Effect of Particle Size and Cohesion on Powder Yielding and Flow

Shi, Hao; Mohanty, Rahul; Chakravarty, Somik; Cabiscol, Ramon; Morgeneyer, Martin; Zetzener, Harald; Ooi, Jin Y.; Kwade, Arno; Luding, Stefan; Magnanimo, Vanessa

doi:10.14356/kona.2018014

Cited by 90 publications

(55 citation statements)

References 48 publications

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“…milling speeds, the best flow properties on the basis of the SE was found for the highest granulometric class. This is consistent with the fact that larger particles are expected to flow more easily (Petit et al , ; Shi et al , ). Also, the better flowability of the 180–315 µm granulometric class for samples milled at 6 000 r.p.m.…”

Section: Resultssupporting

confidence: 84%

Effect of milling and sieving processes on the physicochemical properties of okra seed powders

Waiss

Kimbonguila

Abdoul-Latif

et al. 2020

Int J of Food Sci Tech

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The aim of this work was on one hand to investigate the influence of milling speed and mean particle size of granulometric classes of okra (Abelmoschus esculentus (L.) Moench) seed powders on proximal composition (related to nutritional potential). On the other hand, it was tried to relate flow properties to powder physicochemical characteristics, namely particle size distribution and proximal composition. Then, dry okra seeds were ground with an ultra-centrifugal mill at three rotational speeds, 6 000, 12 000 and 18 000 r.p.m., corresponding to circa 990, 3 958 and 8 906 g, respectively. Each powder was separated into four granulometric classes: ≥500, 315-500, 180-315 and ≤180 µm. Milling speed affected the particle size distribution of dry okra seed powders: on one hand, the higher the milling speed, the lower the mean particle size, mainly because of the higher the proportion of fine particles (<100 µm); on the other hand, at low milling speed, dry okra seed powders were rather monomodal and constituted of large particles, whereas at high milling speed they were bimodal and composed of two populations (fine and large particles). In granulometric classes, fat and protein contents were significantly higher for fine particles, unlike carbohydrate and ash contents that were lower. This differential distribution of macronutrients within granulometric classes was enhanced at higher milling speed. Finally, the ≤180 µm granulometric class, corresponding to the smallest mean particle size, had a low flowability, confirmed by their high cohesion and compressibility, which can be related to its high fat content making it sticky. On the contrary, the ≥500 µm granulometric class was not cohesive, leading to good flow properties.

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Section: Resultssupporting

confidence: 84%

Effect of milling and sieving processes on the physicochemical properties of okra seed powders

Waiss

Kimbonguila

Abdoul-Latif

et al. 2020

Int J of Food Sci Tech

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“…Sample 1 is mostly consisting of Titanium Dioxide, with a smaller particle size, compared to Talc, which is the main ingredient of sample 5. Smaller particle size usually means better cohesion between the particles , which in our case means that the particles from sample 1 would be more probable to stick with each other when the brush is introduced, compared to sample 5. This could also connect to the way the powder flows, insisting that when the cohesive forces are stronger, it would require more energy for the powder to flow.…”

Section: Resultsmentioning

confidence: 91%

“…Performance test: includes the cake strength and pay‐off which were tested as described below: Pay‐off: Two types of brushes were used for this research. The same amount of force was applied to the brush whereas picking up the sample and then the mass of the brush and sample were weighed using a balance. Cake strength: Ogami et al designed the Shock Resistance test, which is widely used in the cosmetic industry. First, pressed powder was dropped from a controlled height of 30.5 cm, and then, the damage of pressed powder was observed.…”

Section: Methodsmentioning

confidence: 99%

Designing high‐performance colour cosmetics through optimization of powder flow characteristics

Liu

Drakontis

Amin

2020

Intern J of Cosmetic Sci

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Objective Explore the impact of powder flow properties such as flow energy and compressibility on the performance characteristics of foundation powders such as cake strength and pay‐off. Methods FT4 Powder Rheometer from Freeman Technology was utilized to explore various powder compositions. The three major tests performed were flowability test, compressibility test and shear cell test. Results The results highlight that the sample which has higher compressibility has the better cake strength, and the sample which requires lower total energy has better pay‐off. Particles or samples with lower total flow energy, should have easier flow, therefore, should have better pay‐off. Samples and components with higher compressibility, should hold the structure better, therefore, should have better cake strength. Talc has the highest compressibility and lowest flow energy. Foundation sample 5 has the highest concentration of talc and also has the best performance. Conclusion The lower the total flow energy, the easier it is for the powder to flow, and have better pay‐off. Powder compressibility correlates with cake strength which means that a sample with better compressibility consequently has the better cake strength. Samples 5 and 10 require less total flow energy, have lower shear stress, and higher compressibility, therefore, have better final performance. Both samples 5 and 10 have higher talc concentrations compared to other formulations.

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“…Each grade of the Eskal series is milled and then sieved to ensure a certain particle size distribution. Three grades of Eskal are chosen specifically from the experience in a previous study [6]: fine/cohesive Eskal300 (d 50 = 2.22 µm), slightly cohesive Eskal15 (d 50 = 19 µm) and coarse/free-flowing Eskal150 (d 50 = 138 µm). The details of their physical properties are summarized in Table 1.…”

Section: Materials Description and Characterizationmentioning

confidence: 99%

“…In the same figure, we have also indicated the values of angle of repose and the extrapolation of the flow angle from the rotating drum at 0 rpm for both Eskal150 and Eskal300. Note that here we have also included the data at larger pre-shear stresses (σ > 2 kPa) from the previous study [6] for the sake of completeness and validation.…”

Section: From Small To Large Confining Stressmentioning

confidence: 99%

Stretching the limits of dynamic and quasi-static flow testing on cohesive limestone powders

2020

Self Cite

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Powders are a special class of granular matter due to the important role of cohesive forces. The flow behavior of powders depends on the flow states and stress and is therefore difficult to measure/quantify with only one experiment. In this study, the most commonly used characterization tests that cover a wide range of states are compared: (static, free surface) angle of repose, the (quasi-static, confined) ring shear steady state angle of internal friction, and the (dynamic, free surface) rotating drum flow angle are considered for free flowing, moderately and strongly cohesive limestone powders.The free flowing powder gives good agreement among all different situations (devices), while the moderately and strongly cohesive powders behave more interestingly. Starting from the flow angle in the rotating drum and going slower, one can extrapolate to the limit of zero rotation rate, but then observes that the angle of repose measured from the heap is considerably larger, possibly due to its special history. When we stretch the ring shear test to its lowest confining stress limit, the steady state angle of internal friction of the cohesive powder coincides with the flow angle (at free surface) in the zero rotation rate limit.

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Effect of Particle Size and Cohesion on Powder Yielding and Flow

Cited by 90 publications

References 48 publications

Effect of milling and sieving processes on the physicochemical properties of okra seed powders

Effect of milling and sieving processes on the physicochemical properties of okra seed powders

Designing high‐performance colour cosmetics through optimization of powder flow characteristics

Stretching the limits of dynamic and quasi-static flow testing on cohesive limestone powders

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