A ---> B+D first order gas phase reaction is carried out in a packed bed reactor at 8 atm pressure and 390 K temperature. The volumetric feed rate is 12 lt/s. The feed contains 40% A and 60% inert. The packed bed reactor is filled with spherical porous catalyst pellets. The actual reaction rate is given as (mol/kg catalyst.s). The pressure drop parameter (α) was found to be 1.5*10-3 kg-1 . Accordingly, calculate the amount of catalyst (kg) required to achieve 85% conversion from the reactor and the pressure at the reactor outlet. k(300) =0.0075 L/ kg.catalyst.min , Ea=15000 cal/mol
A ---> B+D first order gas phase reaction is carried out in a packed bed reactor at 8 atm pressure and 390 K temperature. The volumetric feed rate is 12 lt/s. The feed contains 40% A and 60% inert. The packed bed reactor is filled with spherical porous catalyst pellets. The actual reaction rate is given as (mol/kg catalyst.s). The pressure drop parameter (α) was found to be 1.5*10-3 kg-1 . Accordingly, calculate the amount of catalyst (kg) required to achieve 85% conversion from the reactor and the pressure at the reactor outlet. k(300) =0.0075 L/ kg.catalyst.min , Ea=15000 cal/mol
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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A ---> B+D first order gas phase reaction is carried out in a packed bed reactor at 8 atm pressure and 390 K temperature. The volumetric feed rate is 12 lt/s. The feed contains 40% A and 60% inert. The packed bed reactor is filled with spherical porous catalyst pellets. The actual reaction rate is given as (mol/kg catalyst.s). The pressure drop parameter (α) was found to be 1.5*10-3 kg-1 . Accordingly, calculate the amount of catalyst (kg) required to achieve 85% conversion from the reactor and the pressure at the reactor outlet.
k(300) =0.0075 L/ kg.catalyst.min , Ea=15000 cal/mol
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