Adipic acid is an important substan

Adipic acid is an important substance in chemical industries. It
is ranked in the top ten by the term of volume used [1]. It is used as
a raw material in the productions of polyamide [2,3], polyurethane,
polyester resins, plasticizers, lubricants [4], carpet fibers, specialty
foams, reinforcements, and several items of clothing [5]. Oxidation
of cyclohexanone-cyclohexanol mixture with nitric acid is the
conventional route for preparing adipic acid [1]. In the industry,
it is mainly produced by oxidation of cyclohexane with air and
nitric acid [6]. After oxidization process, crude adipic acid has to
be purified to obtain pure adipic acid [7].

Crystallization is one of the most purification methods for recovering
the target components from the solution. To recover the target
component by crystallization, its solubility data is required [8,9].
For separation by crystallization, a suitable solvent system should
yield an adequately high solubility at the starting conditions in
order to entirely dissolve the product without a dramatic increasein the volume of solution but also allow a significant decrease in
solubility at the end of the process to reduce the product losses and
increase the process yield [10].

The solubility of substances is one of the most considerable
parameters in the development of solution theory [11–18]. However,
the solubility data of some substances that have been reported
are limited [19–21]. This lack of data results from the problems in
the sampling of solutions at high temperatures and pressures [22].

To obtain the solubility data of compounds at high temperatures,
it requires a high experimental effort which is very sophisticated
and time consuming [23,24]. Some thermodynamic models have
been developed to predict the solubility of certain substances to
reduce this effort to a minimum. The modification of the Apelblat
equation model is widely used to correlate the solubility data of
some substances. It provides the acceptable data of solubility at
different temperatures [25–28]. Moreover, it can also be applied to
calculate the molar enthalpy and the molar entropy of dissolution
of compounds [28].

As far as we know, only a few data of the solubility of adipic acid
in several organic solvents and aqueous solutions [7,29–31] was
measured at low temperatures. However, this solubility data is far
from the industrial conditions. Therefore, in this work, the solubility
data of adipic acid was measured in various solvents (water, acetic
acid, acetic acid–water mixture (ratio of 1:1, v/v), cyclohexanol and cyclohexanone) in the temperature ranging from 303.0 to 403.0 K.
The modified Apelblat equation model was applied to correlate the
solubility data of adipic acid. The model was verified by comparing
the solubility data obtained from the model with those gained from
the experimental results.