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Enthalpy
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===Compressors=== {{main|Compressor}} [[File:Schematic of compressor.png|thumb|right|Schematic diagram of a compressor in the steady state. Fluid enters the system (dotted rectangle) at point 1 and leaves it at point 2. The mass flow is {{mvar|αΉ}}. A power {{mvar|P}} is applied and a heat flow {{mvar|QΜ}} is released to the surroundings at ambient temperature {{math|''T''{{sub|a}}}} .]] A power {{mvar|P}} is applied e.g. as electrical power. If the compression is [[adiabatic]], the gas temperature goes up. In the reversible case it would be at constant entropy, which corresponds with a vertical line in the {{math|''T'' β ''s''}} diagram. For example, compressing nitrogen from 1 bar (point '''a''') to 2 bar (point '''b''') would result in a temperature increase from 300 K to 380 K. In order to let the compressed gas exit at ambient temperature {{math|''T''{{sub|a}}}}, heat exchange, e.g. by cooling water, is necessary. In the ideal case the compression is isothermal. The average heat flow to the surroundings is {{mvar|QΜ}}. Since the system is in the steady state the first law gives <math display="block"> 0 = -\dot Q + \dot m\, h_1 - \dot m\, h_2 + P ~.</math> The minimal power needed for the compression is realized if the compression is reversible. In that case the [[second law of thermodynamics]] for open systems gives <math display="block"> 0 = -\frac{\, \dot Q \,}{T_\mathsf{a}} + \dot m \, s_1 - \dot m \, s_2 ~.</math> Eliminating {{mvar|QΜ}} gives for the minimal power <math display="block"> \frac{\, P_\mathsf{min} \,}{ \dot m } = h_2 - h_1 - T_\mathsf{a}\left( s_2 - s_1 \right) ~.</math> For example, compressing 1 kg of nitrogen from 1 bar to 200 bar costs at least :{{nobr| {{math| {{big|(}} ''h''{{sub|'''c'''}} β ''h''{{sub|'''a'''}} {{big|)}} β ''T''{{sub|a}}( ''s''{{sub|'''c'''}} β ''s''{{sub|'''a'''}} )}} .}} With the data, obtained with the {{nobr| {{math|''T'' β ''s''}} }} diagram, we find a value of {{nobr| {{math|(430 β 461) β 300 Γ (5.16 β 6.85) {{=}} 476 }}{{sfrac|β―kJβ―|kg}} .}} The relation for the power can be further simplified by writing it as <math display="block"> \frac{\, P_\mathsf{min} \,}{ \dot m } = \int_1^2 \left( \mathrm{d}h - T_\mathsf{a}\,\mathrm{d}s \right) ~.</math> With : {{nobr| {{math| d''h'' {{=}} ''T'' d''s'' + ''v'' d''p'' }} ,}} this results in the final relation <math display="block">\frac{\, P_\mathsf{min} }{ \dot m } = \int_1^2 v\,\mathrm{d}p ~.</math>
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