IMPACT OF BLENDING OF FRYING OILS ON VISCOSITY AND HEAT TRANSFER COEFFICIENT AT ELEVATED TEMPERATURES

SUKUMAR DEBNATH

Present address: Department of Lipid Science and Traditional foods, Central Food Technological Research Institute, Mysore 570 020, India

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SRIRAM KUMAR VIDYARTHI,

SRIRAM KUMAR VIDYARTHI

Department of Biological and Agricultural Engineering
University of California
Davis, CA 95616

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R. PAUL SINGH,

Corresponding Author

R. PAUL SINGH

Corresponding author. TEL: +001-530-752-0811; FAX: +001-530-752-2640; EMAIL: [email protected]Search for more papers by this author

SUKUMAR DEBNATH,

SUKUMAR DEBNATH

Present address: Department of Lipid Science and Traditional foods, Central Food Technological Research Institute, Mysore 570 020, India

Search for more papers by this author

SRIRAM KUMAR VIDYARTHI,

SRIRAM KUMAR VIDYARTHI

Department of Biological and Agricultural Engineering
University of California
Davis, CA 95616

Search for more papers by this author

R. PAUL SINGH,

Corresponding Author

R. PAUL SINGH

Corresponding author. TEL: +001-530-752-0811; FAX: +001-530-752-2640; EMAIL: [email protected]Search for more papers by this author

First published: 25 January 2010

https://doi.org/10.1111/j.1745-4530.2008.00265.x

Citations: 19

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Abstract

ABSTRACT

In the present work, the effect of binary blending of five frying oils on kinematic viscosity (ν) and convective heat transfer coefficient (h) was studied at elevated temperatures (170, 180 and 190C). A Cannon Ubbelhode calibrated capillary viscometer (Cannon Instrument Company, State College, PA) in a custom-designed and fabricated convective air bath heater and a highly conductive cylindrical metal transducer were used for generatingνand h data, respectively. The value ofνdecreased from 3.617 × 10^-⁶ to 2.062 × 10^-⁶ m² s^-¹, and h increased from 221.0 to 301.2 Wm^-² C^-¹ by increasing the aforementioned oil temperatures. A good correlation betweenν (R² > 0.996) or h (R² > 0.987) of these frying oils and their selected binary blends with the previously mentioned temperature range was observed. Significant difference (P < 0.05) was found between different levels of parameters when treatments were compared using Tukey's test.

PRACTICAL APPLICATIONS

In food engineering applications, the physical properties of foods play an important role in the analysis of process parameters and in the design and fabrication of processing equipment. Determination of kinematic viscosity and convective heat transfer coefficients of frying oils and their selected blends at elevated temperatures are useful from an industrial point of view. In the present work, the effect of blending different edible oils on the kinematic viscosity and convective heat transfer coefficients at elevated temperatures was studied. Because selected blended oils provided lower levels of viscosities and higher levels of heat transfer coefficients, these results may be an attractive proposition in improving the quality of fried products and cost-effectiveness in the fried food industry.

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Volume33, Issue1

February 2010

Pages 144-161

IMPACT OF BLENDING OF FRYING OILS ON VISCOSITY AND HEAT TRANSFER COEFFICIENT AT ELEVATED TEMPERATURES

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IMPACT OF BLENDING OF FRYING OILS ON VISCOSITY AND HEAT TRANSFER COEFFICIENT AT ELEVATED TEMPERATURES

Abstract

ABSTRACT

PRACTICAL APPLICATIONS

REFERENCES

Citing Literature

References

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