EI2356 PROCESS CONTROL SYSTEM LAB SYLLABUS | ANNA UNIVERSITY BE E&I 6TH SEMESTER SYLLABUS REGULATION 2008 2011 2012-2013 BELOW IS THE ANNA UNIVERSITY SIXTH SEMESTER B.E ELECTRONICS AND INSTRUMENTATION ENGINEERING DEPARTMENT SYLLABUS, TEXTBOOKS, REFERENCE BOOKS,EXAM PORTIONS,QUESTION BANK,PREVIOUS YEAR QUESTION PAPERS,MODEL QUESTION PAPERS, CLASS NOTES, IMPORTANT 2 MARKS, 8 MARKS, 16 MARKS TOPICS. IT IS APPLICABLE FOR ALL STUDENTS ADMITTED IN THE YEAR 2011 2012-2013 (ANNA UNIVERSITY CHENNAI,TRICHY,MADURAI, TIRUNELVELI,COIMBATORE), 2008 REGULATION OF ANNA UNIVERSITY CHENNAI AND STUDENTS ADMITTED IN ANNA UNIVERSITY CHENNAI DURING 2009
EI2356 PROCESS CONTROL SYSTEM LABORATORY L T P C
0 0 3 2
OBJECTIVE
To experimentally verify the process control concepts on the selected process control loops.
1. Operation of interacting and non-interacting systems
2. Responses of different order processes with and without transportation lag
3. Response of on-off controller
4. Response of P+I+D controller
5. Characteristics of control valve with and without positioner
6. Operation of on-off controlled thermal process
7. Closed loop response of flow control loop
8. Closed loop response of level control loop
9. Closed loop response of temperature control loop
10. Closed loop response of pressure control loop
11. Tuning of controllers
12. Study of complex control system (ratio / cascade / feed forward)
TOTAL = 45 PERIODS
1. STUDY OF INTERACTING AND NON- INTERACTING SYSTEMS
AIM
To study the operation of interacting and non- interacting systems
EXERCISE
1. Connect the two tank system (Level process) in series (as non- interacting system)
2. Check whether level in tank is affected due to changes made in the second tank.
3. Connect the two tank system in series (as interfacing as system).
4. Check whether level in tank 1 is affected due to changes made in the second tank.
5. Determine the transfer function of individual and overall system.
85
EQUIPMENT
1. Two tank system with provision for making them as interfacing and non- interfacing.
– 1 No
2. Level transmitters – 1 No
3. Recorder – 1 No
2. RESPONSE OF DIFFERENT ORDER PROCESSES WITH AND WITHOUT
TRANSPORTATION DELAY
AIM
To determine the transient response of a first order process with and without transportation
delay and second order process with and without transportation delay to step change in
input.
EXERCISE
1. Record the transient response to a step change of first order process and second order
process (Level or thermal (or) any process) with and without transportation lag.
2.Calculate the process gain, time constant and dead time of the process from the step
response.
EQUIPMENT
1. Two tank system with provision for transportation delay (Non – interacting process)
2. Level transmitter – 1 No
3. Recorder – 1 No
3. RESPONSE OF P+I+D CONTROLLER
AIM
To investigate the operation of an electronic controllers with P, P+I and
P+I+D action.
EXERCISE
1. Plot the response of P, P+I, P+D and P+I+D controllers to step and ramp inputs.
2. Determine
3. the calibration of the proportional, Integral and derivative adjustments.
EQUIPMENT
1. Electronic PID controller – 1 No
2. Source for generating step and ramp inputs – 1 No
3. Recorder – 1 No
4. Digital Multimeter – 1 No
4. CHARACTERISTICS OF CONTROL VALVE WITH AND WITHOUT VALVE POSITIONER
AIM
To determine the flow – lift characteristics (Internet / Installed) of a control valve equipped
with and without valve positioner.
