Example 5 - Compression

            1-Octene (C8H16, 20,000 Ib/hr) at 10 psia and 500 F is compressed to 4,000 psia. Estimate the change
     in enthalpy for the compression assuming adibatic and reversible conditions (constant entropy).

            Substitution of mass flow and enthalpies from the thermodynamic diagram into the equation below provides:

            Enthalpy Change = mass flow (H 2 - H 1) = (20.000 lb/hr)(310 - 210) BTU/lb

                           = 2.0 million BTU/hr

            This change in enthalpy represents energy that is required to accomplish the compression under adibatic
     and reversible conditions. Under operating conditions, the actual energy that is required for the compression will
     be somewhat more depending on the efficiency.

     Example 6 - Expansion

            1-Octene (C8H16, 30,000 Ib/hr) at 8,000 psia and 900 F is expanded to 10 psia. Estimate the change in
     enthalpy for the expansion assuming adibatic and reversible conditions (constant entropy).

            Substitution of mass flow and enthalpies from the thermodynamic diagram into the equation below provides:

            Enthalpy Change = mass flow (H 2 - H 1) = (30.000 lb/hr)(280 - 420) BTU/lb

                           = - 4.2 million BTU/hr

            This change in enthalpy represents energy that is available from the expansion under adibatic and reversible
     conditions. Under operating conditions, the actual energy that is available for the expansion will be somewhat less
     depending on the efficiency.


































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