Design a cyclone to recover solids from a process gas stream, using the following experimental data. The anticipated particle size distribution in the inlet gas is given by sieve analysis table [D,-f(%); Particle size (um) versus Percentage by weight less than]. Particle size (um) 50 40 30 20 10 Percentage by weight less than 90 86 08. 70 45 25 10 Data: p-2500 kg/m'; Q-4000 m' N/h; T-150°C; P=1 atm.; An 80 percent recovery of the solids is required

Introduction to Chemical Engineering Thermodynamics
8th Edition
ISBN:9781259696527
Author:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
Publisher:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
Chapter1: Introduction
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Design a cyclone to recover solids from a process gas stream, using the
following experimental data. The anticipated particle size distribution in
the inlet gas is given by sieve analysis table [D,-f(%); Particle size (um)
versus Percentage by weight less than].
Particle size (um)
50
40
30
20
10
Percentage by weight less than
90
86
*80
70
45
25
10
Data: p-2500 kg/m'; Q-4000 m' N/h; T-150°C; P=1 atm.; An 80 percent
recovery of the solids is required
Design a cyclone to recover solids from a
process gas stream. The density of the particles
is 2500 kg/m3, and the gas is essentially
nitrogen at 150°C. The stream volumetric flow-
rate is 4000 m3/h, and the operation is at
atmospheric pressure. An 80 per cent recovery
of the solids is required.
Viscosity of nitrogen at 1500C = 0.023
mN.s/m2,
viscosity of air =0.018 mN.s/m2
N2 molecular weight = 28 kg/kmol
Transcribed Image Text:Design a cyclone to recover solids from a process gas stream, using the following experimental data. The anticipated particle size distribution in the inlet gas is given by sieve analysis table [D,-f(%); Particle size (um) versus Percentage by weight less than]. Particle size (um) 50 40 30 20 10 Percentage by weight less than 90 86 *80 70 45 25 10 Data: p-2500 kg/m'; Q-4000 m' N/h; T-150°C; P=1 atm.; An 80 percent recovery of the solids is required Design a cyclone to recover solids from a process gas stream. The density of the particles is 2500 kg/m3, and the gas is essentially nitrogen at 150°C. The stream volumetric flow- rate is 4000 m3/h, and the operation is at atmospheric pressure. An 80 per cent recovery of the solids is required. Viscosity of nitrogen at 1500C = 0.023 mN.s/m2, viscosity of air =0.018 mN.s/m2 N2 molecular weight = 28 kg/kmol
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