Abstract
The thermal pressure coefficients in liquid n-Pentadecane (C15), n-Heptadecane (C17), n-octadecane (C18) and n-nonadecane (C19) was measured using pVT data. The measurements were carried out at pressures up to 150 MPa in the temperature range from 293 to 383 K. The experimental results have been used to evaluate various thermophysical properties such as thermal pressure coefficients up to 150 MPa with the use of density and temperature data at various pressures. New parameters of the linear isotherm regularity, the so-called LIR equation of state, are used to calculate of thermal pressure coefficients of n-Pentadecane (C15), n-Heptadecane (C17), n-octadecane (C18) and n-nonadecane (C19) dense fluids. In this paper, temperature dependency of linear isotherm regularity parameters in the form of a first order has been developed to second and third order and their temperature derivatives of new parameters are used to calculate thermal pressure coefficients. The resulting model predicts accurately thermal pressure coefficients from the lower density limit at the Boyle density at the from triple temperature up to about double the Boyle temperature. The upper density limit appears to be reached at 1.4 times the Boyle density. These problems have led us to try to establish a function for the accurate calculation of the thermal pressure coefficients based on the linear isotherm regularity theory for different fluids.
Highlights
A study of the thermophysical properties as a function of pressure and temperature in a homologous series of chemical compounds is of great interest for industrial applications for example, in the petroleum industry, and for fundamental aspects for understanding the influence of the chain length of the components on the liquid structure and developing models for an accurate representation of the liquid state
One of the most difficult problems within the context of the thermodynamics lies in the shortage for experimental data for some basic quantities such as thermal pressure coefficients (TPC) which are tabulated for extremely narrow temperature ranges, normally around the ambient temperature for several types of liquids
We derive an expression for as the thermal pressure coefficient of C15H32, C17H36, C18H38 and C19H40 dense fluids using the linear isotherm regularity[1,3,18]. It has been shown in this work that, the thermal pressure coefficient can be obtained
Summary
A study of the thermophysical properties as a function of pressure and temperature in a homologous series of chemical compounds is of great interest for industrial applications for example, in the petroleum industry, and for fundamental aspects for understanding the influence of the chain length of the components on the liquid structure and developing models for an accurate representation of the liquid state With this aim in mind, a research program of thermal pressure coefficients (TPC) measurements under pressure on most paraffins between decane and triacontane was initiated as a part of a project on crude oil characterization [1,2,3]. A general regularity was reported for pure dense fluids, namely testing literature results for pVT for pure dense fluids, according to which Z 1 V 2 is linear with respect to 2 for each isotherm, where Z pv RT is the compression factor This equation of state works very well for all types of dense fluids, for densities greater than the Boyle density but for temperatures below twice the Boyle temperature.
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