Process Control Lab Manual
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Transcript of Process Control Lab Manual
JAGANNATH INSTITUTE FOR TECHNOLOGY AND
MANAGEMENT
PROCESS CONTROL LAB MANUAL
J A G A N N A T H I N S T I T U T E F O R T E C H N O L O G Y A N D M A N A G E M E N TA L L U R I N A G A R , P A R A L A K H E M U N D I
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Content 1. To study the V-I Characteristic of SCR using PEC16M1A.
2. To study the V-I Characteristics of TRIAC by using PEC16M1A
3. To study the V-I Characteristics of DIAC by using PEC16M1A
4. To study the open loop response of a simple process.
5. To study the closed response of a simple process.
6. To observe the time response of the closed loop second order process with the proportional
control.
7. To study the time response of P+I controller.
8. To study the response of P+I+D controller in a process.
9. To study the action of ON/ OFF control of a temperature control system using VTCS-02
10. To study the action of proportional control on a temperature control system using VTCS-02
11. To study the action of PID controller on a temperature control system using VTCS-02
12. To study the opening v/s flow characteristics of the control valve.
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EXPERIMENT:-1 Aim of the Experiment:
To study the V-I Characteristic of SCR using PEC16M1A.
Apparatus Required:
1. PEC16M1A Trainer
2. Ammeter (0-200mA) MC – 2Nos.
3. Voltmeter (0-30V) MC.
4. Patch chords
Theory:
An SCR is a type of rectifier, controlled by a logic gate signal. It is a four-layer, three-terminal device. A
p-type layer acts as an anode and an n-type layer as a cathode; the p-type layer closer to the n-type
(cathode) acts as a gate.
In the normal "off" state, the device restricts current to the leakage current. When the gate to cathode
voltage exceeds a certain threshold, the device turns "on" and conducts current. The device will remain
in the "on" state even after gate current is removed so long as current through the device remains above
the holding current. Once current falls below the holding current for an appropriate period of time, the
device will switch "OFF".
If the applied voltage increases rapidly enough, capacitive coupling may induce enough charge into the
gate to trigger the device into the "on" state; this is referred to as "dv/dt triggering." This is usually
prevented by limiting the rate of voltage rise across the device, perhaps by using a snubber. "dv/dt
triggering" may not switch the SCR into full conduction rapidly and the partially-triggered SCR may
dissipate more power than is usual, possibly harming the device.
SCRs can also be triggered by increasing the forward voltage beyond their rated breakdown voltage
(also called as break over voltage), but again, this does not rapidly switch the entire device into
conduction and so may be harmful so this mode of operation is also usually avoided. Also, the actual
breakdown voltage may be substantially higher than the rated breakdown voltage, so the exact trigger
point will vary from device to device.
SCRs are made with voltage ratings of up to 7500 volts, and with current ratings up to 3000 RMS
amperes per device. Some of the larger ones can take over 50 kA in single-pulse operation. SCRs are
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used in power switching, phase control, chopper, battery chargers, and inverter circuits. Industrially they
are applied to produce variable DC voltages for motors (from a few to several thousand HP) from AC
line voltage. They control the bulk of the dimmers used in stage lighting, and can also be used in some
electric vehicles to modulate the working voltage in a Jacobson circuit. Another common application is
phase control circuits used with inductive loads. SCRs can also be found in welding power supplies
where they are used to maintain a constant output current or voltage. Large silicon-controlled rectifer
assemblies with many individual devices connected in series are used in high-voltage DC converter
stations.
Two SCRs in "inverse parallel" are often used in place of a TRIAC for switching inductive loads on AC
circuits. Because each SCR only conducts for half of the power cycle and is reverse-biased for the other
half-cycle, turn-off of the SCRs is assured. By comparison, the TRIAC is capable of conducting current
in both directions and assuring that it switches "off" during the brief zero-crossing of current can be
difficult.
Typical electrostatic discharge (ESD) protection structures in integrated circuits produce a parasitic
SCR. This SCR is undesired; if by accident it is triggered, then the IC will go into latchup and may be
destroyed.
Circuit Diagram:
Connection Procedure:
Connect the SCR anode, cathode, gate terminal to SCR Characteristic circuit
Connect the ammeter in anode terminal as indicated in the connection diagram
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Connect the ammeter is gate terminal
Connect the voltmeter to across of anode and cathode terminal
Experimental Procedure:
1. Switch on the 230V AC Supply.
2. Now vary the pot3 and set the gate current (IG) in the range of 4mA to 5mA.
3. Now slowly increase the anode-cathode voltage (VAK) by varying the pot4 till the Thyristor get
turned on, note down the ammeter (IA), Voltmeter (VAK) readings.
4. For various gate current take the reading and Tabulate in Table 1.
5. Plot the graph VAK Vs IA in a graph sheet.
6. After note down the max anode current remove the gate current by switch OFF the switch S1.
7. Now reduce the anode voltage (VAK) gradually, at on stage the node current will suddenly reach
zero value. The current at this stage is holding current (IH).