EXERCISE
1. Plot the flow – lift characteristics of the given valve without positioner keeping
(i) Constant ΔP
(ii) Variable ΔP
2. Compute the valve gain at different operating points.
3. Plot the flow – lift characteristics of the given with positioner keeping.
86
i. Constant ΔP
ii. Variable ΔP
4. Compute the valve gain at different operating points.
EQUIPMENT
1. Control valve trainer (with position for varying ΔP across the valve) - 1 No
2. Flowmeter - 1No
5. CLOSED LOOP RESPONSE OF FLOW CONTROL LOOP
AIM
To obtain the closed loop response of flow control loop for servo and regulator Operation.
EXERCISE
1. Closed – loop connection is made in the flow process station.
2. The flow controller (P+I) is tuned using any one of the tuning techniques.
3. The response of the control loop is obtained for changes in the set point.
4. The response of the control loop is obtained for changes in the load variable.
5. The step 3 and 4 are repeated for different controller modes and settings.
EQUIPMENT
1. Flow process station with all accessories - 1 No
2. Analog / Digital PID controller - 1 No
3. Recorder - 1 No
6. CLOSED LOOP RESPONSE OF LEVEL CONTROL LOOP
AIM
To obtain the closed loop response of level control loop for servo and regulator operation.
EXERCISE
1. Closed loop connection is made in the level process station.
2. The level controller (P+I) is tuned using any one of the tuning techniques.
3. The response of the control loop is obtained for changes in the set point.
4. The response of the control loop is obtained for changes in the load variable.
5. The step 3 and step 4 are repeated for different controller modes and settings.
EQUIPMENT
1. Level process station with all accessories - 1 No
2. Analog / Digital PID controller - 1 No
4. Recorder - 1 No
7. CLOSED LOOP RESPONSE OF TEMPERATURE CONTROL LOOP
AIM
To obtain the closed loop response of temperature control loop for servo and regulator
operation.
EXERCISE
1. Closed-loop connection is made in the temperature process station.
2. The temperature controller (P+I+D) is tuned using any one of the tuning techniques.
3. The response of the control loop is obtained for changes in the set point.
4. The response of the control loop is obtained for changes in the load variable.
5. The step 3 and 4 are repeated for different controller modes and settings.
87
EQUIPMENT
1. Temperature process station with all accessories - 1 No
2. Analog / Digital PID controller - 1 No
3. Recorder - 1 No
8. CLOSED LOOP RESPONSE OF PRESSURE CONTROL LOOP
AIM
To obtain the closed loop response of pressure control loop for servo and regulator
operation.
EXERCISE
1. Closed – loop connection is made in the pressure process station.
2. The pressure controller (P+I) is tuned using any one of the tuning techniques.
3. The response of the control loop is obtained for changes in the set point.
4. The response of the control loop is obtained for changes in the load variable.
5. The step 3 and 4 are repeated for different controller modes and settings.
6.
EQUIPMENT
1. Pressure process station with all accessories - 1 No
2. Analog / Digital PID controller - 1 No
3. Recorder - 1 No
9. TUNING OF PID CONTROLLER
AIM
To determine the controller settings of a given process using two popular tuning techniques.
EXERCISE
1. Plot the process reaction curve for the given process (higher order process)
2. From the reaction curve, calculate the process gain, time constant and dead time using
the above process parameters calculate the Kc, Ti, Td valves using the appropriate
thumb rules.
3. Conduct the closed loop test as per Z-N method [continuous cycling method] and
determine the ultimate gain (Ku) and ultimate period (Pu), calculate the controller
parameters (Kc, Ti, Td) using Ziegler Nichol’s closed loop tuning approach.
EQUIPMENT
1. Process control trainer / real time process (level / thermal process) - 1 No
2. Recorder - 1 No
3. PID controller - 1 No
10. RESPONSE OF CASCADE CONTROL SYSTEM
AIM
To determine the closed loop performance of a cascade control system and
compare it with that of conventional control system.
EXERCISE
1. The secondary and primary controllers are tuned using any one of the tuning
techniques.
