5 results on '"Gentzler, Michael"'
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2. Measurement of velocity and density profiles in discharging conical hoppers by NMR imaging
- Author
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Gentzler, Michael and Tardos, Gabriel I
- Subjects
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FLUID mechanics , *MAGNETIC resonance imaging , *GRANULAR materials , *BOUNDARY layer (Aerodynamics) , *BOUNDARY value problems , *CONTINUUM mechanics , *COMPRESSIBILITY - Abstract
Abstract: Nuclear magnetic resonance (NMR) imaging was used to measure velocity and density profiles in 3-D conical hoppers fed from an open vertical silo. Discharge of a 200μm-diameter powder in both mass and plug flow was studied with hoppers of different half angles, of 10° and 80°, respectively. An analytical solution for compressible (variable density) mass flow in the 3-D axi-symmetric geometry was also developed following the procedure outlined in and . The density variation and velocity profiles obtained experimentally were compared to predictions of this theory for dense, compressible granular flows. We found, from both theory and experiment, that the powder has to exhibit significant dilation (compressibility) as it is accelerated through the constriction in the hopper. The degree of compressibility was found, experimentally, to be lower than that predicted by the mass flow hopper theory. The powder unexpectedly exhibited a boundary layer with a fully-rough boundary condition in the mass flow hopper. In the funnel-flow hopper, the expected “dead zone” was found around the orifice and extended about one diameter length into the silo. The centerline velocity increased according to an exponential function. [Copyright &y& Elsevier]
- Published
- 2009
- Full Text
- View/download PDF
3. XRCT characterization of mesoscopic structure in poured and tapped cohesive powders and prediction by DEM.
- Author
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Abi-Mansour, Andrew, McClure, Sean, and Gentzler, Michael
- Subjects
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POWDERS , *DISCRETE element method , *GRANULAR materials , *COMPUTED tomography , *STRUCTURAL engineering - Abstract
Predicting structural and flow characteristics of cohesive powder systems is a technical challenge in many powder technology applications. The discrete element method (DEM) is a promising approach to model the mesoscale structure and flow behavior of cohesive granular systems. Advances in experimental techniques such as X-ray computed tomography (XRCT) have enabled characterization of powder systems with sub-micron resolution. Combined with standard bulk powder characterization methods, this technique allows for mesoscopic structural characteristics of cohesive powder systems to be compared directly with DEM simulation. In this study, DEM and XRCT are used to characterize the structural characteristics of two moderately cohesive roughly spherical “model” powders – glass and stearic acid – under loosely poured and tapped consolidated conditions. The DEM simulations are based on a constitutive elasto-plastic model that makes use of the JKR theory to account for cohesive interparticle surface forces. Powder density and mesoscopic void structure obtained from DEM simulation are compared to characterization results obtained from XRCT image analysis. The results show that DEM can accurately predict the extent of tapping induced densification and mesostructure characteristics in cohesive powders, with superior agreement for stearic acid. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
4. Hydrodynamic investigation of USP dissolution test apparatus II.
- Author
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Ge Bai, Armenante, Piero M., Plank, Russell V., Gentzler, Michael, Ford, Kenneth, and Harmon, Paul
- Subjects
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HYDRODYNAMICS , *PHARMACEUTICAL industry , *LASER Doppler velocimeter , *VELOCIMETRY , *FLUID dynamics , *DRUG tablets - Abstract
The USP Apparatus II is the device commonly used to conduct dissolution testing in the pharmaceutical industry. Despite its widespread use, dissolution testing remains susceptible to significant error and test failures, and limited information is available on the hydrodynamics of this apparatus. In this work, laser-Doppler velocimetry (LDV) and computational fluid dynamics (CFD) were used, respectively, to experimentally map and computationally predict the velocity distribution inside a standard USP Apparatus II under the typical operating conditions mandated by the dissolution test procedure. The flow in the apparatus is strongly dominated by the tangential component of the velocity. Secondary flows consist of an upper and lower recirculation loop in the vertical plane, above and below the impeller, respectively. A low recirculation zone was observed in the lower part of the hemispherical vessel bottom where the tablet dissolution process takes place. The radial and axial velocities in the region just below the impeller were found to be very small. This is the most critical region of the apparatus since the dissolving tablet will likely be at this location during the dissolution test. The velocities in this region change significantly over short distances along the vessel bottom. This implies that small variations in the location of the tablet on the vessel bottom caused by the randomness of the tablet descent through the liquid are likely to result in significantly different velocities and velocity gradients near the tablet. This is likely to introduce variability in the test. © 2007 Wiley-Liss, Inc. and the American Pharmacists Association J Pharm Sci 96: 2327–2349, 2007 [ABSTRACT FROM AUTHOR]
- Published
- 2007
- Full Text
- View/download PDF
5. Formation and internal microstructure of granules from wetting and non-wetting efavirenz/iron oxide blends.
- Author
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Farber, L., Al-aaraj, Duaa K., Smith, Rachel, and Gentzler, Michael
- Subjects
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FERRIC oxide , *VISCOSITY , *MICROSTRUCTURE , *MIXING , *PHARMACEUTICAL powders - Abstract
• Hollow granules were produced at high binder viscosity regardless of blend wettability. • Solid granules were produced at a low binder viscosity regardless of blend wettability. • Different balance of capillary, viscous and impact forces explains difference in microstructure. • Modified Reynolds and Weber numbers are proposed to rationalize shell stability. • Borderline non-wetting blends are most favorable for hollow granule formation. An examination of granulation of non-wetting/wetting powder mixtures is presented. Non-wetting micron-size pharmaceutical active powder was blended with a sub-micron wetting excipient in three different ratios to produce wetting, non-wetting, and marginally-wetting powder blends. Model nuclei were prepared from these blends using binder droplets with viscosity of ca 10, 100 and 1000 mPa·s and further granulated in tumbling drum and high shear granulator. The effects of blend wettability, binder viscosity, granulation time, and shear forces on granule size and microstructure were investigated. Hollow granules were produced at higher binder viscosity of 100 and 1000 mPa·s regardless of blend wettability. Solid granules with a complex internal microstructure were produced at low binder viscosity of 10 mPa·s regardless of blend wettability. Contribution of capillary, viscous and impact forces are considered to explain differences in granule microstructure. Modified Reynolds and Weber numbers are proposed to rationalize formation and stability of shell microstructures. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
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