Residence time distribution and chemical reactor efficiency

Add to my library

J4014 V1 Article

Residence time distribution and chemical reactor efficiency

Author : Jean-Léon HOUZELOT

Publication date: September 10, 2013 | Lire en français

Add to my library Add to my library

Logo Techniques de l'Ingenieur You do not have access to this resource.
Request your free trial access! Free trial

Already subscribed?

Overview

ABSTRACT

This article deals with the various experimental methods for the acquisition of residence time distribution curves, and presents several mathematical models of residence time distribution for ideal and real reactors. Signal processing methods are provided which allow, via a comparison between experimental curves and curves derived from models, for identification distribution parameters. Two examples are also presented, one based on the model of stirred tanks in series, and the other on the plug flow with axial dispersion model.

Read this article from a comprehensive knowledge base, updated and supplemented with articles reviewed by scientific committees.

Read the article

AUTHOR

  • Jean-Léon HOUZELOT : Professor Emeritus - University of Lorraine - École nationale supérieure des industries chimiques Nancy

 INTRODUCTION

The concept of residence time distribution (RSD) is used in process engineering to characterize the hydrodynamics of a chemical reactor or any other installation through which a circulating fluid passes. It can be used to :

  • diagnose the presence of stagnant zones or short-circuit phenomena;

  • to establish a hydrodynamic flow model that can be used to calculate the chemical performance of a reactor.

The main properties of residence time distributions are reviewed, followed by experimental methods for acquiring DTS curves, and then methods for developing DTS models for ideal and real reactors.

The parameters of a DTS are identified by comparing experiment and model. Signal processing methods are numerous, ranging from the simplest, i.e. the method of moments, through Laplace transforms, then Fourrier transforms, to the most complex, i.e. the method of non-linear regression directly on the curves. Emphasis is placed not only on the methods of implementation, but also on the precision that can be expected.

Two examples are presented:

  • the first on a compartmental model, the cascade mixer model;

  • the other on a distributed-parameter model, the axial-dispersion plug-flow model.

Two programs written in Matlab ® enable the reader to easily implement the most precise processing mode.

You do not have access to this resource.
Logo Techniques de l'Ingenieur

Exclusive to subscribers. 97% yet to be discovered!

You do not have access to this resource. Click here to request your free trial access!

Already subscribed?


KEYWORDS

system dynamics   |   internal age   |   life expectancy   |   residence time   |   hydrodynamic models   |   process enginneering   |   chemical reactors   |   residence time distribution   |   signal processing

Ongoing reading
Residence time distribution and chemical reactor efficiency

Article included in this offer

"Unit operations. Chemical reaction engineering"

( 343 articles )

Complete knowledge base

Updated and enriched with articles validated by our scientific committees

Services

A set of exclusive tools to complement the resources

View offer details

Dans les ressources documentaires

Calcul des réacteurs catalytiques - Approche préliminaire

Le dimensionnement des réacteurs catalytiques est souvent problématique, de par leur caractère polyphasiq...

Calcul des réacteurs catalytiques - Déshydrogénation de l’éthanol

Cet article détaille la démarche à suivre pour aboutir à un dimensionnement d’un réacteur catalytique à t...

Calcul des réacteurs catalytiques - Production de trioxyde de soufre

Le tétraoxosulfate de dihydrogène, de formule H 2 SO 4 , plus couramment appelé acide sulfurique , est o...

Calcul des réacteurs catalytiques - Synthèse d’ammoniac

La synthèse de l’ammoniac est l’un des procédés catalytiques les plus importants, au même titre que la sy...

Tous les livres blancs
Article Qu'est-ce que le Power-to-Gas ?
1 September 2023
Qu'est-ce que le Power-to-Gas ?

Le Power-to-Gas est le procédé par lequel de l’énergie électrique est convertie en énergie chimique, sous forme gazeuse. Par rapport à l’électricité, le gaz ain...

Article Novecal développe des synthèses à façon
20 September 2024
Novecal développe des synthèses à façon

Utilisant des oligomères cycliques, la start-up Novecal développe des catalyseurs innovants. Elle propose aussi de tracer les voies de synthèse sur mesure.

Toutes les actualités
Contact us