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Chapter 24 Thermodynamics

Chapter 24 Thermodynamics. The study of heat and its transformation into mechanical work. If we increase the thermal motion of atoms what happens? Temperature increases. There seems to be no upper limit of temperature. However, there is a lower limit. Absolute Zero.

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Chapter 24 Thermodynamics

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  1. Chapter 24 Thermodynamics

  2. The study of heat and its transformation into mechanical work.

  3. If we increase the thermal motion of atoms what happens? Temperature increases.

  4. There seems to be no upper limit of temperature. However, there is a lower limit.

  5. Absolute Zero • The point at which all molecular motion stops.

  6. No more energy can be extracted from a substance and the temperature can not be lowered any further.

  7. Kelvin: 0 K • Celsius: -273 oC • Fahrenheit: -459 oF

  8. First Law of Thermodynamics: The internal energy of an isolated system is constant.

  9. The increase in the internal energy of a system is equal to the amount of energy added by heating the system, minus the amount lost as a result of the work done by the system on its surroundings.

  10. Signs (+/-) will tell you if energy is entering or leaving a system. + indicates energy enters a system .- indicates energy leaves a system.

  11. First Law of Thermodynamics

  12. Heat can be used to do work. • Heat and work are energy transferred to or from a system.

  13. Work done on or by a gas is the pressure times the change in volume. W = PDV

  14. Work is the transfer of energy that takes place when an object is moved against an opposing force i.e. a system does work when it expands against an external pressure Car engine: petrol burns & produces gases which push out pistons in the engine and transfer energy to the wheels of car • Work stimulates uniform motion • Heat and work can be considered as energy in transit

  15. Ex: An engine cylinder compresses a volume of gas by 0.04 m3. How much work is done by the cylinder if it exerts a constant pressure of 7.5 x 105 Pa?

  16. G: P = 7.5 x 105 Pa, DV = 4 x 10-2 m3 U: W = ? E: W = PDV S: W =(7.5 x 105)(4 x 10-2) S: W = 30,000 J

  17. DU = Q + W • Q = quantity of heat that enters or leaves a system.

  18. DU = the change in internal energy. W = work done on (+) or by the system (-).

  19. Ex: When 5000 J of heat is added to an engine, the engine does 1250 J of work. What is the change in the internal energy of engine?

  20. Q = 5000 J W = 1250 J DU = ?

  21. DU = Q + W DU = Q – W DU = 5000 J–1250 J DU = 3750 J

  22. Adiabatic • The process of compression or expansion of a gas so that no heat enters or leaves a system.

  23. Read Ch 24.3 in CP book. • Examples combustion engine, bike pump, weather conditions.

  24. Starting position, intake stroke, and compression stroke. Ignition of fuel, power stroke, and exhaust stroke.

  25. intake/induction stroke • 2. compression stroke • 3. power stroke • 4. exhaust stroke

  26. 2nd Law of Thermodynamics Heat flows spontaneously from a body of a higher temperature to a one at a lower temperature.

  27. Heat Engine Any device that changes internal energy into mechanical work.

  28. To reverse the flow work must be done.

  29. Ex: steam engine, internal combustion engine, jet engine, etc.

  30. The basic idea of a heat engine is that mechanical work can be obtained only when heat flows from hot to cold temperatures.

  31. Not all heat is transformed into work.

  32. "Typical engines are only 15 to 20 percent efficient in consuming oil, as they lose a lot of energy when they emit hot exhaust gas into the air."

  33. Every heat engine will: • Absorb internal energy from a reservoir of higher temperature.

  34. 2. Convert some of this energy into mechanical work. 3. Expel the remaining energy to some lower temperature reservoir, usually called a “sink”.

  35. When undesirable heat is expelled, its called thermal pollution.

  36. Power plants and industrial factories are among the major contributors to the problem of thermal pollution. These facilities draw water from nearby lakes and streams, which they use to cool their machinery and steam-driven equipment. Although many such facilities now take care not to contaminate the water with chemical pollutants, few return the heated water to its original temperature before dumping it back into the lakes and streams from which it came. The heated water warms local bodies of water by as much as 10° C (18° F), making the water uninhabitable for fish and other organisms.

  37. Carnot Efficiency The maximum amount of energy that can be converted to work in a heat engine.

  38. This gives us the ‘ideal efficiency’.

  39. This gives us the ‘ideal efficiency’.

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