Ideal Batch Reactor
Download as PPTX, PDF2 likes3,211 views
This document discusses the educational material related to ideal reactors for chemical reactions, presented under the supervision of Dr. Imran Nazir Unar. It covers the types of ideal reactors such as batch reactors, plug flow reactors, and mixed flow reactors, along with their performance equations. The presentation emphasizes fair use of potentially copyrighted material and is intended for students during the COVID-19 lockdown.
Ideal Batch Reactor
- 1. The material used in this presentation i.e., pictures/graphs/text, etc. is solely intended for educational/teaching purpose, offered free of cost to the students for use under special circumstances of Online Education due to COVID-19 Lockdown situation and may include copyrighted material - the use of which may not have been specifically authorized by Copyright Owners. It’s application constitutes Fair Use of any such copyrighted material as provided in globally accepted law of many countries. The contents of presentations are intended only for the attendees of the class being conducted by the presenter. Fair Use Notice
- 2. Ideal Reactors for Single Reaction Under the Supervision of: Dr. Imran Nazir Unar Mujeeb UR Rahman 17CH106 Chemical Engineering Department Chemical Reaction Engineering (CH314) Mehran University of Engineering & Technology Jamshoro, Pakistan
- 3. Lecture Objectives Discussion on: • Types of Ideal Reactors • Performance Equation of Ideal Batch Reactor
- 4. IDEAL REACTORS FOR A SINGLE REACTION Objectives In this series of lectures we will develop the performance equations for a single fluid reacting in the ideal reactors. We call these homogeneous reactions. Applications and extensions of these equations to various isothermal and non- isothermal operations are considered in the following lectures chapters.
- 5. IDEAL REACTORS FOR A SINGLE REACTION Types of Ideal Reactors Fig. 1: The three types of ideal reactors: (a) batch reactor, or BR; (b) plug flow reactor, or PFR; and (c) mixed flow reactor, or MFR.
- 6. INTRODUCTION TO REACTOR DESIGN About Batch Reactor. In the batch reactor, or BR, of Fig. 1(a) the reactants are initially charged into a container, are well mixed, and are left to react for a certain period. The resultant mixture is then discharged. This is an unsteady-state operation where composition changes with time; however, at any instant the composition throughout the reactor is uniform.
- 7. INTRODUCTION TO REACTOR DESIGN About Plug Flow Reactor. It is first kind of flow reactors. It has various names like plug flow, slug flow, piston flow, ideal tubular, and unmixed flow reactor. We refer to it as the plug flow reactor, or PFR, and to this pattern of flow as plug flow. It is characterized by the fact that the flow of fluid through the reactor is orderly with no element of fluid overtaking or mixing with any other element ahead or behind. Actually, there may be lateral mixing of fluid in a plug flow reactor; however, there must be no mixing or diffusion along the flow path. The necessary and sufficient condition for plug flow is for the residence time in the reactor to be the same for all elements of fluid
- 8. INTRODUCTION TO REACTOR DESIGN About CSTR. The other ideal steady-state flow reactor is called the mixed reactor, the backmix reactor, the ideal stirred tank reactor, the C* (meaning C-star), CSTR, or the CFSTR (constant flow stirred tank reactor), As its names suggest, it is a reactor in which the contents are well stirred and uniform throughout. Thus, the exit stream from this reactor has the same composition as the fluid within the reactor. We refer to this type of flow as mixed pow, and the corresponding reactor the mixed pow reactor, or MFR.
- 9. INTRODUCTION TO REACTOR DESIGN Understanding the term “V” In the treatment to follow it should be understood that the term V, called the reactor volume, really refers to the volume of fluid in the reactor. When this differs from the internal volume of reactor, then Vr designates the internal volume of reactor while V designates the volume of reacting fluid. For example, in solid catalyzed reactors with voidage ε we have For homogeneous systems, however, we usually use the term V alone.
- 10. INTRODUCTION TO REACTOR DESIGN Performance Equation for Ideal Batch Reactor Make a material balance for any component A. For such an accounting we usually select the limiting component. In a batch reactor, since the composition is uniform throughout at any instant of time, we may make the accounting about the whole reactor. Noting that no fluid enters or leaves the reaction mixture during reaction, the material balance equation, which was written for component A, becomes OR (1)
- 11. INTRODUCTION TO REACTOR DESIGN Performance Equation for Ideal Batch Reactor Evaluating the terms of Eq. 1, we find By replacing these two terms in Eq. 1, we obtain Rearranging and integrating then gives (2) (3)
- 12. INTRODUCTION TO REACTOR DESIGN Performance Equation for Ideal Batch Reactor This is the general equation showing the time required to achieve a conversion XA for either isothermal or non-isothermal operation. The volume of reacting fluid and the reaction rate remain under the integral sign, for in general they both change as reaction proceeds. This equation may be simplified for a number of situations. If the density of the fluid remains constant, we obtain (4)
- 13. INTRODUCTION TO REACTOR DESIGN Performance Equation for Ideal Batch Reactor For all reactions in which the volume of reacting mixture changes proportionately with conversion, such as in single gas-phase reactions with significant density changes, Eq. 3 becomes. In one form or another, Eqs. 2 to 5 have all been encountered in previous lectures. They are applicable to both isothermal and non-isothermal operations. Fig 2 is a graphical representation of two of these equations. (5)
- 14. INTRODUCTION TO REACTOR DESIGN Performance Equation for Ideal Batch Reactor Fig. 2: Graphical representation of the performance equations for batch reactors, isothermal or non-isothermal.
- 15. 15