This paper presents a new model to
predict the density of biodiesel
+ petrodiesel mixtures at high pressure and high temperature (HPHT)
based on the Murnaghan equation of state, as a function of temperature,
pressure, volumetric composition, and petrodiesel and biodiesel densities.
This model was validated by using experimental data from the literature,
along with a new experimental data set for biodiesel (grape seed,
corn, and linseed) + petrodiesel, at high pressure (0.10–100.00
MPa) and high temperature (293.15–413.15 K) in a composition
range of 0, 20, 40, 60, 80, and 100%vol. These experimental data were
correlated by using the Tammann–Tait equation. From these data,
the following derivative properties were determined: isothermal compressibility
(κT), isobaric thermal expansibility (αP), internal pressure (p
int), and
the difference between pressure and volume heat capacities (c
p – c
v).
Deviations obtained from the model proposed in this work (%AARD) were
less than 0.50% for biodiesel + petrodiesel density data.
In
this work, high-pressure and high-temperature density data for
1-methyl-3-octylimidazolium trifluoromethanesulfonate [C8C1Im][OTf], 1-butyl-1-methylpyrrolidinium dicyanamide
[C4C1Pyr][DCA], and 1-ethyl-3-methylimidazolium
acetate [C2C1Im][C1COO] ionic liquids
(ILs) were determined at P = (0.2 to 100.0) MPa and T = (298.15 to 398.15) K with steps of 25 K, by using a
tube vibration method. It was observed that density increases in the
following sequence: [C4C1Pyr][DCA] < [C2C1Im][C1COO] < [C8C1Im][OTf], according to their intermolecular interactions.
These experimental density data were correlated by using the Tammann–Tait
equation, with the average absolute relative deviation less than 0.0090%
for [C8C1Im][OTf] and [C2C1Im][C1COO] and less than 0.0220% for [C4C1Pyr][DCA]. From these data, the following derivative thermodynamic
properties were calculated: isothermal compressibility (κT), isobaric expansivity (αp), thermal pressure
coefficient (γv), and internal pressure (P
i). Furthermore, the densities of the studied
ILs were predicted using six different group contribution models.
The best agreement between experimental and calculated
data was obtained when the model proposed by Paduszynski and Domanska
was applied.
Although
physicochemical properties are essential to developing
new industrial ionic liquid (IL) applications, experimental data must
be obtained, especially under high-pressure operational conditions.
Therefore, density data were measured for three commercial ILs: methyltrioctylammonium
bis(trifluoromethylsulfonyl) imide [(C8)3C1N][NTf2]; 1-methyl-1-propylpiperidinium bis(trifluoromethylsulfonyl)
imide [C3C1Pip][NTf2]; and 1-butylpyridinium
bis(trifluoromethylsulfonyl) imide [C5Py][NTf2] at high-pressure and wide temperature ranges [P = (0.2 to 100.0) MPa and T = (298.15 to 398.15)
K] by the intermediate of a tube vibrating method. The operational
range was chosen because it could cover many industrial applications.
The structural interaction between the IL cation and the anion is
significant in volumetric behavior. It was observed that the density
increases in the following order: [C5Py][NTf2] > [C3C1Pip][NTf2] > [(C8)3C1N][NTf2]. The Tammann–Tait
equation was used to evaluate the influence of pressure and temperature
on density, showing an average absolute relative deviation (%AARD)
of less than 0.032% compared to experimental data. From these data,
the isothermal compressibility (κT), isobaric expansivity
(αp), thermal pressure coefficient (γv), and internal pressure (P
i) were calculated.
Additionally, IL density was estimated using five different group
contribution methods reported in the literature, with better results
obtained for Gardas and Coutinho and Paduszyński and Domańska.
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