1 / 56

第 三 能源的應用範例 Examples of Energy Application

第 三 能源的應用範例 Examples of Energy Application. 3-1 Home Energy Conservation and Heat-Transfer Control 3-2 Air Conditioning and Heat Pumps 3-3 Heat Engines. 3-1 Home Energy Conservation and Heat-Transfer Control. Building Materials (1).

matthew-randall
Download Presentation

第 三 能源的應用範例 Examples of Energy Application

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. 第 三 能源的應用範例Examples of Energy Application 3-1Home Energy Conservation and Heat-Transfer Control 3-2 Air Conditioning and Heat Pumps 3-3Heat Engines

  2. 3-1 Home Energy Conservation and Heat-Transfer Control

  3. Building Materials (1) • Material that is a good conductor of electricity, such as a metal, is usually a good conductor of heat. • An insulator, such as fiberglass or Styrofoam, will retard the flow of heat from one object to another. We say that it provides a high “resistance” to heat transfer. • Air can be a good insulator, especially if it is motionless, and so porous materials such as fiberglass have an excellent resistance to heat flow thanks to the air trapped inside.

  4. Building Materials (2) • The color of a material also influences heat transfer when radiation is concerned. • A black object is both a better emitter and a better absorber of radiant energy than a white or shiny-surfaced object. • To be in thermal equilibrium with its surroundings, an object that is a good emitter must also be a good absorber. Conversely, a poor emitter will be a bad absorber.

  5. Building Materials (3) • Starting from the same temperature, a hot black object will radiant energy faster than a similar hot light-colored object. • Ice water will remain cold longer if it is placed in a silver-colored dish rather a charcoal-colored one. • Light colored clothes are preferable on hot, sunny days, as they are poor absorbers of radiant energy. • The absorber plates on solar collectors are painted flat black to better absorb the sun’s energy.

  6. Building Materials (4) Add cream immediately or later?

  7. Building Materials (5) • The answer is that you should add cream as soon as possible. The cream makes the black coffee lighter in color, which makes it a poorer radiator. Also the temperature will drop when the cream is added, so the rate of heat transfer by radiation and conduction will decrease as a result of the smaller T.

  8. Building Materials (6) Thermos bottle

  9. House Insulation and Heating Calculations (1) R=/k

  10. House Insulation and Heating Calculations (2)

  11. House Insulation and Heating Calculations (3)

  12. House Insulation and Heating Calculations (4) To obtain an R-value of 22 ft2-h-oF/Btu, you would have to use the indicated thickness of various materials

  13. House Insulation and Heating Calculations (5) Superinsulated office building in Toronto, Canada

  14. House Insulation and Heating Calculations (6)

  15. House Insulation and Heating Calculations (7) Thermal drapes mounted in this arrangement will contribute to heat loss rather than stop them.

  16. House Insulation and Heating Calculations (8) This arrangement is better for reducing convective losses.

  17. House Insulation and Heating Calculations (9) Cold air infiltration can account for 50% of the energy needs of a house.

  18. House Insulation and Heating Calculations (10) Caulking around the foundation of a home reduces air infiltration.

  19. House Insulation and Heating Calculations (11)

  20. House Insulation and Heating Calculations (12)

  21. House Insulation and Heating Calculations (13)

  22. House Insulation and Heating Calculations (14)

  23. Site Selection (1) • A very important factor in convective heat loss is the wind. • Heat loss through walls and roofs as well as through window, door, and foundation cracks directly depend on the wind velocity. • Heat load calculations indicate that an increase in wind velocity from 10 to 15 to 20 mph will increase the building infiltration by 100% and 200%.

  24. Site Selection (2) Planting trees on the leeward side of a hill can substantially reduce the wind velocity over the site. Vegetation or walls can block or deflect natural air flow patterns and so reduce convective heat loss.

  25. Cooling (1) • Less expensive solutions to summer cooling loads can be achieved through many types of passive cooling techniques. The main objective here is to control the heat a building gains from its environments. These principles involve: * Site selection--- location, orientation, vegetation * Architectural features--- surface-to-volume ratio, overhangs, window sizing, shades * Building skin features--- insulation, thermal mass, glazing

  26. Cooling (2)

  27. Cooling (3)

  28. Cooling (4)

  29. Cooling (5)

  30. Cooling (6) Radiant barriers can reduce heat gain in the attic of a house.

  31. 3-2 Air Conditioning and Heat Pumps

  32. Air Conditioning and Heat Pumps (1)

  33. Air Conditioning and Heat Pumps (2)

  34. Air Conditioning and Heat Pumps (3)

  35. Air Conditioning and Heat Pumps (4)

  36. Air Conditioning and Heat Pumps (5) C.O.P. (Coefficient of Performance)= heat transferred/electricity input

  37. Air Conditioning and Heat Pumps (6) • Because a heat pump’s performance varies with the local climate, it is better to speak of a seasonally averaged C.O.P. The seasonal performance factor (SPF) is defined as SPF= total output/total energy consumed

  38. Air Conditioning and Heat Pumps (7) An electrically driven heat pump using Freon as a working fluid. In principle, the system becomes an air conditioner if the fluid flow direction is reversed.

  39. Air Conditioning and Heat Pumps (8) Relative costs of different types of heating fuels.

  40. 3-3 Heat Engines

  41. The Energy Content of Fuels (1) • The burning of hydrocarbon fuels is merely the combining of the carbon and the hydrocarbon from the fuel with oxygen from the air. • C + O2 - CO2 + heat energy H2 + O2 - H2O + heat energy • These two simple reactions are both included in the overall reaction formula for an actual fuel. For example, C7H16 + 11 O2 - 7CO2 + 8 H2O + 1.15x106 calories per 100g C7H16

  42. The Energy Content of Fuels (2) The general pathways by which we utilize energy from fossil fuels

  43. The Thermodynamics of Heat Engines (1) Efficiency=work done/energy put into the system =Qhot-Qcold/Qhot =(1-Qcold/Qhot)x100%

  44. The Thermodynamics of Heat Engines (2) • Carnot Cycle: Qcold/Qhot=Tcold/Thot =(1-Tcold/Thot)x100%

  45. Generation of Electricity (1) A diagram of a fuel-burning electric power plant. Here a river provides cooling water to the condenser.

  46. Generation of Electricity (2) An elementary alternating current generator. A loop of wire is forced to rotate in a magnetic field.

  47. Generation of Electricity (3) Typical efficiency of an electric power plant for converting chemical energy in the fuel into electric energy. The best new plants now achieve nearly 40%.

  48. Gasoline Engines The four strokes of a four-cycle spark-ignited internal combustion engine. (a) compression, (b) combustion, (c) exhaust, and (d) fuel-air intake.

  49. Diesel Engines Ignition is accomplished by the high temperature produced by the compression of air.

More Related