The Influence of Work Softening on the Viscoelastic Properties of Butter and Margarine

Shama, F.; Sherman, P.

doi:10.1111/j.1745-4603.1970.tb00723.x

Cited by 49 publications

(36 citation statements)

References 11 publications

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“…The first term on the right hand side of the equation was obtained directly from the experimental creep-compliance data. The middle and last terms were evaluated using a non-linear regression algorithm in SigmaPlot (Jandel Scientific Corporation) (Shama & Sherman, 1970;Steffe, 1996).…”

Section: Creep-compliancementioning

confidence: 99%

Changes in microstructural, thermal, and rheological properties of olive oil/monoglyceride networks during storage

Ojijo

Kesselman

Shuster

et al. 2004

Food Research International

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Section: Creep-compliancementioning

confidence: 99%

Changes in microstructural, thermal, and rheological properties of olive oil/monoglyceride networks during storage

Ojijo

Kesselman

Shuster

et al. 2004

Food Research International

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“…Equations 3 and 4 were used by Sherman in the study of water-in-oil emulsions (30) and food products (31,32). They may be used to investigate aging and temperature effects and to compare different formulations of a preparation or material.…”

Section: J(t) = Jo + S:c L(l -E-t/t)dln 7 + T/r]o (Eq 2)mentioning

confidence: 99%

Investigation of Semisolid Lipophilic Preparations by Small Strain and Continuous Shear Viscometry and Their Application to Texture Profile

Barry

Grace

1971

Journal of Pharmaceutical Sciences

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“…However, processing conditions also influence the rheological characteristics of the final product. For example, agitation (or working) of butter causes a decrease in hardness without changing SFC (17). This is related to the number and structure of fat crystals present and to the interactions between these crystals.…”

mentioning

confidence: 97%

Effect of processing conditions on physical properties of a milk fat model system: Rheology

Herrera

Hartel

2000

J Americ Oil Chem Soc

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The effect of processing conditions on rheological behavior of three blends of 30, 40, and 50% of high-melting fraction [melting point measured as Mettler dropping point (MDP) = 47.5°C] in low-melting fraction (MDP= 16.5°C) of milk fat was studied. The effects of cooling and agitation rates, crystallization temperature, chemical composition of the blends, and time of storage on complex, storage and loss moduli were investigated by dynamic mechanical analysis (DMA). Compression tests were performed on samples using frequency values within the linear viscoelastic range (1 to 10 Hz). Loss modulus was, on average, 10 times lower than elastic modulus and was generally not affected by processing conditions. Samples showed a more solid-like behavior that was better described by storage modulus. Storage modulus varied with all processing conditions used in this study, and even for the same solid fat content, different rheological properties were found. Storage and complex modulus increased with temperature of crystallization (25 to 30°C), even though solid fat contents of samples measured after 24 h at 10°C were the same. Moduli were higher for samples crystallized at slow cooling rate, decreased with agitation rate, and were lower for the 30-70% blend at all processing conditions used. Storage moduli also increased with storage time. Shear storage modulus was calculated from the DMA experimental data, and the results were in agreement with the values reported in literature for butter systems. Fractal dimensions calculated for these systems showed a significant decrease as agitation rate increased in agreement with the softening effect reported for working of butter.In food, an understanding of rheology is critical in optimizing product development efforts, processing methodology, and final product quality (1). The rheological behavior of plastic fats is governed by interactions between fat crystals in an aggregated three-dimensional, solid-liquid matrix (2). The liquid portion of the fat, interspersed throughout the aggregated fat network, serves as a continuous phase and, in conjunction with the solid fraction, is responsible for viscoelastic behavior (3). Of primary importance to the rheological behavior of fat are the amount of crystalline fat and the type of crystals present in the fat crystal network (4,5).Rheological measurements of fats can be performed at low or high deformation. In the latter, the fat crystal network undergoes irreversible deformation, whereas in the former, viscoelasticity is measured below the yield point and any permanent strain remains upon complete release of stress. Materials can be linear elastic, elastoplastic, or nonlinear elastic. Linear elastic materials show a straight line through the origin for stress vs. strain curves. Elastoplastic materials show straight lines until the yield point is reached, and then permanent deformation occurs with higher stress. Nonlinear elastic materials do not show linear behavior in any range of stress. Margarine and butter, at room temperature, may be...

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The Influence of Work Softening on the Viscoelastic Properties of Butter and Margarine

Cited by 49 publications

References 11 publications

Changes in microstructural, thermal, and rheological properties of olive oil/monoglyceride networks during storage

Changes in microstructural, thermal, and rheological properties of olive oil/monoglyceride networks during storage

Investigation of Semisolid Lipophilic Preparations by Small Strain and Continuous Shear Viscometry and Their Application to Texture Profile

Effect of processing conditions on physical properties of a milk fat model system: Rheology

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