1. Chapter 16: Energy Efficiency and Renewable Energy –Evaluating Energy Resources

2. Chapter 15: Energy Efficiency and Renewable Energy –Evaluating Energy Resources –What Types of Energy Do We Use?

3. Chapter 16: Energy Efficiency and Renewable Energy –Evaluating Energy Resources –What Types of Energy Do We Use? Some 99% of the energy used to heat the earth, and all of our buildings, comes directly from the sun.

4. Chapter 16: Energy Efficiency and Renewable Energy –Evaluating Energy Resources –What Types of Energy Do We Use? Some 99% of the energy used to heat the earth, and all of our buildings, comes directly from the sun. Solar energy also helps recycles the carbon, oxygen, water, and other chemicals we and other organisms need to stay alive and healthy.

5. This direct input of solar energy also produces several forms of renewable energy:

6. wind falling/flowing water(hydropower) biomass (solar energy converted to chemical energy stored in the chemical bonds of organic compounds in trees and other plants).

7. The remaining 1%, the portion we generate to supplement the solar input, is commercial energy sold in the marketplace.

8. Most comes from extracting and burning mineral resources obtained from the earth’s crust, primarily nonrenewable fossil fuels.

9. How Should We Evaluate Energy Resources?

10. Experience shows that it usually takes at least 50 years and huge investments to phase in new energy alternatives.

11. How Should We Evaluate Energy Resources? Experience shows that it usually takes at least 50 years and huge investments to phase in new energy alternatives. We must answer the following questions for each energy alternative:

12. How Should We Evaluate Energy Resources? Experience shows that it usually takes at least 50 years and huge investments to phase in new energy alternatives. We must answer the following questions for each energy alternative:

13. How much of the energy source will be available in the near future (the next 15 years)

14. intermediate future (the next 30 years)

15. How much of the energy source will be available in the near future (the next 15 years) intermediate future (the next 30 years) and for the long term (the next 50 years)?

16. What is this source’s net - energy yield?

17. What is this source’s net energy yield? How much will it cost to develop, phase in, and use this energy resource?

18. What is this source’s net energy yield? How much will it cost to develop, phase in, and use this energy resource? Example... Hydrogen

19. What is this source’s net energy yield? How much will it cost to develop, phase in, and use this energy resource? How will extracting, transporting, and using the energy resource affect the environment?

20. What is this source’s net energy yield? How much will it cost to develop, phase in, and use this energy resource? How will extracting, transporting, and using the energy resource affect the environment? What will using this energy source do to help sustain the earth for us, for the future generations, and for the other species living on this planet?

21. What is Net Energy?

22. The Only Energy That Really Counts

23. It takes energy to get energy

24. First Law of Thermodynamics...

25. It takes energy to get energy (second law of energy – when we use energy some of it is always wasted and is degraded to low- quality energy).

26. Net Energy

27. the total useful energy available from the resource over its lifetime, minus the amount of energy used.

28. Net Energy the total useful energy available from the resource over its lifetime, minus the amount of energy used. (the first law of energy)

29. Net Energy the total useful energy available from the resource over its lifetime, minus the amount of energy used. (the first law of energy) automatically wasted

30. Net Energy the total useful energy available from the resource over its lifetime, minus the amount of energy used. (the first law of energy) automatically wasted (the second law of energy)

31. Net Energy the total useful energy available from the resource over its lifetime, minus the amount of energy used. (the first law of energy) automatically wasted (the second law of energy) and unnecessarily wasted in finding, processing, concentrating, and transporting it to users.

32. Net Energy Ratio

33. the ratio of useful energy produced to the useful energy used to produce it.

34. Net Energy Ratio the ratio of useful energy produced to the useful energy used to produce it. The higher the ratio-

35. Net Energy Ratio the ratio of useful energy produced to the useful energy used to produce it. The higher the ratio-the greater the net energy yield.

36. Net Energy Ratio the ratio of useful energy produced to the useful energy used to produce it. The higher the ratio-the greater the net energy yield. When the ratio is less than 1, there is a net energy loss.

37. The Importance of Improving Energy Efficiency What is Energy Efficiency?

38. The Importance of Improving Energy Efficiency What is Energy Efficiency? Doing More with Less

39. The Importance of Improving Energy Efficiency What is Energy Efficiency? Doing More with Less 84% of all commercial energy used in the U.S. is wasted.

40. The Importance of Improving Energy Efficiency What is Energy Efficiency? Doing More with Less 84% of all commercial energy used in the U.S. is wasted. People in the U.S. unnecessarily waste as much energy as 2/3 of the world’s population consumes.

41. The Importance of Improving Energy Efficiency What is Energy Efficiency? Doing More with Less 84% of all commercial energy used in the U.S. is wasted. People in the U.S. unnecessarily waste as much energy as 2/3 of the world’s population consumes. THERFORE...

