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Recipient of James Watt Gold Medal for Energy Conservation Keith Tovey ( ) M.A., PhD, CEng, MICE, CEnv Reader Emeritus: University of East Anglia 1 Pathways.

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Presentation on theme: "Recipient of James Watt Gold Medal for Energy Conservation Keith Tovey ( ) M.A., PhD, CEng, MICE, CEnv Reader Emeritus: University of East Anglia 1 Pathways."— Presentation transcript:

1 Recipient of James Watt Gold Medal for Energy Conservation Keith Tovey ( ) M.A., PhD, CEng, MICE, CEnv Reader Emeritus: University of East Anglia 1 Pathways to an Energy Secure and Low Carbon Future: Hard Choices Ahead Broadland Climate Change Community Champion Teams – May 14 th 2011

2 Pathways to an Energy Secure and Low Carbon Future Energy Security: Difficult Choices Awareness Raising Effective Management Innovative Technical Solutions Many options for Long Term ~ 2050 But how do we also ensure Energy Security Issues to 2020/5 2 Good Record Keeping and Objective Analysis of data > leading to energy reduction through good management Effective Integration of Technologies

3 Import Gap Energy Security is a potentially critical issue for the UK On 7 th /8 th December 2011: UK Production was only 39%: 12% from storage and 49% from imports Prices have become much more volatile since UK is no longer self sufficient in gas. Gas Production and Demand in UK 3 UK becomes net importer of gas Completion of Langeled Gas Line to Norway Oil reaches $140 a barrel

4 Approximate Carbon Emission factors during electricity generation including fuel extraction, fabrication and transport. 4 Impact of Electricity Generation on Carbon Emissions. FuelApprox emission factor Comments Coal900 – 1000g Depending on grade and efficiency of power station Gas400 – 430g Assuming CCGT – lower value for Yarmouth as it is one of most efficient in Europe Nuclear5 – 10gDepending on reactor type Renewables~ 0For wind, PV, hydro Overall UK~530g Varies on hour by hour basis depending on generation mix Norfolk and Suffolk is a very low carbon electricity generation zone in UK But current accounting procedures do not allow regions to promote this. A firm in Norfolk / Suffolk would have only 16% of carbon emissions from electricity consumption Suffolk & Norfolk (2009) ~83g Sizewell B, Yarmouth and existing renewables

5 Carbon sequestration either by burying it or using methanolisation to create a new transport fuel will not be available at scale required until mid 2020s if then 5 Options for Electricity Generation in 2020 - Non-Renewable Methods Potential contribution to electricity supply in 2020 and drivers/barriers Energy Review 2002 late 2010 (*) 9th May 2011 (**) Gas CCGT 0 - 80% (at present 45-50%) Available now (but gas is running out) ~2p + nuclear fission (long term) 0 - 15% (France 80%) - (currently 18% and falling) new inherently safe designs - some development needed 2.5 - 3.5p nuclear fusionunavailable not available until 2040 at earliest not until 2050 for significant impact "Clean Coal" Coal currently ~40% but scheduled to fall Available now: Not viable without Carbon Capture & Sequestration 2.5 - 3.5p ~8.3p +/-3p 8.0p [5 - 11] ~ 9.7p for 1st new nuclear subsequently 7.0p 7.75p [5.5 - 10] New Coal ~ 10.5p with CCS ~ 13.5p [7.5 - 15]p - unlikely before 2025 * Electricity Markey Reform Consultation – January 2011 ** Energy Review 2011 – Climate Change Committee Nuclear New Build assumes one new station is completed each year after 2020. ?

6 6 Options for Electricity Generation in 2020 - Renewable Future prices from * DECC Consultation Document on Electricity Market Reform Jan 2011. ** Renewable Energy Review – 9 th May 2011 Climate Change Committee Potential contribution to electricity supply in 2020 and drivers/barriers 2002 (Gas ~ 2p) Jan 2011 (Gas ~ 8.3p) * May 2011 (Gas ~ 8.0p) ** 1.5MW Turbine At peak output provides sufficient electricity for 3000 homes On average has provided electricity for 700 – 850 homes depending on year On Shore Wind ~10% [~6000 x 3 MW turbines] available now for commercial exploitation ~ 2+p ~8.8p +/- 0.8p ~8.2p +/- 0.8p

