Effects of Particle Size on Mixtures During Nonelectrostatic and Electrostatic Powder Coating

Somboonvechakarn, Chanun; Barringer, Sheryl A.

doi:10.1111/j.1745-4530.2009.00538.x

Cited by 5 publications

(12 citation statements)

References 13 publications

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“…4). A decrease in transfer efficiency of fine powders and an increase in transfer efficiency of coarse powders in starch mixture were also observed by others [15]. For some powders, such as NaCl, KCl and soy protein, the changes in transfer efficiency was significant, while for other powders the trend was the same but was not statistically significant.…”

Section: Separationsupporting

confidence: 59%

“…Greater transfer efficiency for coarse powders than fine powders due to gravity force was also found by others [8,13,19]. Not only differences in targeting loss cause separation, but also the differences in adhesion loss cause separation, particularly when the mixture is coated electrostatically [15]. Finally, differences in dust production also contribute to loss and separation of the powders.…”

Section: Introductionmentioning

confidence: 54%

“…A higher transfer efficiency of coarse powder than fine powders has been reported by others [3,13,21]. In a previous study, the difference in individual transfer efficiency was the biggest cause of separation in mixtures of NaCl and starch [15].…”

Section: Separationmentioning

confidence: 79%

“…Separation can negatively affect flavor and appearance of the final product. While the composition of the powders contributes to the separation of mixtures [6], particle size has been reported to cause separation in a mixture as well [15,20]. Differences in particle trajectory cause the separation in the mixture containing powders with different size.…”

Section: Introductionmentioning

confidence: 96%

“…In a mixture of coarse and fine powders, differences in adhesion loss increase the separation. Fine powders with a higher charge adhere well on the target and increase the adhesion loss of coarse powders by creating a charged layer and repelling the incoming coarse powders [15]. However, in a mixture with similar size powders, using electrostatic coating decreased separation by decreasing targeting loss and adhesion loss of powders in the mixture [6,16].…”

Section: Introductionmentioning

confidence: 98%

See 4 more Smart Citations

The influence of particle size on separation and dustiness in powder mixtures during nonelectrostatic and electrostatic coating

Likitwattanasade

Barringer

2015

Journal of Electrostatics

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Section: Separationsupporting

confidence: 59%

Section: Introductionmentioning

confidence: 54%

Section: Separationmentioning

confidence: 79%

Section: Introductionmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 98%

See 3 more Smart Citations

The influence of particle size on separation and dustiness in powder mixtures during nonelectrostatic and electrostatic coating

Likitwattanasade

Barringer

2015

Journal of Electrostatics

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Effect of Particle Density and Composition on Mixtures During Nonelectrostatic and Electrostatic Powder Coating

Somboonvechakarn

Barringer

2011

J Food Process Engineering

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Nonelectrostatic and electrostatic coating processes cause the proportion of each powder in a mixture to be different on the target than in the initial mixture. First, some loss of powder occurs during the targeting step; thus, not all of the powder lands on the target. This targeting loss is caused by the individual powder characteristics and interactions that occur between powders in the mixture. Also, an uneven distribution is produced on the target because of the way the powder is dispersed. Finally, adhesion loss occurs on the target, also because of individual and mixture characteristics. During nonelectrostatic coating, a mixture of fine NaCl and starch particles changed in proportion due to the differences between individual targeting, and mixture adhesion, losses. Little change in proportion occurred in the coarse NaCl and starch mixture. During electrostatic coating of both mixtures, proportions changed because of differences between individual adhesion losses. PRACTICAL APPLICATIONS Food coatings usually consist of mixtures of powders with different densities and compositions, which cause separation of the powders. For maximum consumer acceptance, the powder should be evenly coated on the surface, with the same proportion of ingredients as in the original powder. In fine powder mixtures, during nonelectrostatic coating, targeting loss is the biggest cause of separation. Therefore, when mixtures of different density and composition are used, the coating systems need to be designed to minimize the targeting loss difference between the powders. Electrostatic coating reduced targeting loss of the fine powders by a large amount; therefore, it is one way to decrease separation. Electrostatic coating of both mixtures had high adhesion loss; therefore, the electrostatic coating system needs to be designed to minimize adhesion loss, such as by addition of oil or other tack agents, when powder mixtures are coated.

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Separation of Powder Mixtures during Electrostatic and Nonelectrostatic Coating

Likitwattanasade

Barringer

2013

J Food Process Engineering

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Powder separation causes uneven flavor and color on coated food products. Understanding the basis behind separation is needed to decrease separation. NaCl, starch, protein, sugar and mixtures of pairs of those powders were coated nonelectrostatically and electrostatically. Separation occurred in most mixtures. Individual targeting loss and adhesion loss caused separation while interactions between powders decreased both of these losses and separation during mixture coating. The difference in individual targeting loss was the greatest cause of separation. During nonelectrostatic coating, when NaCl was one of the powders in the mixture, there were a greater number of locations both where separation actually occurred and where it was predicted to occur. During electrostatic coating, the individual targeting loss of all powders during electrostatic coating was lower than in nonelectrostatic coating and the difference in individual targeting loss was also lower. Electrostatic coating generally decreased separation in the mixtures without NaCl. Practical Applications Using mixtures with similar size powders has been shown to reduce separation during powder coating. However, even if the powders are the same size, separation still occurs because different powders have different properties. Increasing the amount of salt in a mixture may decrease separation because salt has greater targeting loss than other powders. Minimizing differences in individual targeting loss decreases separation, as does mixing powders together. Electrostatic coating can be used to decrease losses and separation in mixtures without salt.

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Effects of Particle Size on Mixtures During Nonelectrostatic and Electrostatic Powder Coating

Cited by 5 publications

References 13 publications

The influence of particle size on separation and dustiness in powder mixtures during nonelectrostatic and electrostatic coating

The influence of particle size on separation and dustiness in powder mixtures during nonelectrostatic and electrostatic coating

Effect of Particle Density and Composition on Mixtures During Nonelectrostatic and Electrostatic Powder Coating

Separation of Powder Mixtures during Electrostatic and Nonelectrostatic Coating

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