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CARNOT CYCLE I am teaching Engineering Thermodynamics using the textbook by Cengel and Boles. This set of slides overlap somewhat with Chapter 6. But here I assume that we have established the concept of entropy, and use the concept to analyze the Carnot cycle in the same way as we analyze any other thermodynamic process. An isolated system conserves energy and generates entropy. I did add a few slides to show how Carnot motivated his idea of entropy using the analogy of waterfall. I used the Dover edition of his book. I went through these slides in one 90-minute lecture. Zhigang Suo, Harvard University
Thermodynamics relates heat and motion thermo = heat dynamics = motion
Stirling engine Please watch this video https://www.youtube.com/watch?v=wGRmcvxB_dk&list=PLZbRNoceG6UmydboILKclQv7Seqy4waCE&index=22
Carnot’s questionHow much work can be produced from a given quantity of heat? “…whether the motive power of heat is unbounded, whether the possible improvements in steam-engines have an assignable limit, a limit which the nature of things will not allow to be passed by any means whatever...” Modern translations Motive power: work Motive power of heat: work produced by heat Limit: Carnot limit, Carnot efficiency Carnot, Reflections on the Motive Power of Fire (1824)
Device runs in cycleSo they can run steadily over many, many cycles Heat, Q Work, W Device
Isolated systemWhen confused, isolate. Isolated system IS Isolated system conservesmass over time: Isolated system conservesenergy over time: Isolated system generatesentropy over time: Define more words:
Reservoir of energy. Reservoir of entropyA (purely) thermal system with a fixed temperature QR reservoir of energy and entropy Fixed TR Changing UR, SR The reservoir has a fixed temperature: The reservoir receives energy by heat Conservation of energy: The reservoir increases entropy (Reversible process. Clausius-Gibbs equation):
Thermodynamics permits heaterA device runs in cycle to convert work to heat Isolated system Reservoir of energy, TR Heat, Q Heat, Q Device Work, W Weight goes down. Device runs in cycle: Isolated system conserves energy: Isolated system generates entropy:
Thermodynamics forbidsperpetual motion of the second kinda device runs in cycle to produce work by receiving heat from a single reservoir Isolated system Reservoir of energy, TR Heat, Q Weight goes up Heat, Q Device Work, W Device runs in cycle: Isolated system conserves energy: Isolated system generates entropy:
Carnot’s remarks “Wherever there exists a difference of temperature, motive power can be produced.” To maximize motive power, “contact (between bodies of different temperatures) should be avoided as much as possible” High-temperature source, TH Q Low-temperature sink, TL Thermal contact of reservoirs of different temperatures generates entropy, and does no work.
Two reservoirs For an engine running in cycle to convert heat to work, a single reservoir will not do; we need reservoirs of different temperatures. Isolated system of 4 parts High-temperature source, TH Engine Wout Low-temperature sink, TL Isolated system conserves energy isolated system generates entropy
Carnot cycle Clapeyron (1834) Carnot (1824) Gibbs (1873)
Carnot efficiency Isolated system Isolated system conserves energy: Isolated system generates entropy: All reversible engines running in cycle between reservoirs of two fixed temperatures TH and TL have the same thermal efficiency (Carnot efficiency): All real engines are irreversible. For an irreversible (i.e. real) engine running in cycle between reservoirs of two fixed temperatures TH and TL, the thermal efficiency is below the Carnot efficiency:
All real processes are irreversible So many ways to generate entropy (i.e., to be irreversible) Friction Heat transfer through a temperature difference
Carnot (1824): Two reservoirsReflections on the Motive Power of Fire. …the re-establishing of equilibrium in the caloric; that is, its passage from a body in which the temperature is more or less elevated, to another in which it is lower. What happens in fact in a steam-engine actually in motion? The caloric developed in the furnace by the effect of the combustion traverses the walls of the boiler, produces steam, and in some way incorporates itself with it. The latter carrying it away, takes it first into the cylinder, where it performs some function, and from thence into the condenser, where it is liquefied by contact with the cold water which it encounters there. Then, as a final result, the cold water of the condenser takes possession of the caloric developed by the combustion...The steam is here only a means of transporting the caloric. These two bodies, to which we can give or from which we can remove the heat without causing their temperatures to vary, exercise the functions of two unlimited reservoirs of caloric. Modern translation Caloric: entropy Reservoir of caloric: Thermal reservoir Carnot (1796-1832)
Carnot:“The steam is here only a means of transporting the caloric.” High-temperature source, TH High-temperature source, TH Engine Q Low-temperature sink, TL Low-temperature sink, TL Thermal contact generates entropyReversible engine transports entropy
Carnot’s analogy in his own words The motive power of a waterfall depends on its height and on the quantity of the liquid; the motive power of heat depends also on the quantity of caloric used, and on what may be termed, on what in fact we will call, the height of its fall, that is to say, the difference of temperature of the bodies between which the exchange of caloric is made. In the waterfall the motive power is exactly proportional to the difference of level between the higher and lower reservoirs. In the fall of caloric the motive power undoubtedly increases with the difference of temperature between the warm and the cold bodies; but we do not know whether it is proportional to this difference. We do not know, for example, whether the fall of caloric from 100 to 50 degrees furnishes more or less motive power than the fall of this same caloric from 50 to zero. It is a question which we propose to examine hereafter. Modern translations Motive power: work Caloric: entropy Carnot, Reflections on the Motive Power of Fire (1824)
Carnot’s analogy in pictures high-height source Wout Low-height sink
Carnot’s analogy in modern terms Fall of caloric (entropy) Fall of water zH TH 1 2 1 2 TL zL 4 3 4 3 m1g m2g S1 S2
Carnot efficiencyreversible engine running between two reservoirs of fixed temperatures TH and TL Carnot efficiency: Low-temperature reservoir is the atmosphere: High-temperature reservoir is limited by materials (Melting point of iron is 1811 K. Metals creep at temperatures much below the melting point.) Carnot efficiency in numbers
23 https://flowcharts.llnl.gov/
Wasted energy Yang, Stabler, Journal of Electronic Materials. 38, 1245 (2009)
Refrigerator Isolated system Isolated system conserves energy: Isolated system generates entropy: Carnot limit:
Isolated system Heat pump Isolated system conserves energy: Isolated system generates entropy: Carnot limit:
Summary • Thermodynamics permits heater (a device running in cycle to convert work to heat). • Thermodynamics forbids perpetual motion of the second kind (a device running in cycle to produce work by receiving heat from a single reservoir of a fixed temperature). • Carnot cycle: A reversible cycle consisting of isothermal processes at two temperatures TH and TL, and two isentropic processes. • All reversible engines running in cycle between reservoirs of two fixed temperatures TH and TL have the same thermal efficiency (Carnot efficiency): • All real engines are irreversible. For an irreversible (i.e. real) engine running in cycle between reservoirs of two fixed temperatures TH and TL, the thermal efficiency is below the Carnot efficiency (Carnot limit): • Carnot cycle also limits the coefficients of performance of refrigerators and heat pumps.