7 7 Options for Electricity Generation in 2020 - Renewable Scroby Sands has a Load factor of 28.8% - 30% but nevertheless produced sufficient electricity on average for 2/3rds of demand of houses in Norwich. At Peak time sufficient for all houses in Norwich and Ipswich Potential contribution to electricity supply in 2020 and drivers/barriers 2002 (Gas ~ 2p) Jan 2011 (Gas ~ 8.3p) * May 2011 (Gas ~ 8.0p) ** On Shore Wind ~10% [~6000 x 3 MW turbines] available now for commercial exploitation ~ 2+p ~8.8p +/- 0.8p ~8.2p +/- 0.8p Off Shore Wind 10 - 15% technical development needed to reduce costs. ~2.5 - 3p ~13.5 -14p for early projects ~11.5p later 12.5p +/- 2.5 Climate Change Committee (9 th May 2011) see offshore wind as being very expensive and recommends reducing planned expansion by 3 GW and increasing onshore wind by same amount

8 8 Options for Electricity Generation in 2020 - Renewable Potential contribution to electricity supply in 2020 and drivers/barriers 2002 (Gas ~ 2p) Jan 2011 (Gas ~ 8.3p) May 2011 (Gas ~ 8.0p) On Shore Wind ~10% [~6000 x 3 MW turbines] available now for commercial exploitation ~ 2+p ~8.8p +/- 0.8p ~8.2p +/- 0.8p Off Shore Wind 10 - 15% technical development needed to reduce costs. ~2.5 - 3p ~13.5 -14p for early projects ~11.5p later 12.5p +/- 2.5 Micro Hydro Scheme operating on Siphon Principle installed at Itteringham Mill, Norfolk. Rated capacity 5.5 kW Future prices from Electricity Market Reform Consultation or Climate Change Report or RO/FITs where not otherwise specified Hydro (mini - micro) 5% technically mature, but limited potential 2.5 - 3p 11p for <2MW projects

9 9 Options for Electricity Generation in 2020 - Renewable Potential contribution to electricity supply in 2020 and drivers/barriers 2002 (Gas ~ 2p) Jan 2011 (Gas ~ 8.3p) * May 2011 (Gas ~ 8.0p) ** On Shore Wind ~10% [~6000 x 3 MW turbines] available now for commercial exploitation ~ 2+p ~8.8p +/- 0.8p ~8.2p +/- 0.8p Off Shore Wind 10 - 15% technical development needed to reduce costs. ~2.5 - 3p ~13.5 -14p for early projects ~11.5p later 12.5p +/- 2.5 9 Future prices from Electricity Market Reform Consultation or Climate Change Report or RO/FITs where not otherwise specified Hydro (mini - micro) 5% technically mature, but limited potential 2.5 - 3p 11p for <2MW projects Photovoltaic <1% even assuming 5 GW of installation available, much research needed to bring down costs significantly 16+ p ~27 - 41p 25p +/-8 Climate Change Report suggests that 1.6 TWh (0.4%) might be achieved by 2020 which is equivalent to ~ 2.0 GW.

10 10 Options for Electricity Generation in 2020 - Renewable Potential contribution to electricity supply in 2020 and drivers/barriers 2002 (Gas ~ 2p) Jan 2011 (Gas ~ 8.3p) * May 2011 (Gas ~ 8.0p) ** On Shore Wind ~10% [~6000 x 3 MW turbines] available now for commercial exploitation ~ 2+p ~8.8p +/- 0.8p ~8.2p +/- 0.8p Off Shore Wind 10 - 15% technical development needed to reduce costs. ~2.5 - 3p ~13.5 -14p for early projects ~11.5p later 12.5p +/- 2.5 10 Future prices from Electricity Market Reform Consultation or Climate Change Report or RO/FITs where not otherwise specified Hydro (mini - micro) 5% technically mature, but limited potential 2.5 - 3p 11p for <2MW projects Photovoltaic <1% even assuming 5 GW of installation available, much research needed to bring down costs significantly 16+ p ~27 - 41p 25p +/-8 Sewage, Landfill, Energy Crops/ Biomass/Biogas ??5% available, but research needed in some areas e.g. advanced gasification 2.5 - 4p 7 - 13p depending on technology Transport Fuels: Biodiesel? Bioethanol? Compressed gas from methane from waste. To provide 5% of UK electricity needs will require an area the size of Norfolk and Suffolk devoted solely to biomass

