Thermo: Faculty File

Thermo: Faculty File 1 Thermodynamics: An Engineering Approach Yunus A. Cengel and Michael A. Boles 4th Edition, McGraw-Hill Inc., 2002 Reserved >Chapter 1: Basic Concepts of Thermodynamics Problem 1-13: Newton's second law|P01_013.ees|no.hlp|no.bmp Problem 1-70: Basic Barometer|P01_070.ees|no.hlp|no.bmp Problem 1-74: Pressure Due to Spring|P01_074.ees|no.hlp|no.bmp Problem 1-76: Effect of Manometer Fluid|P01_076.ees|no.hlp|no.bmp Problem 1-95: Solution of Nonlinear Equation|P01_095.ees|no.hlp|no.bmp Problem 1-96: Solution to System of Two Equations|P01_096.ees|no.hlp|no.bmp Problem 1-97: Solution of System of Three Equations|P01_097.ees|no.hlp|no.bmp Problem 1-98: Solution of System of Three Equations II|P01_098.ees|no.hlp| no.bmp Problem 1-134E: Windchill Temperature|P01_134E.ees|no.hlp|no.bmp Problem 1-138: Acceleration of Balloon|P01_138.ees|no.hlp|no.bmp >Chapter 2: Properties of Pure Substances Problem 2-27: SI Property Tables|P02_026.ees|no.hlp|no.bmp Problem 2-29E: English Property Tables|P02_029E.ees|no.hlp|no.bmp Problem 2-47: Effect of Elevation and Pot Lid Mass on Boiling Temperature| P02_047.ees|no.hlp|no.bmp Problem 2-54: Water in a constant Pressure Process|P02_054.ees|no.hlp|no.bmp Problem 2-56E: Effect of Initial Pressure on Quality after Const. Vol. Process| P02_056E.ees|no.hlp|no.bmp Problem 2-60: Compressed Liquid Properties|P02_060.ees|no.hlp|no.bmp Problem 2-69: Mass of Helium in a Balloon|P02_069.ees|no.hlp|no.bmp Problem 2-80: Compressibility Factor|P02_080.ees|no.hlp|no.bmp Problem 2-92: Comparison of ideal-gas and van der Waals equations|P02_092.ees| no.hlp|no.bmp Problem 2-95: Comparison of ideal-gas and Beattie-Bridgeman equations| P02_095.ees|no.hlp|no.bmp Problem 2-117: Effect of the Environment Temperature on Balloon Air Temperature| P02_117.ees|no.hlp|no.bmp Problem 2-124: Effect of Surroundings Temperature on Final Pressure in Tanks| P02_124.ees|no.hlp|no.bmp Problem 2-128: Unrestrained Expansion of Refrigerant-134a|P02_128.ees|no.hlp| no.bmp >Chapter 3: Energy Transfer by Heat, Work, and Mass Problem 3-16: Refrigerant-134a in a Constant Pressure Process|P03_016.ees| no.hlp|no.bmp Problem 3-23: Polytropic expansion of a gas|P03_023.ees|no.hlp|no.bmp Problem 3-26: Non ideal-gas isothermal expansion|P03_026.ees|no.hlp|no.bmp Problem 3-30: Boundary Work Done Against Spring|P03_030.ees|no.hlp|no.bmp Problem 3-33: Isothermal Expansion of Refrigerant-134a|P03_033.ees|no.hlp| no.bmp Problem 3-71: Heat Transfer Through Glass Wall|P03_071.ees|no.hlp|no.bmp Problem 3-75: Convection and Radiation Heat Transfer From Ball|P03_075.ees| no.hlp|no.bmp Problem 3-79: Convection and Radiation Heat Transfer From Plate|P03_079.ees| no.hlp|no.bmp Problem 3-82: Radiation Heat Transfer On Spacecraft |P03_079.ees|no.hlp|no.bmp Problem 