Behavior and fluidization of the cohesive powders: agglomerates sizes approach

Turki, Djamel; Fatah, Nouria

doi:10.1590/s0104-66322008000400007

Cited by 29 publications

(14 citation statements)

References 11 publications

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“…For 1 mm particles, forces ranged from 0.06 to 2.05 nN. The dominant mechanism by which uncharged particles form agglomerates when stored as powders is direct contact (Turki and Fatah 2008), bonding individual particles by van der Waals (VDW) force. This interparticular force can be calculated as below (Hamaker 1937)…”

Section: Effect Of Air Velocity On Aerosol Diametermentioning

confidence: 99%

“…In contrast, higher drag forces created in the air jet system broke agglomerates down to the sizes for which associated drags become comparable to the interparticle binding force (as discussed in previous sections). Furthermore, the funnel setup-which resembles a fluidized bed-features another deagglomeration mechanism: collisions between flowing particles (Turki and Fatah 2008;van Ommen et al 2010). These conditions promoted sharper peaks in the size distribution of the aerosols generated.…”

Section: Particle Size Distributionmentioning

confidence: 99%

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Dustiness and Deagglomeration Testing: Interlaboratory Comparison of Systems for Nanoparticle Powders

Ding

Stahlmecke

Jiménez

et al. 2015

Aerosol Science and Technology

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Different types of aerosolization and deagglomeration testing systems exist for studying the properties of nanomaterial powders and their aerosols. However, results are dependent on the specific methods used. In order to have well-characterized aerosols, we require a better understanding of how system parameters and testing conditions influence the properties of the aerosols generated. In the present study, four experimental setups delivering different aerosolization energies were used to test the resultant aerosols of two distinct nanomaterials (hydrophobic and hydrophilic TiO 2 ). The reproducibility of results within each system was good. However, the number concentrations and size distributions of the aerosols created varied across the four systems; for number concentrations, e.g., from 10 3 to 10 6 #/cm 3 . Moreover, distinct differences were also observed between the two materials with different surface coatings. The article discusses how system characteristics and other pertinent conditions modify the test results. We propose using air velocity as a suitable proxy for estimating energy input levels in aerosolization systems. The information derived from this work will be especially useful for establishing standard operating procedures for testing nanopowders, as well as for estimating their release rates under different energy input conditions, which is relevant for occupational exposure.

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Section: Effect Of Air Velocity On Aerosol Diametermentioning

confidence: 99%

Section: Particle Size Distributionmentioning

confidence: 99%

Dustiness and Deagglomeration Testing: Interlaboratory Comparison of Systems for Nanoparticle Powders

Ding

Stahlmecke

Jiménez

et al. 2015

Aerosol Science and Technology

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show abstract

“…This energy dissipation promotes an increase of bed cohesiveness, which depends on the strain rate, temperature, moisture content and chemical composition of the particles [10]. Furthermore, the fluid dynamic behavior can be affected by adhesion forces, which vary with the size distribution, morphology (shape) and physical properties (density, specific surface area and porosity) of the powder [17]. The soy protein isolate powder presented non-spherical particles with plastic behavior, once its main constituent is protein, and the fluidization regime showed to be cohesive with cracks and channeling behaviors, as a solid of Geldart's group C. However, during the agglomeration runs, this behavior changed with particle enlargement, and the powder became more free-flowing.…”

Section: Fluid Dynamics Behaviors Of Raw Soy Protein Isolate Powder Amentioning

confidence: 99%

Fluid dynamics and morphological characterization of soy protein isolate particles obtained by agglomeration in pulsed-fluid bed

2013

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“…There are several ways to improve the handling of fine powders. Whereas chemists prefer to use additives [1] to reduce adhesion and cohesion in order to improve the flowability and avoid agglomeration, physicists prefer to use air flow [2] or mechanical vibration [3] to achieve the same effect. The use of additives leads to a permanent altering of powder characteristics.…”

Section: Introductionmentioning

confidence: 99%

Vibration Assisted Handling of Dry Fine Powders

Dunst¹,

Bornmann²,

Hemsel³

et al. 2018

Preprint

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Since fine powders tend strongly to adhesion and agglomeration, their processing with conventional methods is difficult or impossible. Typically, in order to enable the handling of fine powders, chemicals are added to increase the flowability and reduce adhesion. This contribution shows that instead of additives also vibrations can be used to increase the flowability, to reduce adhesion and cohesion, and thus to enable or improve processes such as precision dosing, mixing, and transport of very fine powders. The methods for manipulating powder properties are described in detail and prototypes for experimental studies are presented. It is shown that the handling of fine powders can be improved by using low-frequency, high-frequency or a combination of low-and high-frequency vibration.

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Behavior and fluidization of the cohesive powders: agglomerates sizes approach

Cited by 29 publications

References 11 publications

Dustiness and Deagglomeration Testing: Interlaboratory Comparison of Systems for Nanoparticle Powders

Dustiness and Deagglomeration Testing: Interlaboratory Comparison of Systems for Nanoparticle Powders

Fluid dynamics and morphological characterization of soy protein isolate particles obtained by agglomeration in pulsed-fluid bed

Vibration Assisted Handling of Dry Fine Powders

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