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Attainable Region

Attainable Region. S,S&L Chapt. 6. Attainable Region. Graphical method that is used to determine the entire space feasible concentrations Useful for identifying reactor configurations that will yield the optimal products. Procedure.

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Attainable Region

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  1. Attainable Region S,S&L Chapt. 6

  2. Attainable Region • Graphical method that is used to determine the entire space feasible concentrations • Useful for identifying reactor configurations that will yield the optimal products

  3. Procedure Step 1: Construct a trajectory for a PFR from the feed point, continuing to complete conversion or chemical equilibrium Step 2: When the PFR bounds a convex region, this constitutes a candidate AR. The procedure terminates if the rate vectors outside the candidate AR do not point back into it. Step 3: The PFR trajectory is expanded by linear arcs, representing mixing between the PFR effluent and the feed stream, extending the candidate AR. Step 4: Construct a CSTR trajectory to see if the AR can be extended. Place linear arcs, which represent mixing, on the CSTR trajectory to ensure the trajectory remains convex. Step 5: A PFR trajectory is drawn from the position where the mixing line meets the CSTR trajectory. If the PFR trajectory is convex, it extends the previous AR to form a expanded AR. Then return to step 2. Otherwise, repeat the procedure from Step 3.

  4. Example Reactions Rate Equations

  5. Step 1 Begin by constructing a trajectory for a PFR from the feed point, continuing to the complete conversion of A or chemical equilibrium • Solve the PFR design equations numerically • Use the feed conditions as initial conditions to the o.d.e. • Adjust integration range, t (residence time), until complete conversion or to equilibrium

  6. PFR Design Equations

  7. Solve Numerically

  8. Solve Numerically

  9. Step 2 Plot the PFR trajectory from the previous results. Check to see if rate vectors outside AR point back into it (e.g. Look for non-convex regions on the curve)

  10. Step 3 Expand the AR as much as possible with straight arcs that represent mixing of reactor effluent and feed stream

  11. Interpreting points on mixing line Desired operating point (1-a) PFR CA=0. 2187 CB=0.00011 CA=0.72 CB=0.0004 a CA=1 CB=0

  12. Mixing of StreamsReactant Bypass α =fraction of mixture of stream 1in the mixed stream Feed mixing fraction: a = 0. 64

  13. Step 4 If a mixing arc extends the attainable region on a PFR trajectory, check to see if a CSTR trajectory can extend the attainable region For CSTR trajectories that extend the attainable region, add mixing arcs to concave regions to ensure the attainable region remains convex • Solve CSTR multiple NLE numerically • Vary t until all feed is consumed or equilibrium is reached

  14. CSTR Design Equations

  15. Solve numerically at various t until complete conversion or equilibrium is achieved

  16. Plot extensions to attainable region i.c. for step 5

  17. Step 5 A PFR trajectory is drawn from the position where the mixing line meets the CSTR trajectory. If this PFR trajectory is convex, it extends the previous AR to form an expanded candidate AR. Then return to Step 2. Otherwise repeat Step 3

  18. Solve PFR equations with modified initial conditions Vary integration range New feed point

  19. Attainable Region

  20. Keep track of feed points • Initial feed point occurs at far right on AR • Mixing lines connect two feed points • Connect reactors and mixers with feed points to get network

  21. Reactor configuration for highest selectivity CA=1 CB=0 CSTR PFR CA=0.185 CB=0.000124 CA=0.38 CB=0.0001 Reactor series occur when multiple feed points exist

  22. Go back to calculations for optimal reactor sizing

  23. Other factors to consider • Annualized, operating, and capital costs might favor designs that don’t give the highest selectivity • If objective function (e.g. $ = f{CA} + f{CB}) can be expressed in terms of the axis variable, a family of objective contours can be plotted on top of the AR • The point where a contour becomes tangent to the AR is the optimum • Temperature effects • Changing temperature will change the AR • Need energy balance for non-isothermal reactions • Make sure to keep track of temperature

  24. Profit ($) = 15000*CB-15*CA2 Optimal point not at highest selectivity

  25. Conclusions • Need to know feed conditions • AR graphical method is 2-D and limited to 2 independent species • Systems with rate expressions involving more than 2 species need to be reduced • Atom balances are used to reduce independent species • Independent species = #molecular species - #atomic species • If independent species < 2, AR can be used by Principle of Reaction Invariants

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