3-90E: Boundary Work Done By Balloon|P03_090E.ees|no.hlp|no.bmp >Chapter 4: The First Law of Thermodynamics Problem 4-15: Effect of Mass on Time to Vaporize Water |P04_015.ees|no.hlp| no.bmp Problem 4-17: Effect of Pressure on Temperature in Water Tank |P04_017.ees| no.hlp|no.bmp Problem 4-23: Steam piston-cylinder & linear spring|P04_023.ees|no.hlp|no.bmp Problem 4-39: Ideal Gas in a Polytropic Process|P04_039.ees|no.hlp|no.bmp Problem 4-52: Heat Sink|P04_052.ees|no.hlp|no.bmp Problem 4-62: Adiabatic nozzle|P04_062.ees|no.hlp|no.bmp Problem 4-73: Flow through a diffuser|P04_073.ees|no.hlp|no.bmp Problem 4-80: Steam Turbine|P04_080.ees|no.hlp|no.bmp Problem 4-89E: Water Cooled Air Compressor|P04_089e.ees|no.hlp|no.bmp Problem 4-99: Steam Throttle|P04_099.ees|no.hlp|no.bmp Problem 4-109: Mixing Refrigerant-134a mass streams |P04_109.ees|no.hlp|no.bmp Problem 4-116: Steam Condenser|P04_116.ees|no.hlp|no.bmp Problem 4-119: Ethylene glycol-to-water heat exchanger|P04_119.ees|no.hlp|no.bmp Problem 4-131: Steel Plate Cooled in Oil Bath|P04_131.ees|no.hlp|no.bmp Problem 4-137: Effect of Pipe Diameter on Heat Loss|P04_137.ees|no.hlp|no.bmp Problem 4-141: Hair Drier|P04_141.ees|no.hlp|no.bmp Problem 4-164: Balloon Discharge|P04_164.ees|no.hlp|no.bmp Problem 4-199: Ice Cooled Water|P04_199.ees|no.hlp|no.bmp Problem 4-229: Energy Saving Shower Head|P04_229.ees|no.hlp|no.bmp Problem 4-235: Heat Exchanger Effectiveness|P04_235.ees|no.hlp|no.bmp Problem 4-237: Steady-flow Steam Turbine|P04_237.ees|no.hlp|no.bmp Problem 4-242: Connected Water Tanks|P04_242.ees|no.hlp|no.bmp Problem 4-248: Tank Separated By Movable Piston|P04_248.ees|no.hlp|no.bmp Problem 4-259: Balloon Discharge By Steps|P04_259.ees|no.hlp|no.bmp >Chapter 5: The Second Law of Thermodynamics Problem 5-25: Price of Coal|P05_025.ees|no.hlp|no.bmp Problem 5-35E: Effect of Combustion Efficiency on Energy Cost and Usage| P05_035E.ees|no.hlp|no.bmp Problem 5-56: Power Supplied to House Air Conditioner|P05_056.ees|no.hlp| no.bmp Problem 5-83: Effect of Heat Sink Temperature on Power and Thermal Efficiency| P05_083.ees|no.hlp|no.bmp Problem 5-128: Carnot Steam Engine|P05_128.ees|no.hlp|no.bmp Problem 5-130: Carnot Refrigeration Cycle|P05_130.ees|no.hlp|no.bmp Problem 5-135: Combined Carnot Heat Engine and Refrigerator|P05_135.ees|no.hlp| no.bmp Problem 5-149: Heat Pump Water Heater|P05_149.ees|no.hlp|no.bmp Problem 5-159: Maximum Work Extracted from Pond|P05_159.ees|no.hlp|no.bmp >Chapter 6: Entropy Problem 6-27: Effects of Heat Added and Source Temperature on Entropy Change|P06_027.ees|no.hlp|no.bmp Problem 6-33: Entropy Change of Refrigerant-134a|P06_033.ees|no.hlp|no.bmp Problem 6-36: Free Expansion of Water into Vacuum|P06_036.ees|no.hlp|no.bmp Problem 6-40: Insulated, Reversible Piston-Cylinder|P06_040.ees|no.hlp| no.bmp