2. Obtain the closed loop response of cascade control system with the load variable
entering the inner loop.
3. Obtain the closed loop regulating response with conventional control system.
88
4. Compare the performance of conventional control system and cascade control
system internal of peak overshoot, setting time, I&E etc
EQUIPMENT
1. Cascade control system with flow as inner variable and liquid level as outer variable with
following accessories.
2. Level transmitter - 1 No
3. Flow transmitter - 1 No
4. Control valve - 1 No
5. Analog / Digital PID controller - 1 No
6. Recorder - 1 No
EI2356 PROCESS CONTROL SYSTEM LABORATORY L T P C
0 0 3 2
OBJECTIVE
To experimentally verify the process control concepts on the selected process control loops.
1. Operation of interacting and non-interacting systems
2. Responses of different order processes with and without transportation lag
3. Response of on-off controller
4. Response of P+I+D controller
5. Characteristics of control valve with and without positioner
6. Operation of on-off controlled thermal process
7. Closed loop response of flow control loop
8. Closed loop response of level control loop
9. Closed loop response of temperature control loop
10. Closed loop response of pressure control loop
11. Tuning of controllers
12. Study of complex control system (ratio / cascade / feed forward)
TOTAL = 45 PERIODS
1. STUDY OF INTERACTING AND NON- INTERACTING SYSTEMS
AIM
To study the operation of interacting and non- interacting systems
EXERCISE
1. Connect the two tank system (Level process) in series (as non- interacting system)
2. Check whether level in tank is affected due to changes made in the second tank.
3. Connect the two tank system in series (as interfacing as system).
4. Check whether level in tank 1 is affected due to changes made in the second tank.
5. Determine the transfer function of individual and overall system.
85
EQUIPMENT
1. Two tank system with provision for making them as interfacing and non- interfacing.
– 1 No
2. Level transmitters – 1 No
3. Recorder – 1 No
2. RESPONSE OF DIFFERENT ORDER PROCESSES WITH AND WITHOUT
TRANSPORTATION DELAY
AIM
To determine the transient response of a first order process with and without transportation
delay and second order process with and without transportation delay to step change in
input.
EXERCISE
1. Record the transient response to a step change of first order process and second order
process (Level or thermal (or) any process) with and without transportation lag.
2.Calculate the process gain, time constant and dead time of the process from the step
response.
EQUIPMENT
1. Two tank system with provision for transportation delay (Non – interacting process)
2. Level transmitter – 1 No
3. Recorder – 1 No
3. RESPONSE OF P+I+D CONTROLLER
AIM
To investigate the operation of an electronic controllers with P, P+I and
P+I+D action.
EXERCISE
1. Plot the response of P, P+I, P+D and P+I+D controllers to step and ramp inputs.
2. Determine
3. the calibration of the proportional, Integral and derivative adjustments.
EQUIPMENT
1. Electronic PID controller – 1 No
2. Source for generating step and ramp inputs – 1 No
3. Recorder – 1 No
4. Digital Multimeter – 1 No
4. CHARACTERISTICS OF CONTROL VALVE WITH AND WITHOUT VALVE POSITIONER
AIM
To determine the flow – lift characteristics (Internet / Installed) of a control valve equipped
with and without valve positioner.
EXERCISE
1. Plot the flow – lift characteristics of the given valve without positioner keeping
(i) Constant ΔP
(ii) Variable ΔP
2. Compute the valve gain at different operating points.
3. Plot the flow – lift characteristics of the given with positioner keeping.
86
i. Constant ΔP
ii. Variable ΔP
4. Compute the valve gain at different operating points.
EQUIPMENT
1. Control valve trainer (with position for varying ΔP across the valve) - 1 No
2. Flowmeter - 1No
5. CLOSED LOOP RESPONSE OF FLOW CONTROL LOOP
AIM
To obtain the closed loop response of flow control loop for servo and regulator Operation.
