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PHYSICS 231 INTRODUCTORY PHYSICS I

PHYSICS 231 INTRODUCTORY PHYSICS I. Lecture 19. Last Lecture. First Law of Thermodynamics Work done by/on a gas. V. V. V. V. Some Vocabulary. P. Isobaric P = constant Isovolumetric V = constant W = 0 Isothermal T = constant  U = 0 (ideal gas) Adiabatic Q = 0. P. P. P.

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PHYSICS 231 INTRODUCTORY PHYSICS I

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  1. PHYSICS 231INTRODUCTORY PHYSICS I Lecture 19

  2. Last Lecture • First Law of Thermodynamics • Work done by/on a gas

  3. V V V V Some Vocabulary P • Isobaric • P = constant • Isovolumetric • V = constant • W = 0 • Isothermal • T = constant • U = 0 (ideal gas) • Adiabatic • Q = 0 P P P

  4. P-V Diagrams P Path moves to right: Wby the gas = Area under curve P V Path moves to left: Wby the gas = - Area under curve V (Won the gas = - Wby the gas)

  5. Work from closed cycles Clockwise cycle: WA->B->A= Area Counterclockwise cycle: WA->B->A= -Area (work done by gas) in closed cycles

  6. Example 12.8a C P Consider an ideal gas undergoing the trajectory through the PV diagram. In going from A to B to C, the work done BY the gas is _______ 0. B A V > < =

  7. Example 12.8b C P In going from A to B to C, the change of the internal energy of the gas is _______ 0. B A V > < =

  8. Example 12.8c C D P In going from A to B to C, the amount of heat added to the gas is _______ 0. B A V > < =

  9. Example 12.8d C D P In going from A to B to C to D to A, the work done BY the gas is _______ 0. B A V > < =

  10. Example 12.8e C D P In going from A to B to C to D to A, the change of the internal energy of the gas is _______ 0. B A V > < =

  11. Example 12.8f C D P In going from A to B to C to D to A, the heat added to the gas is _______ 0. B A V > < =

  12. Example 12.7 Consider a monotonic ideal gas. a) What work was done by the gas from A to B? b) What heat was added to the gas between A and B? c) What work was done by the gas from B to C? d) What heat was added to the gas between B and C? e) What work was done by the gas from C to A? f) What heat was added to the gas from C to A? P (kPa) A 75 20,000 J 50 20,000 J B 25 -10,000 J C V (m3) -25,000 J 0.2 0.4 0.6 0 15,000 J

  13. Example 12.7 (Continued) |Qin| P (kPa) g) What was total work done by gas in cycle? h) What was total heat added to gas in cycle? A WAB + WBC + WCA = 10,000 J B C QAB + QBC + QCA = 10,000 J V (m3) This does NOT mean that the engine is 100% efficient! |Qout| Exhaust!!! |Qin|= QAB + QCA= 35,000 J |Qout| = |QBC| = 25,000 J Weng = |Qin|-|Qout|

  14. Qhot engine W Qcold Heat Engines • Described by a cycle with: Qhot= heat that flows into engine from source at ThotQcold= heat exhausted from engine at lower temperature, Tcold W= work done by engine • Efficiency is defined: using

  15. 2nd Law of Thermodynamics(version 1) The most efficient engine is the Carnot Engine (an idealized engine), for which: No heat engine can be 100% efficient (T in Kelvin) In practice, we always have

  16. Carnot Cycle

  17. Example 12.9 An ideal engine (Carnot) is rated at 50% efficiency when it is able to exhaust heat at a temperature of 20 ºC. If the exhaust temperature is lowered to -30 ºC, what is the new efficiency. e = 0.585

  18. Qhot fridge W Qcold Refrigerators • Just a heat engine run in reverse! • Pull Qcold from fridge • Exhaust Qhot to outside Coefficient of Performance: Most efficient is Carnot refrigerator: Note: Highest COP for small T differences

  19. Qhot heatpump W Qcold Heat Pumps • Same as refrigerator, except • Pull Qcold from environment • Exhaust Qhot to inside of house Coefficient of Performance: Again, most efficient is Carnot: Like Refrigerator: Best performance for small DT

  20. Example 12.10 A modern gas furnace can work at practically 100% efficiency, i.e., 100% of the heat from burning the gas is converted into heat for the home. Assume that a heat pump works at 50% of the efficiency of an ideal heat pump. If electricity costs 3 times as much per kw-hr as gas, for what range of outside temperatures is it advantageous to use a heat pump?Assume Tinside = 295 ºK.

  21. Entropy • Measure of Disorder of the system(randomness, ignorance) • S = kBlog(N) N = # of possible arrangements for fixed E and Q Relative probabilities for 12 molecules to arrange on two halves of container.

  22. 2nd Law of Thermodynamics(version 2) On a macroscopic level, one finds that adding heat raises entropy: The Total Entropy of the Universe can never decrease. Defines temperature in Kelvin!

  23. Why does Q flow from hot to cold? • Consider two systems, one with TA and one with TB • Allow Q > 0 to flow from TA to TB • Entropy changes by:DS = Q/TB - Q/TA • This can only occur if DS > 0, requiring TA > TB. • System will achieve more randomness by exchanging heat until TB = TA

  24. Carnot Engine Carnot cycle is most efficient possible, because the total entropy change is zero. It is a “reversible process”. For real engines:

  25. Example 12.11a An engine does an amount of work W, and exhausts heat at a temperature of 50 degrees C. The chemical energy contained in the fuel must be greater than, and not equal to, W. a) True b) False

  26. Example 12.11b A locomotive is powered by a large engine that exhausts heat into a large heat exchanger that stays close to the temperature of the atmosphere. The engine should be more efficient on a very cold day than on a warm day. a) True b) False

  27. Example 12.11c An air conditioner uses an amount of electrical energy U to cool a home. The amount of heat removed from the home must be less than or equal to U. a) True b) False

  28. Example 12.11d A heat pump uses an amount of electrical energy U to heat a home. The amount of heat added to a home must be less than or equal to U. a) True b) False

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