MRI temperature mapping and determination of liquid-particulate heat transfer coefficient in an ohmically heated food system

X. Ye; R. Ruan; P. Chen; C. Doona; I. A. Taub

doi:10.1111/j.1365-2621.2003.tb09648.x

MRI temperature mapping and determination of liquid-particulate heat transfer coefficient in an ohmically heated food system

X. Ye, R. Ruan, P. Chen, C. Doona, I. A. Taub

Bioproducts and Biosystems Engineering

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15 Scopus citations

Abstract

Real-time temperature maps of ohmically heated liquid-particulate mixtures were acquired using the Proton Resonance Frequency (PRF) shift method incorporated into a fast Magnetic Resonance Imaging (MRI). Noise in the MRI images induced by the electrical heating power was eliminated by a post-processing algorithm of the PRF shift method and correction phase images. The time-dependent interface heat transfer coefficients (h_fp) were determined during the holding period using the MRI temperature maps and numerical solutions to the Fourier's 2nd law. The calculated values of h_fp range from 30 to 105 W/m^2.K, consistent with literature values for natural convection. These results provide crucial data for understanding the ohmic heating process.

Original language	English (US)
Pages (from-to)	1341-1346
Number of pages	6
Journal	Journal of food science
Volume	68
Issue number	4
DOIs	https://doi.org/10.1111/j.1365-2621.2003.tb09648.x
State	Published - May 2003

Keywords

Heat transfer coefficient
MRI
Ohmic heating
PRF shift
Temperature mapping

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abstract = "Real-time temperature maps of ohmically heated liquid-particulate mixtures were acquired using the Proton Resonance Frequency (PRF) shift method incorporated into a fast Magnetic Resonance Imaging (MRI). Noise in the MRI images induced by the electrical heating power was eliminated by a post-processing algorithm of the PRF shift method and correction phase images. The time-dependent interface heat transfer coefficients (hfp) were determined during the holding period using the MRI temperature maps and numerical solutions to the Fourier's 2nd law. The calculated values of hfp range from 30 to 105 W/m2.K, consistent with literature values for natural convection. These results provide crucial data for understanding the ohmic heating process.",

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AU - Chen, P.

AU - Doona, C.

AU - Taub, I. A.

PY - 2003/5

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N2 - Real-time temperature maps of ohmically heated liquid-particulate mixtures were acquired using the Proton Resonance Frequency (PRF) shift method incorporated into a fast Magnetic Resonance Imaging (MRI). Noise in the MRI images induced by the electrical heating power was eliminated by a post-processing algorithm of the PRF shift method and correction phase images. The time-dependent interface heat transfer coefficients (hfp) were determined during the holding period using the MRI temperature maps and numerical solutions to the Fourier's 2nd law. The calculated values of hfp range from 30 to 105 W/m2.K, consistent with literature values for natural convection. These results provide crucial data for understanding the ohmic heating process.

AB - Real-time temperature maps of ohmically heated liquid-particulate mixtures were acquired using the Proton Resonance Frequency (PRF) shift method incorporated into a fast Magnetic Resonance Imaging (MRI). Noise in the MRI images induced by the electrical heating power was eliminated by a post-processing algorithm of the PRF shift method and correction phase images. The time-dependent interface heat transfer coefficients (hfp) were determined during the holding period using the MRI temperature maps and numerical solutions to the Fourier's 2nd law. The calculated values of hfp range from 30 to 105 W/m2.K, consistent with literature values for natural convection. These results provide crucial data for understanding the ohmic heating process.

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KW - MRI

KW - Ohmic heating

KW - PRF shift

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MRI temperature mapping and determination of liquid-particulate heat transfer coefficient in an ohmically heated food system

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