"Heat Transfer between Fluidized Bed and Horizontal Bundle of Tubes in a Vertical Channel" INTERNATIONAL JOURNAL OF CHEMICAL REACTOR ENGINEERING 8(1) Volume 8 JANUARY 2010
INTERNATIONAL JOURNAL OF CHEMICAL REACTOR ENGINEERING • 2010
Publication Information
Authors
Mohamed A Moawed. Nabil Berbish, Ahmed A. Allam, Ahmed R. El-Shamy, Karam El-Shazly
Keywords
KEYWORDS: heat transfer, fluidized bed, bundle of tubes, vertical channel
Journal
INTERNATIONAL JOURNAL OF CHEMICAL REACTOR ENGINEERING
Publisher
Not Available
Volume
Vol. 8
Issue
Not Available
Pages
Not Available
publication.type
International
Paper Link
Open Link
Supplementary Materials
Not Available
Abstract
The present work aims to study the fluidization and heat transfer characteristics around a single horizontal heated tube, in-line tubes arrangement and staggered tubes arrangement immersed in a gas fluidized bed. The experiments were carried out on a square test section column (16 cm x 16 cm x 95 cm) from a steel
sheet of 3 mm thickness. Each arrangement of the tubes is installed in a separate test section. The plane tube bank for both in-line and staggered tubes arrangement consists of 5 rows and four tubes per row in equal vertical and horizontal pitch arrangement. The experimental setup has a transition channel with the same square section and 30 cm height. The other side of the transition channel has one hole of 5 mm inside diameter and 30 mm long to measure the pressure before the distributor
plate. The bed material used is sand particles of different sizes (1400 µm, 1600 µm, and 1850 µm). For the tested arrangements, the results show that the average heat transfer coefficient increases with the increase of the fluidizing velocity and with the decrease in particle diameter. Also, the comparison between the in-line and staggered tube arrangement showed that, the average heat transfer coefficient in case of staggered is higher than that of the in-line tube arrangement. Moreover empirical correlations for the average Nusselt number of the tested arrangements
using the experimental data are presented.
sheet of 3 mm thickness. Each arrangement of the tubes is installed in a separate test section. The plane tube bank for both in-line and staggered tubes arrangement consists of 5 rows and four tubes per row in equal vertical and horizontal pitch arrangement. The experimental setup has a transition channel with the same square section and 30 cm height. The other side of the transition channel has one hole of 5 mm inside diameter and 30 mm long to measure the pressure before the distributor
plate. The bed material used is sand particles of different sizes (1400 µm, 1600 µm, and 1850 µm). For the tested arrangements, the results show that the average heat transfer coefficient increases with the increase of the fluidizing velocity and with the decrease in particle diameter. Also, the comparison between the in-line and staggered tube arrangement showed that, the average heat transfer coefficient in case of staggered is higher than that of the in-line tube arrangement. Moreover empirical correlations for the average Nusselt number of the tested arrangements
using the experimental data are presented.
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