Types of reactor
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Types of reactor Chemical Reaction Engineering
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Types of reactor
- 1. Types of Reactor Ihsan Wassan U.S –PAKISTAN CENTER FOR ADVANCED STUDIES IN WATER MEHRAN UNIVERSITY OF ENGINEERING AND TECHNOLOGY, JAMSHORO, SINDH
- 2. Contents • Reactor – Introduction • Different types of Reactors • CSTR Modeling • Example - sizing a CSTR
- 3. Reactor – Introduction • Chemical kinetics is the study of chemical reaction rates and reaction mechanisms. • The study of chemical reaction engineering (CRE) combines the study of chemical kinetics with the reactors in which the reactions occur. • A reactor is the vessel, tank or cylinder in which chemical reaction takes place.
- 4. Types of Reactors • Batch reactors (stirred tanks) • Continuous stirred tank reactor (CSTR) • Plug Flow Reactor (PFR) • Fixed Bed Reactor • Fluidized bed Reactor (FBR)
- 5. Different Types of Reactors
- 6. Batch reactors (Stirred Tanks) • Batch reactor is the generic term for a type of vessel (cylinder tank)widely used in process industries. • A typical batch rector consists of a tank with an agitator and integral heating/ cooling system. • Heating/cooling uses jacketed walls, internal coil and internal tube.
- 7. Batch reactors (Stirred Tanks) Advantages: • Batch reactors can be stopped between batches, so the production rate is flexible. • More flexible, one can use easily • If process degrades the reactor in some way, a batch reactor can be cleaned, relined etc. • Batch reactor often achieve better quality than a plug flow reactor and also better productivity than CSTR. Fig. Simple batch homogenous reactor
- 8. Continuous Stirred Tank Reactor • In CSTR one or more fluid reagents are introduced into the tank reactor equipped with an impeller. • The impeller stirs the reagent to ensure proper mixing. • A steady state the flow rate in must equal the mass flow rate out, likewise the tank will overflow or go empty (transition state) • All calculations in CSTRs assume perfect mixing • Reaction rate associated with the final output concentration • It can be seen hat infinite number of small CSTR operating in series would be equivalent to a PFR. Fig. CSTR
- 9. Continuous Stirred Tank Reactor Kind of phase present Usage Advantages Disadvantages 1. Liquid 1. When agitation required 1. Continuous operation 1. Lowes conversion per volume 2. Gas- liquid 2. Series configuration for different Concentrations streams 2. Good temperature control 2. By-passing and channeling possible with poor agitation 3. Solid- Liquid 3. Easy adapts to two phase runs 4. Good control 5. Simplicity of construction 6. Low operating (labor) cost 7. Easy to clean Advantages and disadvantages
- 10. Plug Flow Reactor • Each and every particle having same residence time, back mixing not allowed in PFR • PFR model is used to describe chemical reaction in continuous, flowing systems. • PFR sometimes called Continues tubular reactors (CTRs) • PFR model works well for many fluids: liquids, gases and slurries. • Fluid flow is sometimes turbulent flow or axial diffusion. • PFR can be used to multiple reactions as well as reactions involving changing temperatures, pressures and densities of flow. • Used for large scale fast reactions, homogenous and heterogenous reactions, continuous production and high temperature reactions.
- 11. Plug Flow Reactor Advantages • PFR have high volumetric unit conversion • Run for long period of time without labor • Excellent heat transfer Disadvantages: • Temperatures are hard to control • Maintenance is expensive • Shutdown and cleaning may be expensive
- 12. Fixed Bed Reactor • Solids take part in reaction • Unsteady or semi-batch mode • Over sometime solids either replaced or regenerated Fig. Simple fixed bed reactor
- 13. Fluidized Bed Reactor • Fluidized bed reactors can be used to carryout a variety of multiphase chemical reactions. • In this type of reactor, a fluid (gas or liquid) is passed through a granular solid material (usually a catalyst possible shaped as tiny spheres) at high enough velocity to suspend the solid. Advantages: • Uniform particle mixing • Uniform temperature • Ability to operate reactor in continuous state Fig. Fluidized bed reactor
- 14. Continuous Stirred Tank Reactor (CSTR) When the general mole balance equation is applied to a CSTR operated at steady state (i.e., conditions do not change with time), in which there are no spatial variations in the rate of reaction (i.e., perfect mixing),
- 15. it takes the familiar form known as the design equation for a CSTR: • The CSTR design equation gives the reactor volume V necessary to reduce the entering flow rate of species j, from Fj0, to the exit flow rate Fj, when species j is disappearing at a rate of -rj. • We note that the CSTR is modeled such that the conditions in the exit stream (e.g.. concentration, temperature) are identical to those in the tank. The molar flow rate Fj is just the product of the concentration of species j and the volumetric flow rate u ------------------ eq (1) ------------------ eq (2) Continuous Stirred Tank Reactor The algebraic form of CSTR
- 16. • Consequently. we could combine Equations (1) and ( 2) to write a balance on species A as Continuous Stirred Tank Reactor ------------------ eq (3)
- 17. CSTR Modeling • Recall that the CSTR is modeled as being we11 mixed such that there are no spatial variations in the reactor. • The CSTR mole balance, Equation ( 1), when applied to species A in the reaction can he arranged to We now substitute for FA in terns of FAO and X ------------------ eq (4) ------------------ eq (5) ------------------ eq (6)
- 18. CSTR Modeling (continue. ) • and then substitute Equation (6) into (5) Simplifying, we see the CSTR volume necessary to achieve a specified conversion X is Because the reactor is perfectly mixed. ------------------ eq (7) ------------------ eq (8)
- 19. Example - Sizing a CSTR The reaction described by the data in the table is to be carried out in CSTR. Species A enters the reactor at a molar flow rate of 0.4 moles/ sec. Using the data from table 1, table 2 or Figure 1. calculate the volume necessary to achieve 80% conversion in a CSTR. Figure 1
- 20. Example - Sizing a CSTR Table 1 Processed Data
- 21. Example - Sizing a CSTR Table 2 Processed Data
- 22. Solution - Sizing a CSTR • The following equation gives the volume of a CSTR as a function of FA0, X and –rA. • In a CSTR, the composition, temperature, and conversion of the effluent stream are identical to that of the fluid within the reactor, because perfect mixing is assumed. Therefore, we need to find the value of -rA (or reciprocal thereof) at X = 0.8. • From either Table 2 or Figure 1- , we see that when X = 0.8, then ------------------ eq (9)
- 23. Solution - Sizing a CSTR (continue.) Substituting value in eq (9) for an entering molar flow rate FA0, of 0.4 mol A/s and X = 0.8, we get
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