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CHE 185 – PROCESS CONTROL AND DYNAMICS

CHE 185 – PROCESS CONTROL AND DYNAMICS. DYNAMIC MODELING FUNDAMENTALS. DYNAMIC MODELING. PROCESSES ARE DESIGNED FOR STEADY STATE, BUT ALL EXPERIENCE SOME DYNAMIC BEHAVIOR. THE REASON FOR MODELING THIS B EHAVIOR IS TO DETERMINE HOW THE SYSTEM WILL RESPOND TO CHANGES .

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CHE 185 – PROCESS CONTROL AND DYNAMICS

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  1. CHE 185 – PROCESS CONTROL AND DYNAMICS DYNAMIC MODELING FUNDAMENTALS

  2. DYNAMIC MODELING • PROCESSES ARE DESIGNED FOR STEADY STATE, BUT ALL EXPERIENCE SOME DYNAMIC BEHAVIOR. • THE REASON FOR MODELING THIS BEHAVIOR IS TO DETERMINE HOW THE SYSTEM WILL RESPOND TO CHANGES. • DEFINES THE DYNAMIC PATH • PREDICTS THE SUBSEQUENT STATE

  3. USES FOR DYNAMIC MODELS • EVALUATION OF PROCESS CONTROL SCHEMES • SINGLE LOOPS • INTEGRATED LOOPS • STARTUP/SHUTDOWN PROCEDURES • SAFETY PROCEDURES • BATCH AND SEMI-BATCH OPERATIONS • TRAINING • PROCESS OPTIMIZATION

  4. TYPES OF MODELS • LUMPED PARAMETER MODELS • ASSUME UNIFORM CONDITIONS WITHIN A PROCESS OPERATION • STEADY STATE MODELS USE ALGEBRAIC EQUATIONS FOR SOLUTIONS • DYNAMIC MODELS EMPLOY ORDINARY DIFFERENTIAL EQUATIONS

  5. Lumped Parameter Process Example

  6. TYPES OF MODELS • DISTRIBUTED PARAMETER MODELS • ALLOW FOR GRADIENTS FOR A VARIABLE WITHIN THE PROCESS UNIT • DYNAMIC MODELS USE PARTIAL DIFFERENTIAL EQUATIONS.

  7. Distributed Parameter Process Example

  8. FUNDAMENTAL AND EMPIRICAL MODELS • PROVIDE ANOTHER SET OF CONSTRAINTS • MASS AND ENERGY CONSERVATION RELATIONSHIPS • ACCUMULATION = IN - OUT + GENERATIONS • MASS IN - MASS OUT = ACCUMULATION • {U + KE + PE}IN - {U + KE + PE}OUT + Q - W = {U + KE +PE}ACCUMULATION

  9. FUNDAMENTAL AND EMPIRICAL MODELS • CHEMICAL REACTION EQUATIONS • THERMODYNAMIC RELATIONSHIPS, INCLUDING • EQUATIONS OF STATE • PHASE RELATIONSHIPS SUCH AS VLE EQUATIONS

  10. DEGREE OF FREEDOM ANALYSIS • AS IN THE PREVIOUS COURSES, UNIQUE SOLUTIONS TO MODELS REQUIRE n-EQUATIONS AND n-UNKNOWNS • DEGREES OF FREEDOM, (UNKNOWNS - EQUATIONS) IS • ZERO FOR AN EXACT SPECIFICATION • >ZERO FOR AN UNDERSPECIFIED SYSTEM WHERE THE NUMBER OF SOLUTIONS IS INFINITE • <ZERO FOR AN OVERSPECIFIED SYSTEM – WHERE THERE IS NO SOLUTION

  11. VARIABLE TYPES • DEPENDENT VARIABLES - CALCULATED FROM THE SOLUTION TO THE MODELS • INDEPENDENT VARIABLES - REQUIRE SOME FORM OF SPECIFICATION TO OBTAIN THE SOLUTION AND REPRESENT ADDITIONAL DEGREES OF FREEDOM • PARAMETERS - ARE SYSTEM PROPERTIES OR EQUATION CONSTANTS USED IN THE MODELS.

