Development of generalized and simplified models for supercritical fluid extraction: Case study of papaya (Carica papaya) seed oil

•Central composite design of supercritical fluid extraction for papaya seed oil.•Parameters; temp., pressure, flow rate, particle size and co-solvent were analyzed.•Highest oil yield was obtained as 36.67%.•Two mathematical models for SFE of papaya seed oil were developed.•Developed models exhibited...

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Bibliographic Details
Published in:Chemical engineering research & design 2019-10, Vol.150, p.341-358
Main Authors: Devi, Vibha, Khanam, Shabina
Format: Article
Language:English
Subjects:
Carbon dioxide
Central composite design
Ethanol
Experimentation
Extraction
Extraction processes
Fatty acids
Flow velocity
Fluid dynamics
Gas chromatography
Genetic algorithms
Mathematical models
Modeling
Oleic acid
Papaya
Parameters
Particle size
Solvents
Supercritical
Supercritical fluids
Supercritical gas extraction
Supercritical processes
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Summary:•Central composite design of supercritical fluid extraction for papaya seed oil.•Parameters; temp., pressure, flow rate, particle size and co-solvent were analyzed.•Highest oil yield was obtained as 36.67%.•Two mathematical models for SFE of papaya seed oil were developed.•Developed models exhibited very well fitness at various parameters range. The present study described the experimentation and modeling of supercritical CO2 extraction (SCE) process for papaya seed oil. Experiments were performed at various ranges of SCE parameters; temperature (303.15–368.15)K, pressure (15–35)MPa, solvent flow rate (5–25)g/min, particle size (0.2–1.4)mm and co-solvent (ethanol) flow rate as (0–20)% of CO2 flow rate. Obtained oil was analyzed through gas chromatography to estimate fatty acid concentrations. Effects of SCE parameters were investigated on the extraction yield and oleic acid concentration of papaya seed oil through central composite design. Further, two mathematical models (PM-1 and PM-2) were developed based on desorption–diffusion–dissolution (PM-1) and broken and intact cell (PM-2) mechanisms. These models were validated with the experimental data of papaya seed oil and further compared with the existing models. PM-1 proposed an equilibrium relation while assuming saturation of solvent and solute at interphase, which was successfully validated with the experimental data in the AARD range from 0.40% to 32.48%. PM-2 reduced the three zones of extraction curves to two and better fitted the experimental data of papaya seed in the AARD range from 0.45% to 35.62%. Model parameters of PM-2 were optimized through genetic algorithm.
ISSN:0263-8762
1744-3563
DOI:10.1016/j.cherd.2019.08.006