EXERCISE
1. Closed – loop connection is made in the flow process station.
2. The flow controller (P+I) is tuned using any one of the tuning techniques.
3. The response of the control loop is obtained for changes in the set point.
4. The response of the control loop is obtained for changes in the load variable.
5. The step 3 and 4 are repeated for different controller modes and settings.
EQUIPMENT
1. Flow process station with all accessories - 1 No
2. Analog / Digital PID controller - 1 No
3. Recorder - 1 No
6. CLOSED LOOP RESPONSE OF LEVEL CONTROL LOOP
AIM
To obtain the closed loop response of level control loop for servo and regulator operation.
EXERCISE
1. Closed loop connection is made in the level process station.
2. The level controller (P+I) is tuned using any one of the tuning techniques.
3. The response of the control loop is obtained for changes in the set point.
4. The response of the control loop is obtained for changes in the load variable.
5. The step 3 and step 4 are repeated for different controller modes and settings.
EQUIPMENT
1. Level process station with all accessories - 1 No
2. Analog / Digital PID controller - 1 No
4. Recorder - 1 No
7. CLOSED LOOP RESPONSE OF TEMPERATURE CONTROL LOOP
AIM
To obtain the closed loop response of temperature control loop for servo and regulator
operation.
EXERCISE
1. Closed-loop connection is made in the temperature process station.
2. The temperature controller (P+I+D) is tuned using any one of the tuning techniques.
3. The response of the control loop is obtained for changes in the set point.
4. The response of the control loop is obtained for changes in the load variable.
5. The step 3 and 4 are repeated for different controller modes and settings.
87
EQUIPMENT
1. Temperature process station with all accessories - 1 No
2. Analog / Digital PID controller - 1 No
3. Recorder - 1 No
8. CLOSED LOOP RESPONSE OF PRESSURE CONTROL LOOP
AIM
To obtain the closed loop response of pressure control loop for servo and regulator
operation.
EXERCISE
1. Closed – loop connection is made in the pressure process station.
2. The pressure controller (P+I) is tuned using any one of the tuning techniques.
3. The response of the control loop is obtained for changes in the set point.
4. The response of the control loop is obtained for changes in the load variable.
5. The step 3 and 4 are repeated for different controller modes and settings.
6.
EQUIPMENT
1. Pressure process station with all accessories - 1 No
2. Analog / Digital PID controller - 1 No
3. Recorder - 1 No
9. TUNING OF PID CONTROLLER
AIM
To determine the controller settings of a given process using two popular tuning techniques.
EXERCISE
1. Plot the process reaction curve for the given process (higher order process)
2. From the reaction curve, calculate the process gain, time constant and dead time using
the above process parameters calculate the Kc, Ti, Td valves using the appropriate
thumb rules.
3. Conduct the closed loop test as per Z-N method [continuous cycling method] and
determine the ultimate gain (Ku) and ultimate period (Pu), calculate the controller
parameters (Kc, Ti, Td) using Ziegler Nichol’s closed loop tuning approach.
EQUIPMENT
1. Process control trainer / real time process (level / thermal process) - 1 No
2. Recorder - 1 No
3. PID controller - 1 No
10. RESPONSE OF CASCADE CONTROL SYSTEM
AIM
To determine the closed loop performance of a cascade control system and
compare it with that of conventional control system.
EXERCISE
1. The secondary and primary controllers are tuned using any one of the tuning
techniques.
2. Obtain the closed loop response of cascade control system with the load variable
entering the inner loop.
3. Obtain the closed loop regulating response with conventional control system.
88
4. Compare the performance of conventional control system and cascade control
system internal of peak overshoot, setting time, I&E etc
EQUIPMENT
1. Cascade control system with flow as inner variable and liquid level as outer variable with
following accessories.
2. Level transmitter - 1 No
3. Flow transmitter - 1 No
4. Control valve - 1 No
5. Analog / Digital PID controller - 1 No
6. Recorder - 1 No
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