important for electricity if renewable sources in the UK meet a large fraction of total demand
• the availability of fuels for import depends on global demand• there are international arrangements that constrain UK policy in terms of demand management and
supply, for example, treaties concerning international aviation and shipping
This leads to system dynamics and the international aspects of energy scenarios.
Society Energy Environment SEE
Energy systems aspects: space and time
SEEScen has a main focus on annual flows, although it can simulate seasonal and hourly flows. Other models are required to analyse issues arising with short term variations in demand and supply, and with the spatial location of demands and supplies.
Questions arising:• Can the demands be met hour by hour using the range of supplies?• What spatial issues might arise? Some aspects of this are explored and illustrated with these models:
• EleServe : Electricity system model for temporal analysis
• EST Energy Space Time model
• InterEnergy Energy trade model
Society Energy Environment SEE
Electricity system: detailed considerationsElectricity demand and supply have to be continuously balanced as there is no storage in the transmission
network, unlike gas. This balancing can be achieved by controlling demand and supply, and by introducing storage on the system (pumped storage) or near the point of use: heat and electricity storage (hot water tanks, storage heaters, vehicle batteries) can be used to store surplus renewable energy when it is available, so that the energy can later be used when needed.
The EleServe Electricity Services model has these components:Electricity demand • disaggregated into segments across sectors and end uses• each segment with
– a temporal profile– load management characteristic
Electricity supply• each renewable source with own temporal profile• heat related generation with its own temporal profile• optional thermal generators characterised by energy costs at full and part load, and for starting upOperational control• load management by moving demands if cost reduced• optional units brought on line to minimise diurnal costs
The following graphs demonstrates the role that load management can play in matching variable demands to electricity supplied by variable renewable and CHP or cogeneration sources.
Society Energy Environment SEE
Electricity : diurnal operation without load management
Society Energy Environment SEE
Electricity : animated diurnal operation with load management
Society Energy Environment SEE
Electricity : diurnal operation with load managementEleServe Scenario: Efficiency + CHP + renewables 2025 Winter day : Summer day SENCO
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Society Energy Environment SEE
Electricity : commentary
The electricity demand-supply simulation :• shows how load management can alter the pattern of demand to better match CHP and renewable
electricity generation. The residual demand to be met by generators utilising fuels such as biomass or fossil fuels, that can alter their output, is less variable and the peak is smaller.
• demonstrates the importance of demand patterns and technologies in strategies for integrating variable electricity sources
• indicates that large fractions of variable sources can be accommodated without substantial back-up capacity
• end use or other local storage could play a significant role, especially if electric vehicles are widely used as in some of the scenarios
Further work is required on:• data defining current and future demand technologies• detailed electricity demand forecasts• the feasibility of integrated control of demand and supply technologies, including the accuracy of prediction
of hourly demands and renewable supplies over time periods of a several hours or days• more refined optimisation
Society Energy Environment SEE
Energy systems in space and time
For temporally variable demand and energy sources, what is the best balance between :• local supply and long distance transmission?• demand management, variable supply, optional or back up generation and system or local
storage?
These questions can be asked over different time scales (hour by hour, by day of week, seasonal) and spatial scales (community, national, international).
The EST and InterTrade models have been developed to illustrate the issues and indicate possible solutions for integrating spatially separate energy demands and sources, each with different temporal characteristics.
Society Energy Environment SEE
UK energy, space and time illustrated with EST
Society Energy Environment SEE
UK energy, space and time illustrated with EST : animated
Society Energy Environment SEE
A wider view of the longer term future
Wealthy countries like the UK can reduce their energy demands and emissions with cost-effective measures implemented in isolation from other counties, and in so doing improve their security. However, at some point it is more practical and cost-effective to consider how the UK can best solve energy and environment problems in concert with other countries.
As global fossil consumption declines because of availability, cost and the need to control climate change, then energy systems will need to be reinforced, extended and integrated over larger spatial scales.
This would be a continuation of the historical development of energy supply that has seen the geographical extension and integration of systems from local through to national and international systems.
The development and operation of these extended systems will have to be more sophisticated than currently. Presently, the bulk of variable demands in rich countries is met with reserves of fossil and nuclear fuels, the output of which can be changed by ‘turning a tap.’ When renewable energy constitutes a large fraction of supply, the matching of demands and supplies is a more complex problem both for planning and constructing a larger scale system, and in operating it.
Society Energy Environment SEE
International electricity : demand
Further connecting the UK system to other countries increases the benefits of diversity, at the cost of transmission.
The first chart shows the pattern of monthly demands for different European countries.
The second chart shows the normalised diurnal demand patterns for some countries. Note that these are all for ‘local’ time; time zone differences would shift the curves and make the differences larger.
