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Mole balance for chemical reaction engineering (Design Equations for reactors)

Mole balance for chemical reaction engineering (Design Equations for reactors). Lec 3 week 3. The General Mole Balance Equation. To perform a mole balance on any system, the system boundaries must first be specified. The volume enclosed by these boundaries is referred to as the system volume.

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Mole balance for chemical reaction engineering (Design Equations for reactors)

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  1. Mole balance for chemical reaction engineering(Design Equations for reactors) Lec 3 week 3

  2. The General Mole Balance Equation • To perform a mole balance on any system, the system boundaries must first be specified. The volume enclosed by these boundaries is referred to as the system volume.

  3. where Nj, represents the number of moles of species j in the system at time t.

  4. The rate of generation of species j is expressed as The product of the reaction term and can be written in more familiar terms, GA = rA V • V is volume of the system. • Note that the units for this relation are consistent: • If GA (and hence rA) varies with position in the system volume, we can take this into account by evaluating this term at several locations. Then DGA1 = rA1 DV1,

  5. Summing the reactions over the entire volume yields: • As (that is, as we decrease the size of these cubes and increase their number) then which gives we now replace G in equation (1) to get :

  6. From this general mole balance equation we can develop the design equations for the various types of industrial reactors: batch, semi-batch. and continuous- flow.

  7. Types of Reactors • Batch • No flow of material in or out of reactor • Changes with time • Fed- Batch (semi batch) • Either an inflow or an outflow of material but not both • Changes with time • Continuous • Flow in and out of reactor • Continuous Stirred Tank Reactor (CSTR) • Plug Flow Reactor (PFR) • Steady State Operation ( no change with time)

  8. General Mole Balance in terms of number of moles

  9. Batch reactor mole balance • Generalized Design Equation for Reactors • No flow into or out of the reactor, then, FA = FA0 = 0 • Good mixing, constant volume

  10. Batch Reactor

  11. Batch Reactor

  12. Fed Batch Reactor • Reactor Design Equation • No outflow FA = 0 • Good Mixing rA dV term out of the integral

  13. Continuous Stirred Tank Reactor CSTR • General Reactor Design Equation • Assume Steady State • Well Mixed • So or

  14. CSTR

  15. Tubular Reactor (Plug Flow Reactor) (PFR) • Tubular Reactor • Pipe through which fluid flows and reacts. • Poor mixing • Difficult to control temperature variations. • An advantage is the simplicity of construction

  16. PFR Design Equation • Design Equation • Examine a small volume element (DV) with length Dy and the same radius as the entire pipe. • If the element is small, then spatial variations in rA are negligible, and Flow of A out of Element Flow of A into Element Assumption of “good mixing” applies only to the small volume element

  17. If volume element is very small, then assume steady state with no changes in the concentration of A. • Simplify design equation to: • rA is a function of position y, down the length of the pipe and reactant concentration • take the limit where the size of a volume element becomes infinitesimally small This is the Design Equation for a PFR

  18. take the limit where the size of a volume element becomes infinitesimally small • or because Dy A = V, • This is the Design Equation for a PFR • Bioapplications - Sometimes hollow fiber reactor analysis is simplified to a PFR

  19. Plug Flow Reactor Mole Balance PFR: The integral form is: This is the volume necessary to reduce the entering molar flow rate (mol/s) from FA0 to the exit molar flow rate of FA.

  20. Packed Bed Reactor PBR The integral form to find the catalyst weight is:

  21. Reactor Mole Balance Summary

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