Prediction of oil expression by uniaxial compression using time-varying oilseed properties

Praveen C. Bargale; Dvora-Laio Wulfsohn; Joseph Irudayaraj; Ron J. Ford; Frank W. Sosulski

Prediction of oil expression by uniaxial compression using time-varying oilseed properties

Praveen C. Bargale, Dvora-Laio Wulfsohn, Joseph Irudayaraj, Ron J. Ford, Frank W. Sosulski

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

27 Citationer (Scopus)

Abstract

Udgivelsesdato: October

Originalsprog	Engelsk
Tidsskrift	Biosystems Engineering
Vol/bind	77
Udgave nummer	2
Sider (fra-til)	171-181
ISSN	1537-5110
Status	Udgivet - 2000
Udgivet eksternt	Ja

Citationsformater

@article{e00a6d20209111de9f0a000ea68e967b,

title = "Prediction of oil expression by uniaxial compression using time-varying oilseed properties",

abstract = "A mathematical simulation of uniaxial compression of oilseeds for oil extraction was developed based upon combining Terzaghi's theory of consolidation for saturated soils with Darcy's law for unsaturated flow, while incorporating the time-varying nature of the coefficients of permeability and consolidation. The model was validated for extruded soy and for sunflower seeds. Material parameters were determined experimentally and predictions of oil recovery rates made for several levels of temperature, pressure and initial sample depth. Results indicated that while the model predicted the values of oil recovery for extruded soybean very well, the predictions were not satisfactory for sunflower seed samples. The higher error was attributed to material non-homogeneity and the presence of hulls in the sunflower seeds, which increased errors in measurement of the medium permeability function. The lack of experimental permeability data in the very early stages of pressing (t<60 s) was an important source of error in general. The incorporation of varying material properties in the simulations resulted in substantially more accurate predictions of quantities and trends in oil recovery with time, when compared to using constant (averaged) values of material parameters. ",

author = "Bargale, {Praveen C.} and Dvora-Laio Wulfsohn and Joseph Irudayaraj and Ford, {Ron J.} and Sosulski, {Frank W.}",

year = "2000",

language = "English",

volume = "77",

pages = "171--181",

journal = "Biosystems Engineering",

issn = "1537-5110",

publisher = "Academic Press",

number = "2",

}

TY - JOUR

T1 - Prediction of oil expression by uniaxial compression using time-varying oilseed properties

AU - Bargale, Praveen C.

AU - Wulfsohn, Dvora-Laio

AU - Irudayaraj, Joseph

AU - Ford, Ron J.

AU - Sosulski, Frank W.

PY - 2000

Y1 - 2000

N2 - A mathematical simulation of uniaxial compression of oilseeds for oil extraction was developed based upon combining Terzaghi's theory of consolidation for saturated soils with Darcy's law for unsaturated flow, while incorporating the time-varying nature of the coefficients of permeability and consolidation. The model was validated for extruded soy and for sunflower seeds. Material parameters were determined experimentally and predictions of oil recovery rates made for several levels of temperature, pressure and initial sample depth. Results indicated that while the model predicted the values of oil recovery for extruded soybean very well, the predictions were not satisfactory for sunflower seed samples. The higher error was attributed to material non-homogeneity and the presence of hulls in the sunflower seeds, which increased errors in measurement of the medium permeability function. The lack of experimental permeability data in the very early stages of pressing (t<60 s) was an important source of error in general. The incorporation of varying material properties in the simulations resulted in substantially more accurate predictions of quantities and trends in oil recovery with time, when compared to using constant (averaged) values of material parameters.

AB - A mathematical simulation of uniaxial compression of oilseeds for oil extraction was developed based upon combining Terzaghi's theory of consolidation for saturated soils with Darcy's law for unsaturated flow, while incorporating the time-varying nature of the coefficients of permeability and consolidation. The model was validated for extruded soy and for sunflower seeds. Material parameters were determined experimentally and predictions of oil recovery rates made for several levels of temperature, pressure and initial sample depth. Results indicated that while the model predicted the values of oil recovery for extruded soybean very well, the predictions were not satisfactory for sunflower seed samples. The higher error was attributed to material non-homogeneity and the presence of hulls in the sunflower seeds, which increased errors in measurement of the medium permeability function. The lack of experimental permeability data in the very early stages of pressing (t<60 s) was an important source of error in general. The incorporation of varying material properties in the simulations resulted in substantially more accurate predictions of quantities and trends in oil recovery with time, when compared to using constant (averaged) values of material parameters.

M3 - Journal article

SN - 1537-5110

VL - 77

SP - 171

EP - 181

JO - Biosystems Engineering

JF - Biosystems Engineering

IS - 2

ER -