42. The easiest, fastest, and cheapest way to get more energy with the least environmental impact is to eliminate mush of this energy waste by making lifestyle changes that reduce energy consumption:

43. The easiest, fastest, and cheapest way to get more energy with the least environmental impact is to eliminate mush of this energy waste by making lifestyle changes that reduce energy consumption: HOW???

44. walking or biking for short trips, using mass transit, putting on a sweater instead of turning up the thermostat, and turning off unneeded lights.

45. Another important way is to increase the efficiency of the energy conversion devices we use.

46. Energy Efficiency

47. Another important way is to increase the efficiency of the energy conversion devices we use. Energy Efficiency: the percentage of total energy input that does useful work (is not converted to low-quality, essentially useless heat)

48. Life Cycle Cost

49. Life Cycle Cost:initial cost plus lifetime operating costs

50. (some energy-efficient models may cost more initially but in the long run they usually save money by having a lower life cycle cost)

51. Why Is Reducing Energy Waste So Important?

52. Makes nonrenewable fossil fuels last longer.

53. Why Is Reducing Energy Waste So Important? Makes nonrenewable fossil fuels last longer. Gives us more time to phase in renewable energy resources.

54. Why Is Reducing Energy Waste So Important? Makes nonrenewable fossil fuels last longer. Gives us more time to phase in renewable energy resources. Decreases dependence on oil imports.

55. Why Is Reducing Energy Waste So Important? Makes nonrenewable fossil fuels last longer. Gives us more time to phase in renewable energy resources. Decreases dependence on oil imports. Lessens the need for military intervention in the oil-rich but politically unstable Middle East.

56. Why Is Reducing Energy Waste So Important? Makes nonrenewable fossil fuels last longer. Gives us more time to phase in renewable energy resources. Decreases dependence on oil imports. Lessens the need for military intervention in the oil-rich but politically unstable Middle East. Reduces local and global environmental damage.

57. Is the cheapest and quickest way to slow projected global warming.

58. Saves more money, provides more jobs, improves productivity, and promotes more economic growth per unit of energy than other alternatives.

59. Is the cheapest and quickest way to slow projected global warming. Saves more money, provides more jobs, improves productivity, and promotes more economic growth per unit of energy than other alternatives. Improves competitiveness in the international marketplace.

60. Ways to Improve Energy Efficiency

61. How Can We Use Waste Heat? For a house, insulate thoroughly, eliminate air leaks, and equip it with an air-to-air heat exchanger to prevent buildup of indoor air pollutants.

62. In office buildings and stores, waste heat from lights, computers, and other machines can be collected and distributed to reduce heating bills during cold weather; during hot weather, this heat can be collected and vented out doors to reduce cooling bills.

63. Waste heat from industrial plants and electrical power plants can be used to produce electricity (cogeneration)

64. it can also be distributed through insulated pipes to heat nearby buildings, greenhouses, and fist ponds, as is done in some parts of Europe.

65. How Can We Save Energy in Industry?

66. Cogeneration

67. How Can We Save Energy in Industry? Cogeneration-the production of two useful forms of energy (such as steam and electricity) from the same fuel source.

68. How Can We Save Energy in Industry? Cogeneration-the production of two useful forms of energy (such as steam and electricity) from the same fuel source. Replacing energy-wasting electric motors.

69. How Can We Save Energy in Industry? Cogeneration-the production of two useful forms of energy (such as steam and electricity) from the same fuel source. Replacing energy-wasting electric motors. Switching to high-efficiency lighting.

70. How Can We Save Energy in Producing Electricity? The Negawatt Revolution

71. How Can We Save Energy in Producing Electricity? The Negawatt Revolution Demand-Side Management or Negawatt Revolution

72. How Can We Save Energy in Producing Electricity? The Negawatt Revolution Demand-Side Management or Negawatt Revolution

73. To reduce demand, utilities give customers cash rebates for buying efficient lights and appliances, free home-energy audits, low- interest loans for home weatherization or industrial retrofits, and lower rates to households or industries meeting certain energy-efficiency standards.

74. Direct Use of Solar Energy For Heat and Electricity

75. How Can Solar Energy Be Used to Heat Houses and Water?

76. Direct Use of Solar Energy For Heat and Electricity How Can Solar Energy Be Used to Heat Houses and Water? Passive Solar Heating System

77. Direct Use of Solar Energy For Heat and Electricity How Can Solar Energy Be Used to Heat Houses and Water? Passive Solar Heating System Active Solar Heating System

78. Direct Use of Solar Energy For Heat and Electricity How Can Solar Energy Be Used to Heat Houses and Water? Passive Solar Heating System Active Solar Heating System Photovoltaic (PV) Cells or Solar Cells

82. http://www.uwsp.edu/cnr/WCEE/keep/Mod1/test/meter.asp