1. ENERGY AMBASSADOR PROGRAMME

2. Outline of Today: The programme Introduction to energy Getting to know your house Behaviour Change Questionnaire Energy Monitors Carbon Calculation Landlords Volunteer Support

3. 1.The Programme

4. Success in Scotland 11 training sessions delivered Students from 21 colleges and universities totalling 145 Energy Ambassadors. Edinburgh Uni: Big Green Makeover -Trained over 90 volunteers over 4 semesters! -Worked with 104 homes – saving 126 tonnes CO2! -Held 128 personal consultations at 39 Energy Saving Advice Clinics around campus – saving 67 tonnes CO2! -Worked with Resident Assistants to save over 100 tonnes in University self-catered accommodation! 100% of students have made changes in their home to save energy!

5. BY THE END OF TODAY…… You will know how to do a home visit and carry out: Behavioural questionnaire Install an Energy Monitor You will able to offer energy saving tips, calculate financial savings and generally to inform the students of Glasgow!

6. And to make it even easier…. You will work in pairs (optional) Only two visits per household There will be ongoing support from the Co-ordinator and the University Free telephone support from Energy Saving Trust

7. Why Volunteer Great CV material: Customer service experience Technical and administrative experience Can appeal to specific disciplines (e.g. in the Energy Sector) Career Opportunities - Energy is growing industry Volunteering is the way to start! Personal knowledge of keeping warm and saving money. Practical life skills! Reference from the university – volunteering appears on your transcript!

8. 2. INTRODUCTION TO ENERGY

9. You know your shoe size but do you know your carbon footprint?

10. Where does our Carbon Footprint come from? Food Waste Travel Energy

11. Energy sources for UK electricity generation (DTI, Aug 2007) Coal 35.8% Natural Gas38.8% Other (oil) 2.1% = Fossil Fuels 76.7% (produce CO2) Nuclear 18.6% Renewables 4.7%

12. Renewables: No need to worry? Current energy and resource consumption rate unsustainable!

13. Renewables: No need to worry? Useful video: http://www.youtube.com/watch?feature=player_embedded&v=VOMWzjrRiBg Technology ≠ Energy! Current economic system requires endless growth – constantly increasing energy consumption – more oil reserves …but no one is questioning the fact that we’re living in an exponential growth model with a finite resource base… The American dream: http://www.youtube.com/watch?v=ZPWH5TlbloU http://www.youtube.com/watch?v=ZPWH5TlbloU Move towards a low-energy society?

14. For individuals, about 40% of our carbon emissions come from our homes.

15. And that’s where we come in! It is estimated that one third of this energy is wasted. This costs the UK £5 Billion, not to mention the environmental damage!

16. Let’s not forget about the MONEY HEATING, COOKING POWER RATING COST TO RUN FOR ONE HOUR 3 bar Electric Fire3000 W36p Oil Filled Radiator 500 – 2000 W6p – 24p Fan Heater2000 – 3000W24p – 36p Immersion Heater 3000 W36p Cooker – 1 ring1400 W17p Oven only 2150 W26p Oven & rings 11500W £1.38 Electric showers 7500 – 12000 W £ 0.9–£1.44 http://www.carbonfootprint.com/energyconsumption.html

17. So what can we do?

18. Useful tips for water by Energy Saving Trust: http://www.youtube.com/watch?v=J7GNTAWfX Kk&feature=player_embedded&noredirect=1 WATER

19. Targets for CO² Emissions Kyoto Target - To cut overall emissions of greenhouse gases by 5.2% below 1990 by 2008-2012 Scottish Government targets: CO2 reduction of 42% by 2020 and 80% by 2050 – one of the most ambitious in the world

20. 3. Getting to know your home

21. Where does all the heat go? Roof Windows Open doors and windows Walls Through the floor Draughts

22. Cavity wall insulation saves around £115 per year 12% 33% 18% 26% 8% Loft Insulation saves up to £150 per year Double Glazing saves around £135 per year Floor Insulation saves £50 per year Draught Proofing saves £25 per year Where does all the heat go? Source: http://www.energysavingtrust.org.uk/Home-improvements/Home-insulation-glazing June 2009 based on an uninsulated semi- detached 3 bedroom home with gas central heating 3% Open doors and windows More cost effective Less cost effective Where does all the heat go?

23. Detached Mid-terraceSemi-detached End-terrace Property Types The more exposed surfaces (outside walls / roof / basement), the greater the heat loss. Question 2 Flat

24. Pre-1900. Solid stone. Single glazed windows. Post-1950s. Solid concrete walls. Double glazed UPVC Windows. Age of property 1900 – 1920s. Single glazed windows. Solid stone walls. 1930s. Brick cavity walls. Upper floor conversions.

