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Integration of Design & Control

Integration of Design & Control. CHEN 4470 – Process Design Practice Dr. Mario Richard Eden Department of Chemical Engineering Auburn University Lecture No. 16 – Integration of Design and Control II March 7, 2013 Contains Material Developed by Dr. Daniel R. Lewin, Technion, Israel.

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Integration of Design & Control

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  1. Integration of Design & Control CHEN 4470 – Process Design Practice Dr. Mario Richard EdenDepartment of Chemical EngineeringAuburn University Lecture No. 16 – Integration of Design and Control II March 7, 2013 Contains Material Developed by Dr. Daniel R. Lewin, Technion, Israel

  2. Plantwide Control Design • Luyben et al. (1999) suggest a method for the conceptual design of plant-wide control systems, which consists of the following steps: • Step 1:Establish the control objectives. • Step 2: Determine the control degrees of freedom. Simply stated – the number of control valves – with additions if necessary. • Step 3: Establish the energy management system. Regulation of exothermic or endothermic reactors, and placement of controllers to attenuate temperature disturbances. • Step 4: Set the production rate. • Step 5:Control the product quality and handle safety, environmental, and operational constraints.

  3. Plantwide Control Design • Step 6:Fix a flow rate in every recycle loop and control vapor and liquid inventories (vessel pressures and levels). • Step 7:Check component balances. Establish control to prevent the accumulation of individual chemical species in the process. • Step 8:Control the individual process units. Use remaining DOFs to improve local control, but only after resolving more important plant-wide issues. • Step 9:Optimize economics and improve dynamic controllability. Add nice-to-have options with any remaining DOFs.

  4. Select V-7 for On-demand product flow Select V-1 for fixed feed Example 2: Acyclic Process • Steps 1 & 2:Establish the control objectives and DOFs: • Maintain a constant production rate • Achieve constant composition in the liquid effluent from flash drum • Keep the conversion of the plant at its highest permissible value.

  5. Example 2: Acyclic Process • Step 3:Establish energy management system: • Need to control reactor temperature: Use V-2 • Need to control reactor feed temperature: Use V-3

  6. Example 2: Acyclic Process • Step 4:Set the production rate: • For on-demand product: Use V-7

  7. Example 2: Acyclic Process • Step 5:Control product quality, and meet safety, environmental, and operational constraints: • To regulate V-100 pressure: Use V-5 • To regulate V-100 temperature: Use V-6

  8. Example 2: Acyclic Process • Step 6:Fix recycle flow rates and vapor and liquid inventories : • Need to control vapor inventory in V-100: Use V-5 (already installed) • Need to control liquid inventory in V-100: Use V-4 • Need to control liquid inventory in R-100: Use V-1

  9. Example 2: Acyclic Process • Step 7:Check component balances • Step 8:Control the individual process units • Step 9:Optimization N/A: Neither A or B can build up N/A: All control valves in use • Install composition controller, cascaded with TC of reactor

  10. Select V-1 for fixed feed Example 2: Acyclic Process • Differences:Only step 6 is different • The liquid levels in R-100 and V-100 are now controlled in the direction of the process flow, where before they were controlled in the reverse direction.

  11. Example 2: Acyclic Process

  12. Example 3: Cyclic Process • This control structure for fixed feed has an inherent problem. • Can you see what it is?

  13. Example 3: Cyclic Process F0 D F0 + B B B

  14. Rearranging: • Balance on A for perfect separation: Example 3: Cyclic Process • Molar balance on CSTR: • Substitute:

  15. e.g., suppose knT = 200: • “Snowball” effect F0 B 50 16.7 A more general result uses the dimensionless, Damköhlernumber: Da = knT/F0giving: 75 45 100 100 125 208 • “Snowball” effect for Da1 150 450 Example 3: Cyclic Process

  16. Example 3: Cyclic Process • Steps 1 & 2:Establish the control objectives and DOFs: • Maintain the production rate at a specified level • Keep the conversion of the plant at its highest permissible value.

  17. Example 3: Cyclic Process • Step 3:Establish energy management system: • Need to control reactor temperature: Use V-2

  18. Example 3: Cyclic Process • Step 4:Set the production rate: • For on-demand product: Use V-1

  19. Example 3: Cyclic Process • Step 5:Control product quality, and meet safety, environmental, and operational constraints: • To regulate V-100 pressure: Use V-4 • To regulate V-100 temperature: Use V-5

  20. Example 3: Cyclic Process • Step 6:Fix recycle flow rates and vapor and liquid inventories : • Need to control recycle flow rate: Use V-6 • Need to control vapor inventory in V-100: Use V-4 (already installed) • Need to control liquid inventory in V-100: Use V-3 • Need to control liquid inventory in R-100: Cascade to FC on V-1

  21. Example 3: Cyclic Process • Step 7, 8 and 9:Improvements • Install composition controller, cascaded with TC of reactor

  22. Summary Part I: Previous Lecture • Provided motivation for handling flowsheet controllability and resiliency as an integral part of the design process • Outlined qualitative approach for unit by unit control structure selection Part II – This Lecture • Outlined a qualitative approach for plantwide control structure selection

  23. Other Business • Next Lecture – March 19 • Equipment sizing and pinch analysis • Q&A Session with Consultant – March 21 • Bob Kline will participate via videoconference • Questions can be sent to Bob and/or me ahead of time

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