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Plantwide control: Towards a systematic procedure

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Title: Plantwide control: Towards a systematic procedure


1
Plantwide control Towards a systematic procedure
  • Sigurd Skogestad
  • Department of Chemical Engineering
  • Norwegian University of Science and Tecnology
    (NTNU)
  • Trondheim, Norway
  • PROST årsmøte 11. Juni 2002
  • Based on Plenary Presentation at ESCAPE12,
  • den Haag, May 2002

2
Personal anecdote from Jack Ponton, University of
Edinburgh (1993)
  • Some years ago, when a fairly junior academic,
    he took an industrial sabattical.
  • Having told that he was a teacher of process
    control, he was presented with a process
    flowsheet and asked to put control loops on it.
  • Despite having taught process control including
    differential eqautions, Laplace tranforms, Bode
    diagrams and so on he was at loss even as to
    start the task. And so most have been generations
    before of chemical engineering graduates. And
    this is the control task which process engineers
    in industry are most frequently called upon to
    perform.

3
Idealized view of control(Ph.D. control)
4
Practice I Tennessee Eastman challenge problem
(Downs, 1991)
5
Practice II Typical PID diagram(PID control)
6
Practice III Hierarchical structure
7
  • Alan Foss (Critique of chemical process control
    theory, AIChE Journal,1973)
  • The central issue to be resolved ... is the
    determination of control system structure. Which
    variables should be measured, which inputs should
    be manipulated and which links should be made
    between the two sets?

8
Plantwide control
  • Not the tuning and behavior of each control loop,
  • But rather the control philosophy of the overall
    plant with emphasis on the structural decisions
  • Selection of manipulated variables (inputs)
  • Selection of controlled variables (outputs)
  • Selection of (extra) measurements (extra
    outputs)
  • Selection of control configuration (structure of
    overall controller that interconnects the
    controlled, manipulated and measured variables)
  • Selection of controller type (PID, decoupler, MPC
    etc.).
  • That is All the decisions made before we get to
    Ph.D control

9
Outline
  • Plantwide control procedure
  • Top-down definition of objectives
  • What to control I Primary controlled variables
  • Inventory control - where set production rate
  • Bottom-up assignment of control loops
  • What to control II Secondary controlled
    variables
  • Decentralized versus multivariable control in
    supervisory layer

10
Related work
  • Page Buckley (1964) - Chapter on Overall process
    control (still industrial practice)
  • Alan Foss (1973) - control system structure
  • George Stephanopoulos and Manfred Morari (1980)
  • Bill Luyben and coworkers (1975- ) many
    snowball effect
  • Ruel Shinnar (1981- ) - dominant variables
  • Jim Douglas and Alex Zheng (Umass) (1985- )
  • Jim Downs (1991) - Tennessee Eastman process
  • Larsson and Skogestad (2000) Review of plantwide
    control

11
Stepwise procedure plantwide control
I. TOP-DOWN Step 1. DEFINE OVERALL CONTROL
OBJECTIVE Step 2. DEGREE OF FREEDOM
ANALYSIS Step 3. WHAT TO CONTROL? (primary
variables) Step 4. PRODUCTION
RATE Steady-state considerations No control
knowledge required!
12
II. BOTTOM-UP (structure control system) Step
5. REGULATORY CONTROL LAYER
5.1 Stabilization (including level control)
5.2 Local disturbance rejection (inner
cascades) What more to control? (secondary
variables) Step 6. SUPERVISORY CONTROL LAYER
Decentralized or multivariable control
(MPC)? Pairing? Step 7. OPTIMIZATION LAYER
(RTO)
13
Step 1. Overall control objective
  • What are the operational objectives?
  • Quantify Minimize scalar cost J
  • Usually J economic cost /h
  • Constraints on flows, equipment constraints,
    product specifications, etc.

14
Step 2. Degree of freedom (DOF) analysis
  • Nm no. of dynamic (control) DOFs (valves)
  • Nss Nm- N0 steady-state DOFs
  • N0 liquid levels with no steady-state effect
    (N0y) purely dynamic control DOFs (N0m)

Cost J depends normally only on steady-state DOFs
15
Distillation column with given feed

Nm 5, N0y 2, Nss 5 - 2 3 (2 with
given pressure)
16
Heat exchanger with bypasses
17
Alternatives structures for optimizing control
Step 3 What should we control? (Control theory
has little to offer)
Control theory has a lot to offer
Hierarchical Centralized
18
Step 3. What should we control? (primary
controlled variables)
  • Intuition Dominant variables (Shinnar)
  • Systematic Define cost J and minimize w.r.t.
    DOFs
  • Control active constraints (constant setpoint is
    optimal)
  • Remaining DOFs Control variables c for which
    constant setpoints give small (economic) loss
  • Loss J - Jopt(d)
  • when disturbances d occurs

19
Loss with constant setpoints
20
Application Recycle processJ V (minimize
energy)
5
4
1
Given feedrate F0 and column pressure
2
3
Nm 5 N0y 2 Nss 5 - 2 3
Constraints Mr lt Mrmax, xB gt xBmin 0.98
21
Recycle process Selection of controlled
variables
  • Step 3.1 JV (minimize energy with given feed)
  • Step 3.1 DOFs for optimization Nss 3
  • Step 3.3 Most important disturbance Feedrate F0
  • Step 3.4 Optimization Constraints on max. Mr and
    xB always active
  • Step 3.5 1 DOF left, candidate controlled
    variables F, D, L, xD, ...
  • Step 3.6 Loss with constant setpoints. Good xD,
    L/F. Poor F, D, L