11 11 Options for Electricity Generation in 2020 - Renewable 11 Future prices from Electricity Market Reform Consultation or Climate Change Report or RO/FITs where not otherwise specified Potential contribution to electricity supply in 2020 and drivers/barriers 2002 (Gas ~ 2p) Jan 2011 (Gas ~ 8.3p) May 2011 (Gas ~ 8.0p) On Shore Wind~10%available now ~ 2+p~8.8p +/- 0.8p~8.2p +/- 0.8p Off Shore Wind 10 - 15% available but costly ~2.5 - 3p~11.5 -14p12.5p +/- 2.5 Small Hydro5% limited potential2.5 - 3p11p for <2MW projects Photovoltaic<<5% available, but very costly 15+ p~27 - 41p25p +/-8 Biomass??5% available, but research needed 2.5 - 4p 7 - 13p depending on technology Wave/Tidal Stream currently < 10 MW may be 1000 - 2000 MW (~0.1%) technology limited- major development not before 2020 4 - 8p No information but likely to be ~20p 19p +/- 6 Tidal 26.5p +/- 7.5p Wave

12 12 Options for Electricity Generation in 2020 - Renewable 12 Future prices from Electricity Market Reform Consultation or Climate Change Report or RO/FITs where not otherwise specified Potential contribution to electricity supply in 2020 and drivers/barriers 2002 (Gas ~ 2p) Jan 2011 (Gas ~ 8.3p) May 2011 (Gas ~ 8.0p) On Shore Wind~10%available now ~ 2+p~8.8p +/- 0.8p~8.2p +/- 0.8p Off Shore Wind 10- 15% available but costly ~2.5 - 3p~11.5 -14p12.5p +/- 2.5 Small Hydro5% limited potential2.5 - 3p11p for <2MW projects Photovoltaic<<5% available, but very costly 15+ p~27 - 41p25p +/-8 Biomass??5% available, but research needed 2.5 - 4p 7 - 13p depending on technology Wave/Tidal Stream currently < 10 MW may be 1000 - 2000 MW (~0.1%) technology limited- major development not before 2020 4 - 8p No information but likely to be ~20p 19p +/- 6 Tidal 26.5p +/- 7.5p Wave

13 13 Options for Electricity Generation in 2020 - Renewable 13 Future prices from Electricity Market Reform Consultation or Climate Change Report or RO/FITs where not otherwise specified Potential contribution to electricity supply in 2020 and drivers/barriers 2002 (Gas ~ 2p) Jan 2011 (Gas ~ 8.3p) May 2011 (Gas ~ 8.0p) On Shore Wind~10%available now ~ 2+p~8.8p +/- 0.8p~8.2p +/- 0.8p Off Shore Wind 10 - 15% available but costly ~2.5 - 3p~11.5 -14p12.5p +/- 2.5 Small Hydro5% limited potential2.5 - 3p11p for <2MW projects Photovoltaic<<5% available, but very costly 15+ p~27 - 41p25p +/-8 Biomass??5% available, but research needed 2.5 - 4p 7 - 13p depending on technology Wave/Tidal Stream ~0.1%technology limited-4 - 8p ~20p?? Tidal ~19p Wave ~26.5p Severn Barrage/ Mersey Barrages have been considered frequently e.g. pre war – 1970s, 2009 Severn Barrage could provide 5- 8% of UK electricity needs In Orkney – Churchill Barriers Output ~80 000 GWh per annum - Sufficient for 13500 houses in Orkney but there are only 4000 in Orkney. Controversy in bringing cables south Would save 40000 tonnes of CO 2 26p +/-5 Tidal Barrages 5 - 15% technology available but unlikely for 2020. Construction time ~10 years. In 2010 Government abandoned plans for development

14 14 Options for Electricity Generation in 2020 - Renewable 14 Future prices from Electricity Market Reform Consultation or Climate Change Report or RO/FITs where not otherwise specified Potential contribution to electricity supply in 2020 and drivers/barriers 2002 (Gas ~ 2p) Jan 2011 (Gas ~ 8.3p) May 2011 (Gas ~ 8.0p) On Shore Wind~10%available now ~ 2+p~8.8p +/- 0.8p~8.2p +/- 0.8p Off Shore Wind 10 - 15% available but costly ~2.5 - 3p~11.5 -14p12.5p +/- 2.5 Small Hydro5% limited potential2.5 - 3p11p for <2MW projects Photovoltaic<<5% available, but very costly 15+ p~27 - 41p25p +/-8 Biomass??5% available, but research needed 2.5 - 4p 7 - 13p depending on technology Wave/Tidal Stream ~0.1%technology limited-4 - 8p ~20p?? Tidal ~19p Wave ~26.5p Tidal Barrages5 - 15% technology available but unlikely for 2020. Construction time ~10 years. In 2010 Government abandoned plans for development 26p +/-5 Geothermal unlikely for electricity generation before 2050 if then -not to be confused with ground sourced heat pumps which consumed electricity

