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The concentration of chlorine gas in air must be reduced from 10.0 mg/m³ to 2.95 mg/m³. Determine the height of the packed tower that should be used if the following parameters apply: Incoming liquid is water free of Cl₁₂ Operating temperature = 20.0°C Operating pressure 101.325 kPa H₂ = 0.662 m H₁ = 0.285 m Henry's law constant, m = 6.820 mole fraction units. Liquid flow rate Gas flow rate 15.0 kg/s 3.00 kg/s

The concentration of chlorine gas in air must be reduced from 10.0 mg/m³ to 2.95 mg/m³. Determine the height of the packed tower that should be used if the following parameters apply: Incoming liquid is water free of Cl₁₂ Operating temperature = 20.0°C Operating pressure 101.325 kPa H₂ = 0.662 m H₁ = 0.285 m Henry's law constant, m = 6.820 mole fraction units. Liquid flow rate Gas flow rate 15.0 kg/s 3.00 kg/s

Introduction to Chemical Engineering Thermodynamics
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
Section: Chapter Questions
Problem 1.1P
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9-39. The concentration of chlorine gas in air must be reduced from 10.0 mg/m³ to 2.95 mg/m³. Determine the height of the packed tower that should be used if the following parameters apply: Incoming liquid is water free of Cl₂ Operating temperature = 20.0°C Operating pressure 101.325 kPa H₂ = 0.662 m H₁ = 0.285 m Henry's law constant, m = 6.820 mole fraction units Liquid flow rate L 15.0 kg/s Gas flow rate= 3.00 kg/s
Transcribed Image Text:9-39. The concentration of chlorine gas in air must be reduced from 10.0 mg/m³ to 2.95 mg/m³. Determine the height of the packed tower that should be used if the following parameters apply: Incoming liquid is water free of Cl₂ Operating temperature = 20.0°C Operating pressure 101.325 kPa H₂ = 0.662 m H₁ = 0.285 m Henry's law constant, m = 6.820 mole fraction units Liquid flow rate L 15.0 kg/s Gas flow rate= 3.00 kg/s
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