Problem 6-43E: Isentropic Turbine|P06_043E.ees|no.hlp|no.bmp Problem 6-45: Reversible, Adiabatic Compression of Steam|P06_045.ees|no.hlp| no.bmp Problem 6-47: Steam in Reversible, Isothermal Expansion|P06_047.ees|no.hlp| no.bmp Problem 6-52: Energy Exchange Between Aluminum and Iron Blocks|P06_052.ees| no.hlp|no.bmp Problem 6-65: Entropy Change During Polytropic Process|P06_065.ees|no.hlp| no.bmp Problem 6-71: Air in Reversible, Adiabatic Compression|P06_071.ees|no.hlp| no.bmp Problem 6-74: Discharging Tank |P06_074.ees|no.hlp|no.bmp Problem 6-77: Non-Adiabatic Nozzle|P06_077.ees|no.hlp|no.bmp Problem 6-85: Net Work Produced by Steam Power Plant|P06_085.ees|no.hlp| no.bmp Problem 6-88E: Helium Entropy Change During Polytropic Process|P06_0858E.ees| no.hlp|no.bmp Problem 6-96: Turbine Isentropic Efficiency|P06_096.ees|no.hlp|no.bmp Problem 6-101: Compressor Isentropic Efficiency|P06_101.ees|no.hlp|no.bmp Problem 6-107E: Nozzle Isentropic Efficiency|P06_107E.ees|no.hlp|no.bmp Problem 6-160: Steam Turbine Driven Air Compressor|P06_160.ees|no.hlp|no.bmp Problem 6-171: Closed Feedwater Heater|P06_171.ees|no.hlp|no.bmp Problem 6-181: Cylinder Divided by Movable Piston|P06_181.ees|no.hlp|no.bmp Problem 6-188: Multistage Compression|P06_188.ees|no.hlp|no.bmp >Chapter 7: Exergy A Measure of Work Potential Problem 7-19: Heat Engine Second Law Analysis|P07_019.ees|no.hlp|no.bmp Problem 7-31: Heat Transfer from Steam in Radiator|P07_031.ees|no.hlp|no.bmp Problem 7-34: Water Expanding into Vacuum|P07_034.ees|no.hlp|no.bmp Problem 7-36: Electrical Resistance Heater|P07_036.ees|no.hlp|no.bmp Problem 7-53: Second Law Analysis of a Compressor|P07_053.ees|no.hlp|no.bmp Problem 7-55: Throttling Process|P07_055.ees|no.hlp|no.bmp Problem 7-57: Steady-Flow Nozzle|P07_057.ees|no.hlp|no.bmp Problem 7-66: Reversible Work of Compression|P07_066.ees|no.hlp|no.bmp Problem 7-112: Reversible Work for Steam Feedwater Heater|P07_112.ees|no.hlp| no.bmp >Chapter 8: Gas Power Cycles Problem 8-15: Ideal Gas Power Cycle|P08_015.ees|no.hlp|no.bmp Problem 8-34: Ideal Otto Cycle|P08_034.ees|no.hlp|no.bmp Problem 8-51: Ideal Diesel Cycle with Polytropic Expansion|P08_051.ees|no.hlp| no.bmp Problem 8-55: Ideal Dual Cycle|P08_055.ees|no.hlp|no.bmp Problem 8-71: Brayton Cycle|P08_071.ees|no.hlp|no.bmp Problem 8-88: Gas Turbine With Regeneration|P08_088.ees|no.hlp|no.bmp Problem 8-90: Non-ideal Gas Turbine with Regeneration|P08_090.ees|no.hlp| no.bmp Problem 8-116: Turbojet Engine|P08_116.ees|no.hlp|no.bmp Problem 8-123: Second Law Analysis of Brayton Cycle|P08_123.ees|no.hlp|no.bmp Problem 8-133: Otto Cycle|P08_133.ees|no.hlp|no.bmp Problem 8-144: Gas Turbine with Regeneration, Intercooling, and Reheat| P08_144.ees|no.hlp|no.bmp Problem 8-148: Otto Cycle with Variable Specific Heats|P08_148.ees|no.hlp|no.bmp