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Chapter 7. Application of Thermodynamics to Flow Processes
고려대 화공 생명공학과
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7.1 Duct Flow of Compressible Fluids (1)
Adiabatic, steady state, one-dimensional flow of compressible fluid No shaft work and no change in potential energy Energy Balance Equation – 1st law Steady state Changes in enthalpy directly go to changes in velocity
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7.1 Duct Flow of Compressible Fluids (2)
Mass balance equation – Continuity Equation
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7.1 Duct Flow of Compressible Fluids (3)
Thermodynamic Relations Replace V in terms of S and P (eqn 3-2) (eqn 6-17)
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7.1 Duct Flow of Compressible Fluids (4)
Relation from physics Velocity of sound in a medium is related with pressure derivative w.r.t volume with const.S
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7.1 Duct Flow of Compressible Fluids (5)
Variables : dH, du, dV, dA, dS, dP Equations : four dS, dA : independent Can develop equations of other derivatives with dS and dA
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7.1 Duct Flow of Compressible Fluids (6)
M : Mach number = u/c
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7.1 Duct Flow of Compressible Fluids (7)
According to second law, (dS/dx) >= 0
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Pipe Flow Pipe Flow : constant cross sectional area (dA/dx=0)
Subsonic flow : Implies : Pressure drops in the direction of flow Velocity increases in the direction of flow
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Pipe flow The velocity does not increase indefinitely.
If the velocity exceeds the sonic value, Supersonic flow Shock wave and turbulence Unstable flow
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Nozzles Flow within a pipe or a duct (variable cross-sectional area)
Assume isentropic flow reversible flow
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Nozzles Converging Diverging Subsonic (M<1) Supersonic(M>1)
dA/dx - + dP/dx du/dx
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Converging Nozzle Pressure Velocity
Maximum obtainable velocity = speed of sound Increase in velocity requires increase in cross-sectional area in diverging section Converging nozzle can be used to deliver constant flow into a region of variable pressure P1 P2 As p2 decreases, velocity increases and maximum value at sonic velocity. Further decrease in p2 has no effect on velocity.
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Converging / Diverging Nozzle
Speed of sound is attained at the throat of converging/diverging nozzle only when the pressure at the throat is low enough that critical value of P2/P1 is reached. See figure 7.1
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Value of critial pressure ratio
dS=0 Adiabatic ,
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Value of critical pressure ratio
Critical value u=c
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Throttling Process Throttling Process : Orifice , Partly closed valve, porous plug, … Primary result : pressure drop For ideal gases, H=H(T) and no change in T For real gases, slight change in T
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Example 7.5 Joule-Thompson Coefficient
Temperature change resulting from a throttling a real gas. Joule-Thompson coefficient
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Joule/Thomson Coefficient and other properties
J-T coeff. comes from the pressure dependence of H
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Joule/Thomson Coeff. from PVT relation
With Cp and PVT relation , any property can be predicted.
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7.2 Turbines (Expanders) Expansion of gas Production of Work
Internal Energy Kinetic Energy Work 1 Ws 2
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Turbines (Expanders) Heat effects are negligible, Inlet and outlet velocity changes are small Normally T1, P1 and P2 are given Maximum work : isentropic process (adiabatic process)
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Turbines (Expanders) Turbine Efficiency
Turbine efficiency of properly designed turbine : 0.7 to 0.8
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Turbines (Expanders) H Adiabatic expansion process in a turbine or expander S
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7.4 Compression Processes
Compression Devices : Rotating blades, Reciprocating pistions 2 Ws 1
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Compressors Compressor efficiency : 0.7 to 0.8
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Compressors H Adiabatic compression process S
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