15 15 Do we want to exploit available renewables i.e onshore/offshore wind and biomass?. Photovoltaics, tidal, wave are not options for next 10 - 20 years. [very expensive or technically immature or both] If our answer is NO Do we want to see a renewal of nuclear power ? Are we happy with this and the other attendant risks? If our answer is NO Do we want to return to using coal? then carbon dioxide emissions will rise significantly unless we can develop carbon sequestration within 10 years UNLIKELY – confirmed by Climate Change Committee [9 th May 2011] If our answer to coal is NO Do we want to leave things are they are and see continued exploitation of gas for both heating and electricity generation? >>>>>> Our Choices: They are difficult

16 16 Our Choices: They are difficult If our answer is YES By 2020 we will be dependent on GAS for around 70% of our heating and electricity imported from countries like Russia, Iran, Iraq, Libya, Algeria Are we happy with this prospect? >>>>>> If not: We need even more substantial cuts in energy use. Or are we prepared to sacrifice our future to effects of Global Warming? - the North Norfolk Coal Field? Do we wish to reconsider our stance on renewables? Inaction or delays in decision making will lead us down the GAS option route and all the attendant Security issues that raises. We must take a coherent integrated approach in our decision making – not merely be against one technology or another

17 Our looming over-dependence on gas for electricity generation We need an integrated energy supply which is diverse and secure. We need to take Energy out of Party Politics.!

18 18 The Behavioural Dimension: Awareness raising Social Attitudes towards energy consumption have a profound effect on actual consumption Data collected from 114 houses in Norwich between mid November 2006 and mid March 2007 For a given size of household electricity consumption for appliances [NOT HEATING or HOT WATER] can vary by as much as 9 times. When income levels are accounted for, variation is still 6 times 18

19 19 Good Management has reduced Energy Requirements 800 350 Space Heating Consumption reduced by 57% CO 2 emissions reduced by 17.5 tonnes per annum. 19 Performance of ZICER Building

20 Electricity Consumption in an Office Building in East Anglia Consumption rose to nearly double level of early 2005. Malfunction of Air-conditioning plant. Extra fuel cost £12 000 per annum ~£1000 to repair fault Additional CO 2 emitted ~ 100 tonnes. Low Energy Lighting Installed 20

21 Pilot Lights £9 per week Pilot lights off Pilot Lights turned off during week Good Record Keeping and Analysis can result in significant savings St Pauls Church, Tuckswood Heated by 3 warm air heaters New Strategy: pilot lights off throughout summer and used strategically in winter resulted in an annual saving of: 5400 kWh of gas; 1030 kg of CO 2 ; and a monetary saving of £260 Or a percentage saving of 38% The Behavioural Dimension: Awareness raising

22 kWh% costRank% Renewables 2008 Norwich3,53579%6 0.0% Ipswich4,34997%159 0.0% Waveney4,41799%181 1.9% Broadland4,618103%231 3.0% Great Yarmouth4,699105%252 30.0% St Edmundsbury4,869109%280 1.0% Breckland5,028112%312 31.8% Forest Heath5,174116%336 0.0% Babergh5,252117%343 0.1% South Norfolk5,347119%358 5.0% Suffolk Coastal5,371120%360 1.0% North Norfolk5,641126%385 1.3% Mid Suffolk5,723128%390 18.3% King's Lynn and West Norfolk5,731128%393 2.5% UK Average4478 % of average cost of electricity bills compared to National Average Rank position in UK out of 408 Local Authorities Average house in Norwich emits 1.87 tonnes of CO 2 from electricity consumption in Kings Lynn 3.04 tonnes of CO 2 (based on UK emission factors) Average household electricity bill in Norwich is 64% that in Kings Lynn Average Domestic Electricity Consumption in Norfolk and Suffolk - 2009

23 Installations under the Feed In Tariff Scheme (11/05/2011) 23 Technology Domestic Installations Other Installations*Total Number Installed Capacity (MW) Number Installed Capacity (MW) Number Installed Capacity (MW) Norfolk Hydro20.02110.4920.021 Micro CHP40.003003 Photovoltaic7491.883120.0997611.982 Wind210.15360.040270.193 Total7752.060180.1397932.198 Suffolk Hydro000000.000 Micro CHP10.001001 Photovoltaic7481.90480.0397561.944 Wind190.12520.011210.136 Total7682.030100.0507782.080 * Commercial, Industrial and Community Schemes. Note: Chris Huhne announced a potential curtailment of large PV FIT schemes (>50kW) in early February 2011.