Problem 8-149: Effects of Compression Ratio on Otto Cycle|P08_149.ees|no.hlp| no.bmp Problem 8-150: Effects of Pressure Ratio on Brayton Cycle|P08_150.ees|no.hlp| no.bmp Problem 8-151: Effect of Adiabatic Efficiencies on Brayton Cycle|P08_151.ees| no.hlp|no.bmp Problem 8-152: Diagram Window Version of Brayton Cycle|P08_152.ees|no.hlp|no.bmp Problem 8-153: Effect of Maximum Cycle Temperature on Otto Cycle|P08_153.ees| no.hlp|no.bmp Problem 8-154: Helium as Working Fluid in Brayton Cycle|P08_154.ees|no.hlp| no.bmp Problem 8-155: Diagram Window Version of Regenerative Brayton Cycle|P08_155.ees| no.hlp|no.bmp Problem 8-156: Diagram Window Version of Regenerative Brayton Cycle|P08_156.ees| no.hlp|no.bmp Problem 8-157: Regenerative Brayton Cycle Using Helium|P08_157.ees|no.hlp|no.bmp Problem 8-158: Brayton Cycle with Multistage Compression and Expansion| P08_158.ees|no.hlp|no.bmp Problem 8-159: Brayton Cycle with Multistage Compression and Expansion using Helium|P08_159.ees|no.hlp|no.bmp >Chapter 9: Vapor and Combined Power Cycles Problem 9-28: Rankine Cycle with Reheat|P09_028.ees|no.hlp|no.bmp Problem 9-42: Rankine Cycle with Regeneration|P09_042.ees|no.hlp|no.bmp Problem 9-50: Reheat Rankine Cycle Irreversibilities|P09_050.ees|no.hlp|no.bmp Problem 9-62: Rankine Cycle with Regeneration and Process Heater|P09_062.ees| no.hlp|no.bmp Problem 9-68: Combined Gas-Steam Power Plant|P09_068.ees|no.hlp|no.bmp Problem 9-70: Combined Gas-Steam Power Plant|P09_070.ees|no.hlp|no.bmp Problem 9-92: Effect of Condenser Pressure on Rankine Cycle|P09_092.ees|no.hlp| no.bmp Problem 9-93: Effect of Boiler Pressure on Rankine Cycle|P09_093.ees|no.hlp| no.bmp Problem 9-94: Effect of Superheating on Rankine Cycle|P09_094.ees|no.hlp|no.bmp Problem 9-95: Effect of Reheat Pressure on Reheat Rankine Cycle|P09_095.ees| no.hlp|no.bmp Problem 9-96: Effect of Number of Reheat Stages on Rankine Cycle|P09_096.ees| no.hlp|no.bmp Problem 9-97: Effect of Extraction Pressure for One Open Feedwater Heater| P09_097.ees|no.hlp|no.bmp Problem 9-98: Regeneration using Multiple Open Feedwater Heaters|P09_098.ees| no.hlp|no.bmp >Chapter 10: Refrigeration Cycles Problem 10-15: Vapor-Compression Refrigeration Cycle|P10_015.ees|no.hlp|no.bmp Problem 10-20: Effect of Comp Eff & Volume Flow Rate on Refrig Cycle| P10_020.ees|no.hlp|no.bmp Problem 10-31: Effect of Compressor Efficiency on Heat Pump Cycle|P10_031.ees| no.hlp|no.bmp Problem 10-41: Two-Stage Compression Refrigeration Cycle|P10_041.ees|no.hlp| no.bmp Problem 10-51: Gas Turbine Refrigeration Cycle|P10_051.ees|no.hlp|no.bmp Problem 10-84: Refrigeration with Water Cooled Condenser|P10_084.ees|no.hlp| no.bmp Problem 10-92: Ideal Absorption Refrigeration System|P10_092.ees|no.hlp|no.bmp Problem 10-98: Effect of Evap. Pressure on COP of