Measurement and prediction of CO2 solubility in sodium phosphate monobasic solutions for food treatment with high pressure carbon dioxide

Two experimental systems were designed and tested to measure the CO2 solubility in sodium dibasic phosphate solutions (0.276, 2.76 and 5.52 g/100 g water) at different pressures (7.5 and 15.0 MPa) and temperatures (35, 40 and 50°C). The results were compared with those for pure water. Three thermodynamic solubility models were tested using the Aspen Simulation PlusTM software: 1) Peng-Robinson equation of state (EOS), where the a and b parameters were evaluated with the Wong and Sandler mixing rules (PRWS) and the activity coefficients were defined using the functional groups with the modified UNIFAC method 2) Electrolytic non-random two liquids (ELECNRTL) with the Redlich-Kwong equation of state for aqueous and mixed solvent applications 3) The completely predictive Soave-Redlich-Kwong (PSRK) equation of state. CO2 solubility was a strong function of sodium dibasic phosphate concentrations. The predictions of the PRWS EOS agreed well with the experimental data in the pressure and temperature ranges tested. A higher difference between the experimental and predicted results was observed for conditions close to the CO2 critical point and for low sodium dibasic phosphate concentrations. Thermodynamic models 2 and 3 predictions had a much higher deviations from experimental data.