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Society Energy Environment SEE
International electricity: supply; monthly hydro output
Hydro will remain the dominant renewable in Europe for some time. It has a marked seasonality in output as shown in the chart; note that hydro output can vary significantly from year to year. Hydro embodies some energy storage and can be used to balance demand and supply; to a degree determined by system design and other factors such as environment.
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Society Energy Environment SEE
Electricity trade
• An extensive continental grid already exists
• The diversity of demand and supply variations increases across geographical regions
• What is the best balance between local and remote supply?
InterEnergy model• Trade of energy over links
of finite capacity• Time varying demands and
supply• Minimise avoidable
marginal cost• Marginal cost curves for
supply generated by model such as EleServe
Society Energy Environment SEE
InterEnergy – animated trade
Animation shows programme seeking minimum cost for one period (hour)
Society Energy Environment SEE
Europe and western Asia – large point sourcesThe environmental impact of energy is a global issue: what is the best strategy for reducing
emissions within a larger region?
Society Energy Environment SEE
WorldThere are global patterns in demands and renewable supplies:• Regular diurnal and seasonal variations in demands, some climate dependent• Regular diurnal and seasonal incomes of solar energy• Predictable tidal energy income
Society Energy Environment SEE
World: a global electricity transmission grid?• Should transmission be global to achieve an optimum balance between supply, transmission and storage?• Which investments are most cost efficient in reducing GHG emission? Should the UK invest in photovoltaic
systems in Africa, rather than the UK? This could be done through the Clean Development Mechanism
Society Energy Environment SEE
Security: preliminary generalities 1
Energy security can be defined as the maintenance of safe, economic energy services for social wellbeing and economic development, without excessive environmental degradation.
A hierarchy of importance for energy services can be constructed:• Core services which it is immediately dangerous to interrupt
– food supply– domestic space heating, lighting– emergency services; health, fire, police
• Intermediate importance. Provision of social services and short-lived essential commodities• Lower importance. Long-lived and inessential commodities
Part of security planning is for these energy services to degrade gracefully to the core.
The various energy supply sources and technologies pose different kinds of insecurity:• renewable sources are, to a degree, variable and/or unpredictable, except for biomass• finite fossil and nuclear fuels suffer volatile increases in prices and ultimate unavailability• some technologies present potentially large risks or irreversibility
Society Energy Environment SEE
Security : preliminary generalities 2
Supply security over different time scales• Gross availability of supply over future years. The main security is to reduce dependence on the imports of
gas, oil and nuclear fuels and electricity through demand management and the development of renewable energy.
• Meeting seasonal and diurnal variations. This mainly causes difficulty with electricity, gas, and renewables except for biomass. Demand management reduces the seasonal variation in demand and thence the supply capacity problem for finite fuels and electricity. Storage and geographical extension of the system alleviates the problem.
Security of economic supply.• Demand management reduces the costs of supply.
– The gross quantities of fuel imports are less, and therefore the marginal and average prices– The reduced variations in demand bring reduced peak demands needs and therefore lower capacity costs
and utilisation of the marginal high cost supplies• The greater the fraction of renewable supply, the less the impact of imported fossil or nuclear fuel price rise• A diverse mix of safe supplies each with small unit size will reduce the risks of a generic technology failure
Security from technology failure or attack. In the UK, the main risk is nuclear power.
Security from irreversible technology risk. In the UK, nuclear power and carbon sequestration
Environment impacts. All energy sources and technologies have impacts, but the main concern here are long term, effectively irreversible, regional and global impacts. The greater the use of demand management and renewable energy, the less fossil and nuclear, the less such large impacts.
Society Energy Environment SEE
Electricity security
Demand management will reduce generation and peak capacity requirements as it :• reduces total demand• reduces the seasonal variation in demand, and thence maximum capacity requirements
It has been illustrated how load management might contribute to the matching of demand with variable supply. This can be further extended with storage, control and interruptible demand.
During the transition to CHP and renewable electricity, supply security measures could be exercised:• Retain some fossil fuel stations as reserves. Currently in the UK, there are these capacities:
– Coal 19 GW large domestic coal reserve– Oil 4.5 GW oil held in strategic reserves– Dual fired 5.6 GW– Gas 25 GW gas availability depends on other gas demands
• Utilisation, if necessary of some end use sector generation. Currently in excess of 7 GW, but these plants are less flexible because they are tied to end use production, services and emergency back-up
• The building of new flexible plant such as gas turbines if large stations are not suitable
Electricity trade with other countries can be used for balancing. There are geographical differences in the hourly variations of demands and renewable supply because of time zones, weather, etc. The strengthening of the link between France and the UK, and creation of links with other countries would enhance this option.
Society Energy Environment SEE
Gas and oil security
The measures to improve oil and gas security are basically the same, diversify fuel sources and store fuels:
• Diversify supply sources– Extension of the gas transmission system– Develop LNG imports
• Increase storage– Enlarge long term gas storage in depleted gas fields– Increase strategic 90 day oil reserve as required by IEA