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Published byCamron Palmer Modified over 8 years ago
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11-3 1
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In review, the 1 st law of thermodynamics indicates that all energy entering and leaving the system is accounted for and is conserved. 2
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More work is gained by taking more energy at a higher temperature and giving up less energy at a lower temperature. 3
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The transfer of energy as heat from the high temperature source to the engine would cause the engine to do work. This would not be a cyclic process. 4
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In order for the cycle to be completed, the engine would have to transfer energy always as heat. 5
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Because the only body to which this energy can be transferred is the high temperature source, the engine must do work to transfer this energy. 6
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This is the same amount of work that was made available through the energy transferred as heat from the high temperature body in the first place. 7
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Thus, no net work is obtained from the engine in a cyclic process. 8
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The requirement that a heat engine gives up some energy at a lower temperature in order to do work does not follow the 1 st law of thermodynamics. 9
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This requirement is the basis of what is called the second law of thermodynamics. 10
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The second law of thermodynamics can be stated as follows: No cyclic process that converts heat entirely into work is possible. 11
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According to the 2 nd law of thermodynamics, W can never be equal to Q h in a cyclic process. Some energy must always be transferred as heat to the system’s surroundings. (Q c >0) 12
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A cyclic process cannot completely convert energy transferred as heat into work, nor can it transfer energy as heat from a low temperature body to a high temperature body without work being done in the process. 13
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However, a cyclic process can be made to approach these ideal situations. A measure of how well an engine operates is given by the engine’s efficiency. 14
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Efficiency is a measure of the useful energy taken out of a process relative to the total energy that is put into the process. 15
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Efficiency = W net Q h net work done by engine heat energy added to engine 16
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Efficiency = Q h – Q c Q h heat energy added – heat energy removed heat energy added 17
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Notice that efficiency is a unitless quantity that can be calculated using only the magnitudes for the energies added to and taken away from the engine. 18
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This equation confirms that a heat engine has 100% efficiency only if there is no energy transferred away from the engine as heat. (Q c = 0) 19
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Real heat engines, though, will have efficiencies of less than 1.0. The smaller the fraction of usable energy that an engine can provide, the lower its efficiency. 20
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The equation also provides some important information for increasing engine efficiency. 21
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If the amount of energy added to the system as heat is increased or the amount of energy given up by the system is reduced, the ratio of Q c /Q h becomes smaller and the engine’s efficiency comes closer to 1.0. 22
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The efficiency equation gives only a maximum values for an engine’s efficiency. 23
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Friction and thermal conduction in the engine hinder the engine’s performance and experimentally measured efficiencies are usually lower than the calculated efficiencies. 24
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