Influence of contact point treatment on the cross flowmixing in a simple cubic packed bed: CFD simulation and experimental validation
Granular Matter • 2018
معلومات البحث
المؤلفون
Ali Alkhalaf · H. A. Refaey · Nabeh Al-durobi · E. Specht
الكلمات المفتاحية
Computational fluid dynamics · Cross flow mixing · Packed bed · Simple cubic · Contact point · Turbulent flow
المجلة العلمية
Granular Matter
الناشر
Springer
المجلد
20:22
العدد
Not Available
الصفحات
Not Available
publication.type
International
رابط البحث
Open Link
المواد المرفقة
Not Available
الملخص
The present study numerically investigates the mixing of an axial flow with a cross flow in a structured packed bed. Threedimensional
computational fluid dynamics CFD simulations have been carried out corresponding to the experimental setup.
ANSYS software version 14 was used with the standard κ–ε turbulence model. The study focuses on the effect of the contact
point treatment by using three methods; gap, overlap and bridge to avoid a high skewed element in the near of contact point.
A simple cubic packing with spherical particles of 52mm diameter was used which gives a porosity of 0.48. The mixing
is measured by an injection of nitrogen in the box with a structured bed of 924 spheres with an axial flow of air under
different operating conditions. The following parameters were measured; height, injection velocity, volume flow rate ratio,
flow conditions and location of injection. It is shown that the CFD simulation results can predict the cross flow mixing. The
study revealed that the gap method produced the best experimental results.
computational fluid dynamics CFD simulations have been carried out corresponding to the experimental setup.
ANSYS software version 14 was used with the standard κ–ε turbulence model. The study focuses on the effect of the contact
point treatment by using three methods; gap, overlap and bridge to avoid a high skewed element in the near of contact point.
A simple cubic packing with spherical particles of 52mm diameter was used which gives a porosity of 0.48. The mixing
is measured by an injection of nitrogen in the box with a structured bed of 924 spheres with an axial flow of air under
different operating conditions. The following parameters were measured; height, injection velocity, volume flow rate ratio,
flow conditions and location of injection. It is shown that the CFD simulation results can predict the cross flow mixing. The
study revealed that the gap method produced the best experimental results.
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