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The effect of disperse phase viscosity in the emulsification of a semi-dairy beverage–combining emulsification experiments and numerical single drop breakup simulations

Lewerentz, Frida LU ; Pappas, Konstantinos ; Bergenståhl, Björn LU and Håkansson, Andreas LU (2023) In Food and Bioproducts Processing 138. p.103-115
Abstract

Due to the rise in the demand for semi-dairy beverages (vegetable fat in a de-fatted dairy matrix) as well as for fully plant-based formulations, there is a growing interest in better understanding how emulsification processes are influenced by raw material choices. Semi-dairy beverages, for example, utilize a wide variety of vegetable oils in their formulation. This contribution combines traditional emulsification experiments with high-resolution numerical drop breakup simulations to improve the understanding of how oil viscosity influences the emulsification process. It is concluded that the experimentally observed increase in drop diameter with oil viscosity is well predicted by the viscosity-corrected Kolmogorov Hinze theory. The... (More)

Due to the rise in the demand for semi-dairy beverages (vegetable fat in a de-fatted dairy matrix) as well as for fully plant-based formulations, there is a growing interest in better understanding how emulsification processes are influenced by raw material choices. Semi-dairy beverages, for example, utilize a wide variety of vegetable oils in their formulation. This contribution combines traditional emulsification experiments with high-resolution numerical drop breakup simulations to improve the understanding of how oil viscosity influences the emulsification process. It is concluded that the experimentally observed increase in drop diameter with oil viscosity is well predicted by the viscosity-corrected Kolmogorov Hinze theory. The numerical simulations are able to reproduce this trend and allow further insight into breakup mechanism; suggesting that it is the prolonging of the deformation phase that make more viscous oils more challenging to homogenize. From a beverage processing perspective, the homogenizing pressure (and energy cost) necessary to achieve the same physical stability needs to be 73% higher if using a typical high-viscosity vegetable oil than if using a typical low viscosity vegetable oil.

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author
; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
Drop breakup, Emulsification, Homogenization, Semi-dairy beverage, Turbulence
in
Food and Bioproducts Processing
volume
138
pages
13 pages
publisher
Elsevier
external identifiers
  • scopus:85147197339
ISSN
0960-3085
DOI
10.1016/j.fbp.2023.01.008
language
English
LU publication?
yes
additional info
Funding Information: Prof Luca Brandt and Dr Marco Crialesi-Esposito are gratefully acknowledged for providing and helping to set up the numerical single drop breakup code. The authors would also like to thank AAK Sweden AB for providing the Fritex HORO used in the project. AH acknowledges financial support from The Swedish Research Council (VR), grant number 2018-03820. Funding Information: Prof Luca Brandt and Dr Marco Crialesi-Esposito are gratefully acknowledged for providing and helping to set up the numerical single drop breakup code. The authors would also like to thank AAK Sweden AB for providing the Fritex HORO used in the project. AH acknowledges financial support from The Swedish Research Council (VR), grant number 2018-03820 . Publisher Copyright: © 2023 The Author(s)
id
50800d27-6ca0-4668-b0b4-00b2f23459cd
date added to LUP
2023-02-13 06:55:12
date last changed
2023-12-20 06:21:39
@article{50800d27-6ca0-4668-b0b4-00b2f23459cd,
  abstract     = {{<p>Due to the rise in the demand for semi-dairy beverages (vegetable fat in a de-fatted dairy matrix) as well as for fully plant-based formulations, there is a growing interest in better understanding how emulsification processes are influenced by raw material choices. Semi-dairy beverages, for example, utilize a wide variety of vegetable oils in their formulation. This contribution combines traditional emulsification experiments with high-resolution numerical drop breakup simulations to improve the understanding of how oil viscosity influences the emulsification process. It is concluded that the experimentally observed increase in drop diameter with oil viscosity is well predicted by the viscosity-corrected Kolmogorov Hinze theory. The numerical simulations are able to reproduce this trend and allow further insight into breakup mechanism; suggesting that it is the prolonging of the deformation phase that make more viscous oils more challenging to homogenize. From a beverage processing perspective, the homogenizing pressure (and energy cost) necessary to achieve the same physical stability needs to be 73% higher if using a typical high-viscosity vegetable oil than if using a typical low viscosity vegetable oil.</p>}},
  author       = {{Lewerentz, Frida and Pappas, Konstantinos and Bergenståhl, Björn and Håkansson, Andreas}},
  issn         = {{0960-3085}},
  keywords     = {{Drop breakup; Emulsification; Homogenization; Semi-dairy beverage; Turbulence}},
  language     = {{eng}},
  pages        = {{103--115}},
  publisher    = {{Elsevier}},
  series       = {{Food and Bioproducts Processing}},
  title        = {{The effect of disperse phase viscosity in the emulsification of a semi-dairy beverage–combining emulsification experiments and numerical single drop breakup simulations}},
  url          = {{http://dx.doi.org/10.1016/j.fbp.2023.01.008}},
  doi          = {{10.1016/j.fbp.2023.01.008}},
  volume       = {{138}},
  year         = {{2023}},
}