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Thermodynamics Lecture Series

Thermodynamics Lecture Series. Assoc. Prof. Dr. J.J. Second Law – Quality of Energy-Part1. 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. Quotes.

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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-Part1 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. Symbols • Q • q • W •  • V •  • E • 

  4. Introduction - Objectives Objectives: • Explain the need for the second law of thermodynamics on real processes. • State the general and the specific statements of the second law of thermodynamics. • State the meaning of reservoirs and working fluids. • List down the characteristics of heat engines.

  5. Introduction - Objectives Objectives: • State the difference between thermodynamic heat engines and mechanical heat engines. • Sketch an energy-flow diagram indicating the flow of energy and label all the energies and all the reservoirs for a steam power plant. • Sketch a schematic diagram for a steam power plant and label all the energies, flow of energies and all the reservoirs.

  6. Introduction - Objectives Objectives: • State the desired output and required input for a steam power plant. • State the meaning of engines’ performance and obtain the performance of a steam power plant in terms of the heat exchange. • State the Kelvin-Planck statement on steam power plant.

  7. Introduction - Objectives Objectives: • Sketch an energy-flow diagram indicating the flow of energy and label all the energies and all the reservoirs for a refrigerator. • Sketch a schematic diagram for a refrigerator and label all the energies, flow of energies and all the reservoirs. • State the desired output and required input for a refrigerator.

  8. Introduction - Objectives Objectives: • Obtain the performance of a refrigerator in terms of the heat exchange. • Sketch an energy-flow diagram indicating the flow of energy and label all the energies and all the reservoirs for a heat pump. • Sketch a schematic diagram for a a heat pump and label all the energies, flow of energies and all the reservoirs.

  9. Introduction - Objectives Objectives: • State the desired output and required input for a a heat pump. • Obtain the performance of a a heat pump in terms of the heat exchange. • State the Clausius statement for refrigerators and heat pumps. • Solve problems related to steam power plants, refrigerators and heat pumps.

  10. 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

  11. Win Wout Mass in Mass out Qin Qout System E1, P1, T1, V1 To E2, P2, T2, V2 Review - First Law Properties will change indicating change of state How to relate changes to the cause Dynamic Energies as causes (agents) of change

  12. Review - First Law Energy Balance Amount of energy causing changemust be equal toamount of energy change of system

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

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

  15. Review - First Law Energy Balance – Control Volume Steady-Flow Steady-flow is a flow where all properties within boundary of the system remains constant with time DEsys= 0, kJ; Desys= 0 , kJ/kg, DVsys= 0, m3; Dmsys= 0 or min = mout , kg

  16. Review - First Law Mass & Energy Balance–Steady-Flow CV Mass balance Energy balance qin + win + qin = qout+ wout+ qout, kJ/kg

  17. Review - First Law Mass & Energy Balance–Steady-Flow: Single Stream Mass balance Energy balance qin – qout+ win – wout = qout – qin, kJ/kg = hout - hin + keout– kein + peout - pein, kJ/kg

  18. First Law – Heat Exchanger Heat Exchanger Boundary has 2 inlets and 2 exits

  19. First Law – Heat Exchanger Heat Exchanger Boundary has 1 inlet and 1 exit

  20. First Law of Thermodynamics Heat Exchanger • no mixing • 2 inlets and 2 exits In, 3 In, 1 Exit, 2 Exit, 4

  21. First Law of Thermodynamics Heat Exchanger • no mixing • 1 inlet and 1 exit In, 3 In, 1 Exit, 2 Exit, 4

  22. First Law of Thermodynamics Heat Exchanger Case 1 Energy balance Mass balance

  23. Qout First Law of Thermodynamics Heat Exchanger Case 2 Mass balance Energy balance

  24. First Law of Thermodynamics Heat Exchanger Energy balance: Case 1 Purpose: Remove or add heat Mass balance: where

  25. First Law of Thermodynamics Heat Exchanger Mass balance: Purpose: Remove or add heat Energy balance: Case 2 where Qout

  26. First Law of Thermodynamics Heat Exchanger Mass balance: Purpose: Remove or add heat Energy balance: Case 2 Qin where

  27. 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

  28. 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.

  29. 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.

  30. Tsys,initial=25C Qin Qin Second Law qin – 0 + 0 - 0 = Du =u2-u1 kJ/kg • First Law involves quantity or amount of energy to be conserved in processes Tsurr=25C Tsys,final=40C This is a NOT a natural process!!! Q does not flow from low T to high T medium. Never will equilibrium be reached But is the process in this cup possible??

  31. Second Law • First Law is not sufficient to determine if a process can or cannot proceed

  32. 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.

  33. 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.

  34. Second Law Heat Engine Characteristics: Receive heat from a high T source. Convert part of the heat into work. Reject excess heat into a low T sink. Operates in a cycle.

  35. Second Law Thermodynamics heat engines – external combustion: steam power plants Heat Engines Combustion outside system Mechanical heat engines – internal combustion: jets, cars, motorcycles Combustion inside system Performance = Desired output / Required input

  36. 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

  37. Second Law Working fluid: Water High T Res., TH Furnace qin = qH Boiler Turbine Pump out in Condenser qout = qL qin- qout = out - in Low T Res., TL Water from river qin- qout = net,out A Schematic diagram for a Steam Power Plant

  38. Second Law Thermal Efficiency for steam power plants

  39. Second Law Thermal Efficiency for steam power plants

  40. Second Law Kelvin Planck Statement for steam power plants It is impossible for engines operating in a cycle to receive heat from a single reservoir and convert all of the heat into work. Heat engines cannot be 100% efficient.

  41. 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.

  42. Com pressor Second Law Working fluid: Refrigerant-134a High T Res., TH Kitchen/Outside house qout = qH Condenser in Throttle Valve Evaporator qin = qL Low T Res., TL Ref. Space/Room A Schematic diagram for a Refrigerator/Air Cond.

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

  44. Second Law Coefficient of Performance for a Refrigerator

  45. 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

  46. Com pressor Second Law Working fluid: Refrigerant-134a High T Res., TH Inside house qout = qH Condenser in Throttle Valve Evaporator qin = qL Low T Res., TL Outside the house A Schematic diagram for a Heat Pump

  47. Second Law Coefficient of Performance for a Heat Pump

  48. Second Law Clausius Statement on Refrigerators/Heat Pump It is impossible to construct a device operating in a cycle and produces no effect other than the transfer of heat from a low T to a high T medium. Must do external work to the device to make it function. Hence more energy removed to the surrounding.

  49. 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

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