8. Now switch ON the switch S1 and vary the anode cathode voltage (VAK) slightly, now again
switch OFF the switch S1.
If the anode current shows zero value again switch ON S1 and vary the anode cathode
voltage.
If the anode current shows some value , i.e., the latching current of SCR.
Tabulation:
Sl.No. IG = IG =
VAK IA VAK IA
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Model Graph:
Result:
Thus the V-I characteristic of
SCR were drawn and note down the following values from the graph sheet.
1. Latching current (IL) = -------------------------
2. Holding current (IH) = -------------------------
3. Gate Current (IG) = -------------------------
4. Break over Voltage (VAK) = -------------------------
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EXPERIMENT:-2 Aim of the Experiment:
To study the V-I Characteristics of TRIAC by using PEC16M1A
Apparatus Required:
5. PEC16M1A Trainer
6. Ammeter (0-200mA) MC – 2Nos.
7. Voltmeter (0-30V) MC.
8. Patch chords
Theory:
A TRIAC, or Triode for Alternating Current is an electronic component approximately equivalent to two
silicon-controlled rectifiers (SCRs/thyristors) joined in inverse parallel (paralleled but with the polarity
reversed) and with their gates connected together. Formal name for a TRIAC is bidirectional triode
thyristor. This results in a bidirectional electronic switch which can conduct current in either direction
when it is triggered (turned on). It can be triggered by either a positive or a negative voltage being
applied to its gate electrode (with respect to A1, otherwise known as MT1). Once triggered, the device
continues to conduct until the current through it drops below a certain threshold value, such as at the end
of a half-cycle of alternating current (AC) mains power. This makes the TRIAC a very convenient
switch for AC circuits, allowing the control of very large power flows with milliampere-scale control
currents. In addition, applying a trigger pulse at a controllable point in an AC cycle allows one to control
the percentage of current that flows through the TRIAC to the load (so-called phase control).
Low power TRIACs are used in many applications such as light dimmers, speed controls for electric
fans and other electric motors, and in the modern computerized control circuits of many household small
and major appliances. However, when used with inductive loads such as electric fans, care must be
taken to assure that the TRIAC will turn off correctly at the end of each half-cycle of the ac power.
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Circuit Diagram:
Connection Procedure:
Connect the MT2 terminal of TRIAC is positive w.r.t. MT1 and gate current also positive.
Connect the ammeter in anode terminal as indicated in the connection diagram.
Connect the ammeter is gate terminal as indicated in the connection diagram.
Connect the voltmeter in between TRIAC MT1 and MT2.
Experimental Procedure:
1. Now switch on the 230V AC Supply.
2. Now vary the pot3 and set the gate current IG.
3. Now slowly increase the MT1 and MT2 voltage by varying the pot4 till the TRIAC is turned on
and note the voltage (VMT1) , current (IF) readings as shown in table.
4. Now measure the break over voltage VBO1.
5. Further increase MT1 - MT2 voltage and note the current IA .
6. Plot the VF Vs IF in a graph sheet.
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Tabulation:
Sl.No. IG = IG =
VMT1 IA VMT1 IF
Model Graph:
Result:
Thus the V-I Characteristics of TRIAC were studied and notedown the following values from the graph
sheet.
Latching Current (IL) = ________________________
Holding Current (IH) = ________________________
Gate Current (IG) = ________________________
Break Over Voltage (VAK) = ________________________
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EXPERIMENT:-3 Aim of the Experiment:
To study the V-I Characteristics of DIAC by using PEC16M1A
Apparatus Required:
1. PEC16M1A Trainer
2. Ammeter (0-200mA) MC – 2Nos.
3. Voltmeter (0-30V) MC.
4. Variable DC Power Supply
5. Patch chords
Theory:
The DIAC, or diode for alternating current, is a bidirectional trigger diode that conducts current only
after its breakdown voltage has been exceeded momentarily. When this occurs, the resistance of the
diode abruptly decreases, leading to a sharp decrease in the voltage drop across the diode and, usually, a
sharp increase in current flow through the diode. The diode remains "in conduction" until the current
flow through it drops below a value characteristic for the device, called the holding current. Below this
value, the diode switches back to its high-resistance (non-conducting) state. When used in AC
applications this automatically happens when the current reverses polarity.
The behavior is typically the same for both directions of current flow. Most DIACs have a breakdown
voltage around 30 V. In this way, their behavior is somewhat similar to (but much more precisely
controlled and taking place at lower voltages than) a neon lamp.
DIACs are a form of thyristor but without a gate electrode. They are typically used for triggering both
thyristors and TRIACs - a bidirectional member of the thyristor family. Because of this common usage,
many TRIACs contain a built-in DIAC in series with the TRIAC's "gate" terminal.