Refrigerator|P10_098.ees| no.hlp|no.bmp Problem 10-99: Effect of Cond. Pressure on COP of Refrigerator|P10_099.ees| no.hlp|no.bmp >Chapter 11: Thermodynamic Property Relations Problem 11-17: Maxwell Relation|P11_017.ees|no.hlp|no.bmp Problem 11-26: Enthalpy of Vaporization|P11_026.ees|no.hlp|no.bmp Problem 11-49E: Joule-Thompson Coefficient|P11_049E.ees|no.hlp|no.bmp Problem 11-62: Closed System Solution by Generalized Charts|P11_062.ees| no.hlp|no.bmp Problem 11-66: Adiabatic Nozzle Solution by Generalized Charts|P11_066.ees| no.hlp|no.bmp Problem 11-77: Turbine Work by Generalized Charts|P11_077.ees|no.hlp|no.bmp >Chapter 12: Gas Mixtures Problem 12-40: Unsteady-Flow with Mixing|P12_040.ees|no.hlp|no.bmp Problem 12-52: Adiabatic Mixing of Two Gases|P12_052.ees|no.hlp|no.bmp Problem 12-55E: Mixture Flow Through Non-Isentropic Nozzle|P12_055e.ees|no.hlp| no.bmp Problem 12-58: Mixing Gases in Two Tanks|P12_058.ees|no.hlp|no.bmp Problem 12-62: Compare Ideal Gas and Amagat's Law In Compressor Analysis| P12_062.ees|no.hlp|no.bmp Problem 12-69: Power Produced by Mixing Two Streams|P12_069.ees|no.hlp|no.bmp Problem 12-79: Compare Ideal Gas and Kay's Rule In Heat Transfer Process| P12_079.ees|no.hlp|no.bmp Problem 12-82: Determine Mass or Mole Fractions of Gas Mixture|P12_082.ees| no.hlp|no.bmp Problem 12-83: Determine Properties of a Gas Mixture|P12_083.ees|no.hlp|no.bmp Problem 12-84: Determine Entropy Change of a Gas Mixture|P12_084.ees|no.hlp| no.bmp >Chapter 13: Gas-Vapor Mixtures and Air Conditioning Problem 13-32: Properties of Moist Air, P>Patm(SI Units)|P13_032.ees|no.hlp| no.bmp Problem 13-39: Prop of Moist Air & Psychrometric Chart(SI Units)|P13_039.ees| no.hlp|no.bmp Problem 13-41: Properties of Moist Air, Z=2000m (SI Units)|P13_041.ees|no.hlp| no.bmp Problem 13-43E: Prop of Moist Air & Psychrometric Chart (Eng. Units)| P13_043E.ees|no.hlp|no.bmp Problem 13-45: Properties of Moist Air, Z=3000m (SI Units)|P13_045.ees|no.hlp| no.bmp Problem 13-79: Cooling Coil Dehumidifier(SI Units)|P13_079.ees|no.hlp|no.bmp Problem 13-82E: Cooling Coil Dehumidifier (English Units)|P13_082E.ees|no.hlp| no.bmp Problem 13-99E: Mixing Two Atmospheric Air Streams (Eng. Units)|P13_099E.ees| no.hlp|no.bmp Problem 13-101: Mixing Two Atmospheric Air Streams (SI Units)|P13_101.ees| no.hlp|no.bmp Problem 13-120: Atmospheric Air in Constant Volume Process|P13_120.ees|no.hlp| no.bmp Problem 13-127: Heating Followed by Evaporative Cooling Process|P13_127.ees| no.hlp|no.bmp Problem 13-130: Effect of Press on Mixing Atmospheric Air Streams (SI Units)| P13_130.ees|no.hlp|no.bmp Problem 13-132: Cooling tower|P13_132.ees|no.hlp|no.bmp >Chapter 14: Chemical Reactions Problem 14-27: Effect of Fuel Type, Prod T&P on Condensation|P14_027.ees| no.hlp|no.bmp Problem 14-40: Enthalpy of Combustion|P14_040.ees|no.hlp|no.bmp