  12. DYNAMIC MODELS FOR CONTROL SYSTEMS • ACTUATOR MODELS HAVE THE GENERAL FORM: • THE CHANGE IN THE VARIABLE WITH RESPECT TO TIME IS A FUNCTION OF • THE DEVIATION FROM THE SET POINT (VSPEC- V) • AND THE ACTUATOR DYNAMIC TIME CONSTANT τv • THE SYSTEM RESPONSE IS MEASURED BY THE SENSOR SYSTEM THAT HAS INHERENT DYNAMICS

  13. GENERAL MODELING PROCEDURE • FORMULATE THE MODEL • ASSUME THE ACTUATOR BEHAVES AS A FIRST ORDER PROCESS • THE GAIN FOR THE SYSTEM • IS THE RATIO OF THE SIGNAL SENT TO THE ACTUATOR TO THE DEVIATION FROM THE SET POINT • ASSUMED TO BE UNITY SO THE TIME CONSTANT REPRESENTS THE SYSTEM DYNAMIC RESPONSE

  14. EXAMPLE OF Dynamic Model for Actuators • equations assume that the actuator behaves as a first order process • dynamic behavior of the actuator is described by the time constant since the gain is unity

  15. First Order Dynamic Response of an Actuator

  16. EXAMPLE OF Dynamic Model for Sensors • equations assume that the actuator behaves as a first order process • dynamic behavior of the actuator is described by the time constant since the gain is unity • T and L are the actual temperature and level

  17. RESULTS FOR SIMPLE SYSTEM MODEL • SEE EXAMPLE 3.1 • THE PROCESS MODEL FOR A CST THERMAL MIXING TANK WHICH ASSUMES UNIFORM MIXING • RESULTS IN A LINEAR FIRST ORDER DIFFERENTIAL EQUATION FOR THE ENERGY BALANCE • SEE FIGURE 3.5.6 FOR THE COMPARISON OF THE MODEL BASED ON THE PROCESS-ONLY RESPONSE AND THE MODEL WHICH INCLUDES THE SENSOR AND THE ACTUATOR WITH THE PROCESS.

  18. EXAMPLE OF A MODEL APPLICATION FOR A PROCESSRESPONSE • STEP INCREASE IN A CONCENTRATION FOR A STREAM FLOWING INTO A MIXING TANK • GIVEN: A MIX TANK WITH A STEP CHANGE IN THE FEED LINE CONCENTRATION • WANTED: DETERMINE THE TIME REQUIRED FOR THE PROCESS OUTPUT TO REACH 90% OF THE NEW OUTPUT CONCENTRATION, CA

  19. EXAMPLE OF A MODEL APPLICATION FOR A PROCESSRESPONSE • BASIS: F0 = 0.085 m3/min, VT = 2.1 m3, CAinit = 0.925 mole A/m3. AT t = 0. CA0 = 1.85 mole A/m3 AFTER THE STEP CHANGE. • ASSUME CONSTANT DENSITY, CONSTANT FLOW IN, AND A WELL-MIXED VESSEL • SOLUTION (USING THE TANK LIQUID AS THE SYSTEM): • USE OVERALL AND COMPONENT BALANCES • MASS BALANCE OVER Δt: • F0ρΔt - F01ρΔt = (ρV)(t + )t) - (ρV)t

  20. EXAMPLE OF A MODEL APPLICATION FOR A PROCESSRESPONSE • DIVIDING BY Δt AND TAKING THE LIMIT AS Δt → 0 • FOR A CONSTANT TANK LEVEL AND CONSTANT DENSITY, THIS SIMPLIFIES TO:

  21. EXAMPLE OF A MODEL APPLICATION FOR A PROCESSRESPONSE • SIMILARLY, USING A COMPONENT BALANCE ON A: • MWAFCA0Δt - MWAFCAΔt = (MWAVCA)(t + Δt) - (MWAVCA)t • DIVIDING BY Δt AND TAKING THE LIMIT AS Δt → 0

  22. EXAMPLE OF A MODEL APPLICATION FOR A PROCESSRESPONSE • DOF ANALYSIS SHOWS THE INDEPENDENT VARIABLES ARE F0 AND CA0 AND THE TWO PREVIOUS EQUATIONS SO THERE IS AN UNIQUE SOLUTION • SOLUTION FOR THE NON-ZERO EQUATION: LET τ= V/F AND REARRANGE:

