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A B C D E F G H I J K L M N O P Q R S T U V W X Y Z
G-type shells in shell-and-tube heat exchangers: Gaddis, E S, Galerkin method, for heat conduction finite-element calculations, Galileo number, Gas-liquid flows: Gas-liquid-solid interfaces, fouling at, Gas-solid interfaces, fouling at, Gas tungsten arc welding, Gaseous fuels, properties of, Gases:
as constituent of multiphase flows, density of pure,
Density of Pure Fluids corresponding states principle for, virial equation for,
diffusion coefficients in, emissivity of, emissivity of combustion product mixtures of isothermal, radiative heat transfer in, nonisothermal, radiative heat transfer in, radiation properties, superheated, thermodynamic properties of, tables, transport properties tables: for low pressure, viscosity of,
Gaskets: Gauss-Seidel method, for solution of implicit equations, Geometric optics models for radiative heat transfer from surfaces, geothermal brines, fouling of heat exchangers by, Germany, Federal Republic of, mechanical design of heat exchangers in: Gersten, K, Girth flanges, in shell-and-tube heat exchangers, Glass production, furnaces and kilns for, Glycerol (glycerine): Gn (heat generation number), Gnielinski, V Gnielinski correlation, for heat transfer in tube banks, Gomez-Thodas method, for vapour pressure, Goodness factor, as a basis for comparison of plate fin heat exchanger surfaces, Goody narrow band model for gas radiation properties, Gorenflo correlation, for nucleate boiling, Gowenlock, R, Graetz number: Granular products, moving, heat transfer to, Graphite, density of, Grashof number Gravitational acceleration, effect in pool boiling, Gravity conveyor: Gregorig effect in enhancement of condensation, Grid baffles: Grid selection, for finite difference method, Griffin, J M, Groeneveld correlation for postdryout heat transfer, Groeneveld and Delorme correlation for postdryout heat transfer, Gross plastic deformation Group contribution parameters tables, Guerrieri and Talty correlations for forced convective heat transfer in two-phase flow, Gungor and Winterton correlation, for forced convective boiling, Gylys, J,

Index

HEDH
A B C D E F G
G-type shells in shell-and-tube heat exchangers: Gaddis, E S, Galerkin method, for heat conduction finite-element calculations, Galileo number, Gas-liquid flows: Gas-liquid-solid interfaces, fouling at, Gas-solid interfaces, fouling at, Gas tungsten arc welding, Gaseous fuels, properties of, Gases:
as constituent of multiphase flows, density of pure,
Density of Pure Fluids corresponding states principle for, virial equation for,
diffusion coefficients in, emissivity of, emissivity of combustion product mixtures of isothermal, radiative heat transfer in, nonisothermal, radiative heat transfer in, radiation properties, superheated, thermodynamic properties of, tables, transport properties tables: for low pressure, viscosity of,
Gaskets: Gauss-Seidel method, for solution of implicit equations, Geometric optics models for radiative heat transfer from surfaces, geothermal brines, fouling of heat exchangers by, Germany, Federal Republic of, mechanical design of heat exchangers in: Gersten, K, Girth flanges, in shell-and-tube heat exchangers, Glass production, furnaces and kilns for, Glycerol (glycerine): Gn (heat generation number), Gnielinski, V Gnielinski correlation, for heat transfer in tube banks, Gomez-Thodas method, for vapour pressure, Goodness factor, as a basis for comparison of plate fin heat exchanger surfaces, Goody narrow band model for gas radiation properties, Gorenflo correlation, for nucleate boiling, Gowenlock, R, Graetz number: Granular products, moving, heat transfer to, Graphite, density of, Grashof number Gravitational acceleration, effect in pool boiling, Gravity conveyor: Gregorig effect in enhancement of condensation, Grid baffles: Grid selection, for finite difference method, Griffin, J M, Groeneveld correlation for postdryout heat transfer, Groeneveld and Delorme correlation for postdryout heat transfer, Gross plastic deformation Group contribution parameters tables, Guerrieri and Talty correlations for forced convective heat transfer in two-phase flow, Gungor and Winterton correlation, for forced convective boiling, Gylys, J,
H I J K L M N O P Q R S T U V W X Y Z
G Gases: density of pure,
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Density of Pure Fluids

DOI 10.1615/hedhme.a.000499

5.1 PROPERTIES OF PURE FLUIDS
5.1.2 Density of pure fluids

A. Fenghour

A. Introduction

In this section are presented practical methods for the calculation of the density of pure gases and liquids as a function of temperature and pressure. The selected methods are quite accurate and relatively easy to use. They can easily be implemented using calculators or spreadsheet programs. The more elaborate thermodynamic models such as equations of state, which in principle allow the calculation of all the thermodynamic properties of single substances or mixtures, are beyond the scope of this article for their implementation would require the development of computer programs with lengthy testing periods.

B. Pure gases

(a) Corresponding states principle

Pitzer et al. (1955) have shown that the compression factor of a given substance at reduced temperature and reduced pressure can be expanded as a power series in the acentric factor ω. In practice, they restricted the expansion of the compression factor Z to the following linear form:

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