22
Recycle process Loss with constant setpoint, cs
Large loss with c F (Luyben rule)
Negligible loss with c L/F
23
Recycle process Proposed control structurefor
case with J V (minimize energy)
Active constraint Mr Mrmax
Active constraint xB xBmin
24
Self-optimizing control(Skogestad, 2000)
Loss L J - Jopt (d)
Self-optimizing control is achieved when a
constant setpoint policy results in an
acceptable loss L (without the need to reoptimize
when disturbances occur)
25
Effect of implementation error on cost
26
Recycle systems
Do not recommend Luybens rule of fixing a flow
in each recycle loop (even to avoid
snowballing)
27
Good candidate controlled variables c (for
self-optimizing control)
  • Requirements
  • The optimal value of c should be insensitive to
    disturbances
  • c should be easy to measure and control
  • The value of c should be sensitive to changes in
    the steady-state degrees of freedom
  • (Equivalently, J as a function of c should be
    flat)
  • For cases with more than one unconstrained
    degrees of freedom, the selected controlled
    variables should be independent.

Singular value rule (Skogestad and Postlethwaite,
1996) Look for variables that maximize the
minimum singular value of the appropriately
scaled steady-state gain matrix G from u to c
28
Step 4. Where set production rate?
  • Very important!
  • Determines structure of remaining inventory
    (level) control system
  • Set production rate at (dynamic) bottleneck
  • Link between Top-down and Bottom-up parts

29
Production rate set at inlet Inventory control
in direction of flow
30
Production rate set at outletInventory control
opposite flow
31
Production rate set inside process
32
Reactor-recycle processGiven feedrate with
production rate set at inlet
33
Reactor-recycle processReconfiguration required
when reach bottleneck (max. vapor rate in column)
34
Reactor-recycle processGiven feedrate with
production rate set at bottleneck (column)
F0s
35
II. Bottom-up assignment of loops in control layer
  • Identify secondary (extra) controlled variable
  • Determine structure (configuration) of control
    system (pairing)
  • A good control configuration is insensitive to
    parameter changes!
  • Industry most common approach is to copy old
    designs

36
Step 5. Regulatory control layer
  • Purpose Stabilize the plant using local SISO
    PID controllers to enable manual operation (by
    operators)
  • Main structural issues
  • What more should we control? (secondary cvs, y2)
  • Pairing with manipulated variables (mvs)

37
Selection of secondary controlled variables (y2)
  • The variable is easy to measure and control
  • For stabilization Unstable mode is quickly
    detected in the measurement (Tool pole vector
    analysis)
  • For local disturbance rejection The variable is
    located close to an important disturbance
    (Tool partial control analysis).

38
Partial control
39
Step 6. Supervisory control layer
  • Purpose Keep primary controlled outputs cy1 at
    optimal setpoints cs
  • Degrees of freedom Setpoints y2s in reg.control
    layer
  • Main structural issue Decentralized or
    multivariable?

40
Decentralized control(single-loop controllers)
  • Use for Noninteracting process and no change in
    active constraints
  • Tuning may be done on-line
  • No or minimal model requirements
  • Easy to fix and change
  • - Need to determine pairing
  • - Performance loss compared to multivariable
    control
  • - Complicated logic required for reconfiguration
    when active constraints move

41
Multivariable control(with explicit constraint
handling - MPC)
  • Use for Interacting process and changes in
    active constraints
  • Easy handling of feedforward control
  • Easy handling of changing constraints
  • no need for logic
  • smooth transition
  • - Requires multivariable dynamic model
  • - Tuning may be difficult
  • - Less transparent
  • - Everything goes down at the same time

42
Step 7. Optimization layer (RTO)
  • Purpose Identify active constraints and compute
    optimal setpoints (to be implemented by
    supervisory control layer)
  • Main structural issue Do we need RTO? (or is
    process self-optimizing)

43
Conclusion
  • Procedure plantwide control
  • I. Top-down analysis to identify degrees of
    freedom and primary controlled variables (look
    for self-optimizing variables)
  • II. Bottom-up analysis to determine secondary
    controlled variables and structure of control
    system (pairing).

44
More details....
  • Skogestad, S. (2000), Plantwide control -towards
    a systematic procedure, Proc. ESCAPE12
    Symposium, Haag, Netherlands, May 2002.
  • Larsson, T., 2000. Studies on plantwide control,
    Ph.D. Thesis, Norwegian University of Science and
    Technology, Trondheim.
  • Larsson, T. and S. Skogestad, 2000, Plantwide
    control A review and a new design procedure,
    Modeling, Identification and Control, 21,
    209-240.
  • Larsson, T., K. Hestetun, E. Hovland and S.
    Skogestad, 2001, Self-optimizing control of a
    large-scale plant The Tennessee Eastman
    process, Ind.Eng.Chem.Res., 40, 4889-4901.
  • Larsson, T., M.S. Govatsmark, S. Skogestad and
    C.C. Yu, 2002, Control of reactor, separator and
    recycle process, Submitted to Ind.Eng.Chem.Res.
  • Skogestad, S. (2000). Plantwide control The
    search for the self-optimizing control
    structure. J. Proc. Control 10, 487-507.

See also the home page of Sigurd
Skogestad http//www.chembio.ntnu.no/users/skoge/
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