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Thermodynamics Lecture Series

Thermodynamics Lecture Series. Assoc. Prof. Dr. J.J. Second Law – Quality of Energy - Carnot Engines. Applied Sciences Education Research Group (ASERG) Faculty of Applied Sciences Universiti Teknologi MARA. email: drjjlanita@hotmail.com http://www5.uitm.edu.my/faculties/fsg/drjj1.html.

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Thermodynamics Lecture Series

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  1. Thermodynamics Lecture Series Assoc. Prof. Dr. J.J. Second Law – Quality of Energy - Carnot Engines Applied Sciences Education Research Group (ASERG) Faculty of Applied Sciences Universiti Teknologi MARA email: drjjlanita@hotmail.comhttp://www5.uitm.edu.my/faculties/fsg/drjj1.html

  2. Quotes • It does not matter how slowly you go, so long as you do not stop. --Confucius To be wronged is nothing unless you continue to remember it. --Confucius

  3. Introduction - Objectives Objectives: • State factors of irreversibilities in real cyclic processes. • Explain how each of the irreversibility factor causes energy to degrade. • State what is the purpose to introduce a dream engine • Describe and explain the processes in a Carnot engine.

  4. Introduction - Objectives Objectives: • Apply the first law in each of the process of the Carnot engine. • Sketch a pressure-volume diagram representing a Carnot cycle and label all the energy interaction for a steam power plant. • Sketch a pressure-volume diagram representing a reversed Carnot cycle and label all the energy interaction for a refrigerator or heat pump.

  5. Introduction - Objectives Objectives: • State the Carnot principles. • Use result of Carnot principles to obtain performances for a Carnot steam power plant, Carnot refrigerator and a Carnot heat pump. • Compare performances of Carnot engines to performances of real engines. • Solve problems related to Carnot engines.

  6. Review - First Law • All processes must obey energy conservation • Processes which do not obey energy conservation cannot happen. • Processes which do not obey mass conservation cannot happen Piston-cylinders, rigid tanks Turbines, compressors, Nozzles, heat exchangers

  7. Review - First Law Energy Balance Ein – Eout = Esys, kJ or ein – eout = esys, kJ/kg or

  8. Review - First Law Mass Balance min – mout = msys, kg or

  9. Qout Tsys,initial=40C Qout Second Law 0 -qout+ 0 - 0 = -Du = u1 - u2, kJ/kg OK for this cup • First Law involves quantity or amount of energy to be conserved in processes Tsurr=25C Tsys,final=25C This is a natural process!!! Q flows from high T to low T medium until thermal equilibrium is reached

  10. Tsys,initial=25C Qin Qin Second Law qin – 0 + 0 - 0 = Du = u2 - u1, kJ/kg Tsurr=25C Tsys,final=40C This is NOT a natural process!!! Q does not flow from low T to high T medium. Never will the coffee return to its initial state.

  11. Second Law • First Law is not sufficient to determine if a process can or cannot proceed Introduce the second law of thermodynamics – processes occur in its natural direction. • Heat (thermal energy) flows from high temperature medium to low temperature medium. • Energy has quality & quality is higher with higher temperature. More work can be done.

  12. Second Law Considerations: Work can be converted to heat directly & totally. Heat cannot be converted to work directly & totally. • Requires a special device – heat engine.

  13. Second Law Working fluid: Water High T Res., TH Furnace Purpose: Produce work, Wout, out qin = qH qin - qout = out - in qin = net,out + qout Steam Power Plant net,out net,out = qin - qout qout = qL Low T Res., TL Water from river An Energy-Flow diagram for a SPP

  14. Second Law Thermal Efficiency for steam power plants

  15. Second Law Working fluid: Ref-134a High T Res., TH, Kitchen room / Outside house qout– qin = in - out qout = qH Refrigerator/ Air Cond net,in qin = qL net,in = qout - qin Purpose: Maintain space at low T by Removing qL Low Temperature Res., TL, Inside fridge or house net,in = qH - qL An Energy-Flow diagram for a Refrigerator/Air Cond.

  16. Second Law Coefficient of Performance for a Refrigerator Divide top and bottom by qin

  17. Second Law Working fluid: Ref-134a High Temperature Res., TH, Inside house Purpose: Maintain space at high T by supplying qH qout = net,in + qin qout = qH Heat Pump net,in net,in = qout - qin qin = qL net,in = qH - qL Low Temperature Res., TL, Outside house An Energy-Flow diagram for a Heat Pump

  18. Second Law Coefficient of Performance for a Heat Pump

  19. Second Law – Energy Degrade What is the maximum performance of real engines if it can never achieve 100%?? Factors of irreversibilities • less heat can be converted to work • Friction between 2 moving surfaces • Processes happen too fast • Non-isothermal heat transfer Processes in real devices are irreversible

  20. Second Law – Energy Degrade What is the maximum performance of real engines if it can never achieve 100%?? Factors of irreversibilities • Friction between 2 moving surfaces • Heat generated during compression causes wall of cylinder to increase • Work supplied by surrounding is lost to warming of cylinder walls. • At end of cycle, if piston can be returned to original state, surrounding cannot be returned to original state ( work in not equal to work out).

  21. System System System Second Law – Energy Degrade What is the maximum performance of real engines if it can never achieve 100%?? Factors of irreversibilities • Processes happen too fast • Fast compression causes pressure near piston to be higher than pressure at bottom due to molecules near piston not enough time to react. • Hence more work is required to compress system. (work in bigger than work out)

  22. Second Law – Energy Degrade What is the maximum performance of real engines if it can never achieve 100%?? Factors of irreversibilities • Heat transfer at finite temperature difference • Surrounding loses Q during warming of coke. • Surrounding loses W but supply Q during return process. • After cycle, surrounding not returned to original state since the work supplied by surrounding was not returned to the surrounding.

  23. Second Law – Dream Engine Carnot Cycle-All processes in cycle is completely reversible. Hence performance is the highest. • Isothermal expansion • Slow adding of Q resulting in work done by system (system expand) • Qin – Wout = U = 0. So, Qin = Wout . Pressure drops.

  24. Second Law – Dream Engine Carnot Cycle • Adiabatic expansion • 0 – Wout = U. Final U smaller than initial U. • T & P drops.

  25. Second Law – Dream Engine Carnot Cycle • Isothermal compression • Work done on the system • Slow rejection of Q • - Qout + Win = U = 0. So, Qout = Win . • Pressure increases.

  26. Second Law – Dream Engine Carnot Cycle • Adiabatic compression • 0 + Win = U. Final U higher than initial U. • T & P increases.

  27. P, kPa qin 1 2 4 3 qout , m3/kg Second Law – Dream Engine Carnot Cycle P -  diagram for a Carnot (ideal) power plant

  28. P, kPa qout 1 4 2 3 qin , m3/kg Second Law – Dream Engine Reverse Carnot Cycle P -  diagram for a Carnot (ideal) refrigerator

  29. Second Law – Dream Engine Carnot Principles • For heat engines in contact with the same hot and cold reservoir • All reversible engines have the same performance. • Real engines will have lower performance than the ideal engines.

  30. Second Law Working fluid: Not a factor High T Res., TH Furnace qin = qH P1: 1 = 2 = 3 Steam Power Plants net,out P2: real < rev qout = qL Low T Res., TL Water from river An Energy-Flow diagram for a Carnot SPPs

  31. Second Law Working fluid: Not a factor High T Res., TH, Kitchen room / Outside house qout = qH Rev. Fridge/ Heat Pump net,in qin = qL Low Temperature Res., TL, Inside fridge or house An Energy-Flow diagram for Carnot Fridge/Heat Pump

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