Problem 14-56: Steady-flow combustion with excess air|P14_056.ees|no.hlp| no.bmp Problem 14-59: Constant-volume combustion|P14_059.ees|no.hlp|no.bmp Problem 14-66: Effect of Theoretical Air on Adiabatic Flame Temp|P14_066.ees| no.hlp|no.bmp Problem 14-71: Adiabatic Combustion with Atmospheric Air|P14_071.ees|no.hlp| no.bmp Problem 14-82: Steady-flow Combustion of Liquid Fuel|P14_082.ees|no.hlp|no.bmp Problem 14-95: Constant-Vol vs. Constant-Pres Combustion |P14_095.ees|no.hlp| no.bmp Problem 14-99: Effect of Amount of Air on Adiabatic Flame Temp |P14_099.ees| no.hlp|no.bmp Problem 14-100: Effect of Excess Air & Prod. Temp. on Heat Released|P14_100.ees| no.hlp|no.bmp Problem 14-101: Adiabatic Flame Temperature|P14_101.ees|no.hlp|no.bmp Problem 14-102: Adiabatic Flame Temperature of Several Fuels|P14_102.ees|no.hlp| no.bmp Problem 14-103: Min Excess Air for Given Adiabatic Flame Temp |P14_103.ees| no.hlp|no.bmp Problem 14-104: Min Excess Air for Other Adiabatic Flame Temp|P14_104.ees| no.hlp|no.bmp Problem 14-105: Adiabatic Flame Temperature|P14_105.ees|no.hlp|no.bmp Problem 14-107: Rate of Heat Transfer Based on Fuel Flow Rate |P14_107.ees| no.hlp|no.bmp Problem 14-108: Rate of Heat Transfer Based on Fuel Flow Rate |P014_108.ees| no.hlp|no.bmp Problem 14-109: Adiabatic Constant-Volume Combustion|P14_109.ees|no.hlp|no.bmp Problem 14-125: Adiabatic Flame Temperature|P14_125.ees|no.hlp|no.bmp >Chapter 15: Chemical and Phase Equilibrium Problem 15-20: Single Chemical Equilibrium Reaction|P15_020.ees|no.hlp|no.bmp Problem 15-31: NO in Comb. Prod. for liq. C3H8|P15_031.ees|no.hlp|no.bmp Problem 15-40E: Min Gibbs Func Sol for Equilibrium|P15_040E.ees|no.hlp|no.bmp Problem 15-42: Heat Transfer to Dissociate Water|P15_042.ees|no.hlp|no.bmp Problem 15-76: Chemical Equilibrium and Adiabatic Flame Temp|P15_076.ees| no.hlp|no.bmp Problem 15-80: Effect of Pressure on Equilibrium Composition|P15_080.ees| no.hlp|no.bmp Problem 15-82: Estimate Enthalpy of Reaction from Equilibrium Data| P15_082.ees|no.hlp|no.bmp >Chapter 16: Thermodynamics of High-Speed Flow Problem 16-25E: Mach Number of Steam Flow|P16_025E.ees|no.hlp|no.bmp Problem 16-42: Isentropic Flow Mach Number Relations|P16_042.ees|no.hlp|no.bmp Problem 16-66: Converging Nozzle|P16_066.ees|no.hlp|no.bmp Problem 16-79E: Air Flow with Normal Shock|P16_079E.ees|no.hlp|no.bmp Problem 16-90: Non-Isentropic Turbine Nozzle Flow|P16_090.ees|no.hlp|no.bmp Problem 16-120: Converging-Diverging Nozzle|P16_120.ees|no.hlp|no.bmp Problem 16-121: 1D Compressible-Flow Functions|P16_121.ees|no.hlp|no.bmp Problem 16-122: 1D Normal Shock Functions|P16_122.ees|no.hlp|no.bmp Problem 16-123: 1D Compressible-Flow & Normal Shock Functions|P16_123.ees| no.hlp|no.bmp Problem 16-124: 1D Nozzle Flow with Normal Shock|P16_124.ees|no.hlp|no.bmp