To find the fugacity, of cyclopentane at 110 0 C and 275 bar. Concept Introduction : For the given conditions, we first find Reduced Temperature, T r and Reduced Pressure, P r T r = T T C and P r = P P C Fugacity Coefficient can be found by Virial equation ϕ = exp [ P r T r ( B 0 + ω B 1 ] where the values of B 0 and B 1 are found as below, B 0 = 0.083 − 0.422 T r 1.6 B 1 = 0.139 − 0.172 T r 4.2 V s a t = V c Z c ( 1 − T r ) 2 / 7 f = [ ϕ × P s a t × exp [ V s a t × ( P − P s a t ) R × T ] ] Where, R = Universal Gas constant = 8.314×10-5 m 3 bar/mol.K T = Temperature = 110 0 C = 383.15 K T c = Critical Temperature P c = Critical Pressure ϕ = Fugacity Coefficient = f P P = Pressure = 275 bar f = Fugacity P s a t = Vapor pressure = 5.267 bar ω = Acentric factor

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Chapter 10, Problem 10.19P

Interpretation Introduction

Interpretation:

To find the fugacity, of cyclopentane at 110 ⁰C and 275 bar.

Concept Introduction :

For the given conditions, we first find Reduced Temperature, T_r and Reduced Pressure, P_rTr=TTC

and

Pr=PPC

Fugacity Coefficient can be found by Virial equation

ϕ=exp[PrTr(B0+ωB1]

where the values of B0 and B1 are found as below,

B0=0.083−0.422Tr1.6

B1=0.139−0.172Tr4.2

Vsat=VcZc(1− T r)2/7

f=[ϕ×Psat×exp[Vsat×(P−Psat)R×T]]

Where,

R = Universal Gas constant = 8.314×10-5 m³bar/mol.K

T = Temperature = 110 ⁰C = 383.15 K

T_c = Critical Temperature

P_c = Critical Pressure

ϕ = Fugacity Coefficient = fP

P = Pressure = 275 bar

f = Fugacity

P_s_a_t = Vapor pressure = 5.267 bar

ω = Acentric factor

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