Examples 1 1.At  150°F the vapor pressure of methane is 363.20 psia and the saturated specific internal energies are u f = 100.36 Btu/lbm and u g = 210.94.

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Examples 1 1.At  150°F the vapor pressure of methane is psia and the saturated specific internal energies are u f = Btu/lbm and u g = Btu/lbm. Determine the quality of methane at T =  150°F and u = 200 Btu/lbm. 2.Determine the change in the specific internal energy and specific enthalpy of glycerin as its temperature changes from 490 R, 14.7 psia to 520 R, 1000 psia. The density of the glycerin can be assumed to be constant at 79.3 lbm/ft 3. 3.Carbon dioxide gas undergoes a process where its state changes from 20 kPa, 350 K to 1000 kPa, 400K. Calculate the change in the specific enthalpy between these two states. Assume that the ideal gas law is valid, but the heat capacities vary with temperature according to Table C.14b.

2 1.At  150°F the vapor pressure of methane is psia and the saturated specific internal energies are u f = Btu/lbm and u g = Btu/lbm. Determine the quality of methane at T =  150°F and u = 200 Btu/lbm.

3 2.Determine the change in the specific internal energy and specific enthalpy of glycerin as its temperature changes from 490 R, 14.7 psia to 520 R, 1000 psia. The density of the glycerin can be assumed to be constant at 79.3 lbm/ft 3. Assumption: The glycerin is incompressible. Then...

4 3.Carbon dioxide gas undergoes a process where its state changes from 20 kPa, 350 K to 1000 kPa, 400K. Calculate the change in the specific enthalpy between these two states. Assume that the ideal gas law is valid, but the heat capacities vary with temperature according to Table C.14b. From Table C.14b for carbon dioxide,