25. Wall type & heat loss Brick: could be solid brick, or could have a cavity. Solid stone: most older properties Timber frame: lots of modern builds use this type. Rarer: Conservatory / garage slows down heat loss from the wall it is attached to. Question 13

26. Wall type & heat loss Question 13 If your house was built after the 1920s it is likely to have cavity walls. Older houses are more likely to have solid walls If your home has solid walls, the bricks will have an alternating pattern like this: If you can see the brickwork on the outside of the house, look at the pattern of the bricks. If your home has cavity walls, the bricks will usually have a regular pattern like this:

27. Insulation Loft insulation Draughtproofing Cavity wall insulation 27cm is recommended minimum Open fireplaces can be blocked-off or a chimney balloon can be installed to exclude draughts. Question 16 -17

28. Windows Secondary glazing Shutters Shutters and secondary glazing can cut heat loss through window by half to a third Draughtproofing reduces heat loss through gaps around the window Secondary glazing film is cheap and DIY, but single-use Question 14 -15

29. Heating Electric Storage Heaters Store, then release heat. Room Heaters Gas or electric. Directly use energy as they heat (peak electricity) Rarer: Underfloor Heating Can electric cable or powered from gas boiler. More common in new builds / conversions. ‘Wet’ Boiler & Radiators Gas or electric. Question 18

30. Main Heating Fuels Bottled gas Anthracite Bulk LPG House Coal Smokeless Coal Gas Electricity

31. ‘Wet’ Boiler & Radiators May have a water tank or may not. Gas Central Heating Gas Boiler (does it have a blue flame?) Wet radiators Hot water tank or cylinder TRV

32. Electric Central Heating Storage Heaters Electric ‘Wet’ Radiators Input /output control Electric wet heating will not give instant water. Emersion tank needed

33. Gas fire Open ‘real’ fire Decorative gas fire Gas/open fire with back boiler Bottled gas heaters Secondary Heating (standalone) Electric heaters Question 29

34. Heating control: Boiler & Radiators Can have any combination of… Timer: to set when heating / hot water is on / off. Room thermostat: to accurately maintain temperature of room / house, when heating is on, by controlling all radiators (fires or turns off boiler). Thermostatic radiator valves: less accurately maintain temperature of a room by controlling an individual radiator. Hotter than 20 o C is wasting energy. On thermostatic valves half way = 18-20 o C. 1 o C cooler = 10% cut in bill Question 22

35. Heating Control: Storage Heaters Cheaper electricity at night heats up a ‘brick’ inside the heater which acts as a reservoir. Look for DUAL-TARIFF on bill. Input switch controls how much heat gets stored overnight Output switch controls how much heat gets let out during the day Boost switch gives more heat directly from electricity during the day (more expensive) If output is turned up at night heat will escape rather than be stored. Can have thermostatic control like radiators example. If input is turned down at night less heat will be stored.

36. Boiler Types Question 20 Condensing boiler: middle plastic pipe

37. Boiler and tank: ‘Normal’ boiler: with linked hot water tank. Boiler but no tank: Combination boiler: fires when hot tap is turned. Hot water Tank can be insulated with jacket and pipes with lagging. Can be additional electrical immersion element to ‘top-up’ water heated by a boiler. Rarer: Over the sink instant hot water. Can be gas or electric. Question 20

38. Showers Mixer shower: takes water from the hot water tank. Electric shower: heats instantly using a lot of electricity. Question 31

39. Insulation Heating Water Washing Lighting Cooking Appliances So what can we do?

40. 4. Behaviour Change Questionnaire

43. Energy Monitors Help household to fit energy monitor Decide dates to record energy usage Find an old electricity bill and record usage for the same time last year Set a family challenge Compare data on return visit one month from now.

45. What about carbon?

46. If you know how many kWh you use (appliances, energy tracker, meter or bills) it is very easy to calculate a ‘carbon footprint’. The average volume of CO 2 released into the atmosphere per kWh of electricity is: 0.543 kg (DEFRA’s new figure*). What about carbon? * 0.54303kg - June 2009 guidelines

47. 602 kWh/year x 0.543 kg = 327 kgCO 2 /year So this little fridge is responsible for 0.3 tCO 2 /year

48. £££ cost of electricity Gone up 65% in last 4 years!! Heading one way A typical current campus cost is 12p / kWh Consider: –Day and night (12am to 7am) rates

49. 602 kWh/year x £0.12 = £72.24 per year So this little fridge will cost around £72 to run a year

50. Night club ventilation system10,000 W Air conditioning cassette 3,500 W Dairy deck fridge2,500 W Electric heater 2,000 W Bottle fridge900 W Water cooler (NB: when cooling)750 W 1 x standard tungsten filament (TFL) bulb100 W 1 x energy efficient bulb11 W Mobile phone charger on standby>1 W

51. Calculating energy consumption A Cafe has 44 x 50W tungsten filament halogen bulbs in the seating area. They are on for 10 hours, 6 days a week for 51 weeks a year. (Their average tariff for electricity is £0.12 per KWh) What is the value of the energy they consume in a year? » And what is their carbon footprint? Example – Halogen bulbs in a Cafe

52. Hours open per year? 10hours x 6 days x 51 weeks = 3060 hours per year. Watt hours per year? 50 W x 3060 hours = 153,000 watt hours per bulb per year. 44 bulbs x 153,000 = 6,732,000 watt hours per year. kWh’s per year? 6,732,000 watt hours / 1000 = 6,732 kWh Cost? 6732kWh x £0.12 = £807.84 Carbon? 6732kWh x 0.543kg of CO 2 = 3655.5 kg of CO 2 = 3.6 tonnes of CO 2

53. Giving your landlord the lowdown

55. 4. Volunteer Support

57. Help! I don’t know the answer? Energy Saving Trust free helpline: 0800 512 012 www.energysavingtrust.org.uk/

58. So...what now? Volunteering benefits Energy audit: Ask for Energy Peformance Certificate Check type of house, heating, insulation, electrical appliances, water heating Behaviour questionnaire Install energy monitor

59. Admin Code of Conduct Data Protection Volunteer Policy & Agreement Confidentiality Agreement

60. FIN