24 Low Carbon Strategies: making efficient use of technology 24 Solar Thermal solutions can provide hot water However, performance can be significantly affected by way normal central heating boiler is used for backup. A factor of two in output has been measured for otherwise identical installations

25 Low Carbon Strategies: making efficient use of technology 3 units each generating 1.0 MW electricity and 1.4 MW heat 25 e.g. UEAs Combined Heat and Power Improved insulation, improved appliance efficiency, (power packs, lighting etc, etc). Energy conserving technologies e.g. heat pumps, CHP etc.

26 26 1997/98 electricitygas oilTotal MWh198953514833 Emission factorkg/kWh0.460.1860.277 Carbon dioxideTonnes91526538915699 ElectricityHeat 1999/ 2000 Total site CHP generation exportimportboilersCHPoiltotal MWh204371563097757831451028263923 Emission factor kg/kWh -0.460.460.186 0.277 CO 2 Tonnes -44926602699525725610422 Before installation After installation This represents a 33% saving in carbon dioxide 26 Significant Savings in CO2 emissions are possible with CHP

27 A 1 MW Adsorption chiller Uses Waste Heat from CHP Provides chilling requirements in summer Reduces electricity demand in summer Increases electricity generated locally Saves ~500 tonnes Carbon Dioxide annually. 27 Load Factor of CHP Plant at UEA Demand for Heat is low in summer: plant cannot be used effectively. More electricity could be generated in summer A Paradox: Largest amount of electricity was imported when demand was least! For optimum results: Care in matching demand is needed

28 Peak output is 34 kW All electricity must be converted from DC to AC by use of inverters. Inverters are only 91% efficient 28 Building Integrated Renewable Electricity Generation Typical Solar Array: ZICER Building, UEA Most use of electricity is for computers DC power packs are typically ~70% efficient Only 2/3rds of costly electricity is used effectively. An integrated system in a new building would have both a DC and AC network. Reduced heat gain in building leading to less air-conditioning requirements.

29 29 A Pathway to a Low Carbon Future: A summary 4.Using Renewable Energy UEA Advanced Gasifier CHP 5.Offset Carbon Emissions 3.Using Efficient Equipment 1.Raising Awareness 2.Good Management 29

30 30 Seeking Effective Low Carbon Solutions Some costs for providing a low carbon future Small scale solar PV under the Feed in Tariff ~ £700+ per tonne CO 2 saved On-shore wind under Renewable obligation ~ £90+ per tonne CO 2 saved Cavity Insulation - £30 to - £80 per tonne CO 2 saved i.e. cost negative [based on 30 year] Effective Energy Management can also often be cost negative in terms of CO 2 saved. An effective strategy for a low carbon economy will focus on most cost effective solutions first.

31 31 Conclusions Lao Tzu (604-531 BC) Chinese Artist and Taoist Philosopher "If you do not change direction, you may end up where you are heading." And Finally! Some costs for providing a low carbon future Energy Security and a Low Carbon Strategies are important for a sustainable and prosperous future and should not focus just on energy generation but also on energy reduction Significant savings in monetary and carbon terms can be achieved through awareness raising Better management can lead to significant and often cheaper solutions for a low carbon future Important to Integrate effectively the use of newer technologies with actual demand e.g. local generation avoiding unnecessary losses – also avoid unnecessary conversion form DC to AC etc.

32 32

33 33 Variation in UK Electricity and Demand and Wind Generation. A single wind farm may have moderate variation in output Output smoothed if whole UK is considered. Demand also has significant diurnal variation Data for 23-25 th February 2011 from www.bmreports.comwww.bmreports.com Output from nuclear plant is nearly constant difference in variation in nuclear output compared to demand is comparable with difference in demand and wind generation

34 34 Impact of Electricity Generation on Carbon Emissions. Electricity exported from Norfolk/Suffolk in 2009 to rest of UK ~ 3200 GWh representing a net CO 2 saving of ~ 1.43 Mtonnes At £12.50 per tonne (current EU-ETS price), this represents a benefit of £18 million to rest of UK in carbon saved. However – in 2010, Sizewell B was off line from over 6 months, so is this low carbon electricity sustainable? Is such a reliance on a single source a secure or sustainable? From BBC Website – 27 th May 2008 Hundreds of thousands of homes suffered power cuts after a fault caused an unplanned shutdown at the Sizewell B nuclear power plant in Suffolk. Homes and businesses in London, and East Anglia were affected….. Local generation avoids most transmission and distribution losses and small scale schemes avoid such major power blackouts. However – over decentralisation may lead to distribution grid problems if there is no reinforcement.