  23. EXAMPLE OF A MODEL APPLICATION FOR A PROCESSRESPONSE • THIS EQUATION CAN BE TRANSFORMED INTO A SEPARABLE EQUATION USING AN INTEGRATING FACTOR, IF :

  24. EXAMPLE OF A MODEL APPLICATION FOR A PROCESSRESPONSE • SO THE RESULTING EQUATION BECOMES:

  25. EXAMPLE OF A MODEL APPLICATION FOR A PROCESSRESPONSE • EVALUATION • THE INTEGRATING CONSTANT IS EVALUATED USING THE INITIAL CONDITION CA(t) = CAinit AT t = 0. • FOR THE TIME CONSTANT

  26. EXAMPLE OF A MODEL APPLICATION FOR A PROCESSRESPONSE • THE FINAL EQUATION IN TERMS OF THE DEVIATION BECOMES:

  27. EXAMPLE OF A MODEL APPLICATION FOR A PROCESSRESPONSE • RESULTS OF THE CALCULATION:

  28. EXAMPLE OF A MODEL APPLICATION FOR A PROCESSRESPONSE • CONSIDERING THE ORIGINAL OBJECTIVE, THE DATA CAN BE ANALYZED TO DETERMINE THE TIME REQUIRED TO REACH 90% OF THE CHANGE BY CALCULATING THE CHANGE IN TERMS OF TIME CONSTANTS:

  29. EXAMPLE OF A MODEL APPLICATION FOR A PROCESSRESPONSE • ANALYSIS INDICATES THE TIME WAS BETWEEN 2τAND 3τ.ALTERNATELY, THE EQUATION COULD BE REARRANGED ANDS OLVED FOR t AT 90% CHANGE: • CA= CAinit + 0.9(CA0 - CAinit) OR:

  30. EXAMPLE OF A MODEL APPLICATION FOR A PROCESSRESPONSE • OTHER FACTORS THAT COULD AFFECT THE RESULTS OF THIS TYPE OF ANALYSIS ARE: • THE ACCURACY OF THE CONTROL ON THE FLOWS AND VOLUME OF THE TANK • THE ACCURACY OF THE CONCENTRATION MEASUREMENTS • THE ACTUAL RATE OF THE STEP CHANGE

  31. SENSOR NOISE • THE VARIATION IN A MEASUREMENT RESULTING FROM THE SENSOR AND NOT FROM THE ACTUAL CHANGES • CAUSED BY MANY MECHANICAL OR ELECTRICAL FLUCTUATIONS • IS INCLUDED IN THE MODEL FOR ACCURATE DYNAMICS

  32. PROCEDURE TO EVALUATE NOISE • (SECTION 3.6) DETERMINE REPEATABILITY σ= STD. DEV. • GENERATE A RANDOM NUMBER (APPENDIX C) • USE THE RANDOM NUMBER TO REPRESENT THE NOISE IN THE MEASUREMENT • ADD THIS TO THE NOISE-FREE MEASUREMENT TO GET AN APPROXIMATION OF THE ACTUAL RANGE

  33. NUMERICAL INTEGRATION OF ODE’s • METHODS CAN BE USED WHEN CONVENIENT ANALYTICAL SOLUTIONS DO NOT EXIST • ACCURACY AND STABILITY OF SOLUTIONS • REDUCING STEP SIZE FOR NUMERICAL • INTEGRATION CAN IMPROVE ACCURACY AND STABILITY • INCREASING THE NUMBER OF TERMS IN EIGENFUNCTIONS CAN INCREASE ACCURACY • EXPLICIT METHODS APPLIED ARE NORMALLY THE EULER METHOD OR THE RUNGE-KUTTA METHOD

  34. NUMERICAL INTEGRATION OF ODE’s • EULER METHOD

  35. NUMERICAL INTEGRATION OF ODE’s • RUNGE-KUTTA METHOD

  36. NUMERICAL INTEGRATION OF ODE’s • IMPLICIT METHODS OVERCOME STABILITYU LIMITS ON Δt BUT ARE USUALLY MORE DIFFICULT TO APPLY • IMPLICIT TECHNIQUES INCLUDE THE TRAPEZOIDAL METHOD IS THE MOST FLEXIBLE AND IS EFFECTIVE • THERE ARE MANY MORE METHODS AVAILABLE, BUT THESE WILL COVER A LARGE NUMBER OF CASES.

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