35 35 Ways to Respond to the Challenge: Technical Solutions: Solar Photovoltaic Photovoltaic cells are expensive, but integration of ideas is needed. Output depends on type but varies from ~70kWh to ~100kWh per square meter per year. The New Feed In Tariff form April 1 st will make things more attractive. 41p per unit generated – an extra 3p if exported. But those who have installed PV will get the benefit from increased payments for electricity by those who have not.

36 * Electricity Markey Reform Consultation – January 2011 ** Energy Review 2011 – Climate Change Committee 36 Options for Electricity Generation in 2020 - Non-Renewable Methods Potential contribution to electricity supply in 2020 and drivers/barriers Energy Review 2002 late 2010 (*) 9th May 2011 (**) Gas CCGT 0 - 80% (currently 45- 50%) Available now (but UK gas running out rapidly) ~2p + ~8.3p +/-3p 8.0p [5 - 11] Projection made in/on Wholesale Electricity Price surge in January and December 2010 when Gas imports are high. UK becomes net importer of gas Completion of Langeled Gas Line to Norway Oil reaches $140 a barrel Government Projections of wholesale price of gas generation

37 37 Energy SourceScaleTo 31/03/11From 01/04/11 Duration (years) Anaerobic digestion500kW11.512.120 Anaerobic digestion>500kW99.420 Hydro15 kW19.920.920 Hydro>15 - 100kW17.818.720 Hydro>100kW - 2MW1111.520 Hydro>2kW - 5MW4.54.720 Micro-CHP*****<2 kW1010.510 Solar PV4 kW new36.137.825 Solar PV4 kW retrofit41.343.325 Solar PV>4-10kW36.137.825 Solar PV>10 - 100kW31.432.925 Solar PV>100kW - 5MW29.330.725 Solar PVStandalone29.330.725 Wind1.5kW34.536.220 Wind>1.5 - 15kW26.728.020 Wind>15 - 100kW24.125.320 Wind>100 - 500kW18.819.720 Wind>500kW - 1.5MW9.49.920 Wind>1.5MW - 5MW4.54.720 Existing generators transferred from RO99.4 to 2027 Export Tariff33.1 Feed in Tariffs – Introduced 1 st April 2010 ***** for first 30000 installations

38 38 Raising Awareness A Toyota Corolla (1400cc): 1 party balloon every 60m. 10 gms of carbon dioxide has an equivalent volume of 1 party balloon. Standby on electrical appliances up to 20 - 150+ kWh a year - 7500 balloons. (up to £15 a year) A Mobile Phone charger: > 10 kWh per year ~ 500 balloons each year. Filling up with petrol (~£55 for a full tank – 40 litres) --------- 90 kg of CO2 (5% of one hot air balloon) How far does one have to drive in a small family car (e.g. 1400 cc Toyota Corolla) to emit as much carbon dioxide as heating an old persons room for 1 hour? 1.6 miles At Gaoan No 1 Primary School in Xuhui District, Shanghai A tumble dryer uses 4 times as much energy as a washing machine. Using it 5 times a week will cost ~ £100 a year just for this appliance alone and emit over half a tonne of CO 2. School children at the Al Fatah University, Tripoli, Libya

39 39 Mostly Eye and Thetford Scroby Renewable Energy Generation in Suffolk and Norfolk 2009 - 10 Generation in GWh stationsGWh Capacity (kW) Load Factor Biomass33266181660.2% Landfill Gas 181272671954.3% Off-shore Wind 11706000032.3% On-shore Wind 5582450027.0% Sewage Gas 210483623.6% Total 29 691177871 Total Demand in Norfolk and Suffolk 7803.2 GWh % Renewables 8.9% National Average 7.8% Target 10.4%

40 40 How many people know what 9 tonnes of CO 2 looks like? 5 hot air balloons per person per year. On average each person in UK causes the emission of 9 tonnes of CO 2 each year. "Nobody made a greater mistake than he who did nothing because he thought he could do only a little." Edmund Burke (1727 – 1797)


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