DIACs are also called symmetrical trigger diodes due to the symmetry of their characteristic curve.
Because DIACs are bidirectional devices, their terminals are not labeled as anode or cathode but as A1
and A2 or MT1 ("Main Terminal") and MT2.
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Circuit Diagram:
Procedure:
1. Made Connections as per the the circuit diagram.
2. Vary the voltage linearly by varying the input dc voltage till the DIAC get turned ON.
3. Note down the ammeter (IA) and voltmeter (VA) readings and note down the break over voltage
4. Plo the VA Vs IA in graph sheet.
5. Now change the DIAC MT2 is positive with respect to MT1.
6. Repeat the same procedure and plot the graph.
Tabulation:
SL. NO. VOLTAGE(VA) CURRENT(IA)
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Model Graph:
Result:
Thus the V-I Characteristic of DIAC were studied.
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EXPERIMENT:-4 Aim of the experiment:- To study the open loop response of a simple process.
Procedure:-
1. Patch the front panel of the PCS-01 as in figure.
2. Keep the process fast/slow switch (SW4) in slow position.
3. Using this set value control, attempt to make measured value meter to indicate any desired value.
4. Note down the relative readings of both measured value and set value meters.
5. Then apply a small disturbing voltage of 1 v DC to the load disturbance socket from DC voltage
source.
6. Note down the changes in measured value meter.
Tabulation:-
Sl. No. Set Value Measured Value
(No Load)
Measured Value
(With Load)
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Conclusion:-
As long as the other conditions are constant, the measured values are also constant. When the load is
disturbed no corrective action occurs.
In furnace for example if the some of the heat is removed and no adjustment is made to the power level,
the actual temperature or measured value may well rise above the desired value. The system is now
needs to be modified, so that it can correct itself for any changes in operating conditions. This can be
achieved by closing the loo.
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EXPERIMENT:-5 Aim of the experiment: - To study the closed response of a simple process.
Summary:-
There are three main features of such a system. A comparison is made between the set value and
measured value to reduce the deviation.
Deviation = Set value – Measured value.
Deviation operates the system and there is a power gain.
Procedure:-
1. Make the connections as per the front panel diagram as shown in the figure.
2. Keep the process fast/slow switch (SW4) in slow position.
3. Change the set value, and note the corresponding changes on set value and measured value
meters and also note down the deviation.
4. Then apply a voltage of approximately 1 v to the load disturbance socket.
5. Note down the changes in measured value and deviation.
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Tabulation:-
S. No Set value No Load With Load
Measured
Value
Deviation
Measured
Value
Deviation
Conclusion:-
When change in set value is made the measured value changes, but somewhat slower than the set value
and the measured value is not as same as the set value.
When load disturbance is applied to both the measured value and the deviation changes. The delay in the
change of the measured value is due to lags in the process.
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EXPERIMENT:-6 Aim of the experiment:-
To observe the time response of the closed loop second order process with the proportional control.
Summary:-
The system considered in experiment 3 had one major disadvantage, namely that there is considerable
deviation present at all times. As deviation should operate the system, this implies that sensitivity is too
low.
In process control this sensitivity is defined I terms of the proportional and. This is the range of values of
deviation that causes the controller output to cover its full operating range. This is often expressed as a
percentage such that 100% proportional band means the full range of outputs of the measuring systems
causes the controller to operate over its full range.
Adjustments of the percentage of the proportional band vary with the gain of the controller. The
following experiment will examine the effects of the changes in percentage of the proportional band and
response of the system to disturbances.
Procedure:-
1. Patch the front panel of PCS-01 as shown in figure.
2. Set the process fast/slow switch (sw4) in fast position.
3. Keep the set value pot to zero.
4. Apply a square wave signal of 2V p-p at around 50 Hz.
5. Alternatively display I the oscilloscope the set value disturbance point and measured value from
the point PV.
6. Repeat all the above tests with the percentage proportional band 50% and 40%.
7. As each step is applied to the system response as.
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Response of the system:
Tabulation:-
% PB Peak
overshoot
MP
Rise time t r Peak time t p Damping
Ratio ζ
Setting time
ts
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Conclusion:-
The system moves slowly towards the set value, overshoots, returns and after a few oscillations settles
so that the measured value is less than the set value as shown in figure-32.When it has settled there
exists a considerable deviation as shown figure-33. As the percentage proportional band is reduced, i.e.
the gain of the system is increased by,
KP = 100%/PB%
As this steady state deviation is reduced and the system settles with its measured value much closer to
set value.
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EXPERIMENT:-7
Aim of the experiment:- To study the time response of P+I controller.
Summary:-
The proportional control to maintain a stable system the gain level is such that the system is insensitive
to deviation below the certain level. In an ideal system the measured value and the set value should be
the same under steady state condition the deviation should be zero.
What is required is an alternative signal to be fed into the main amplifier of sufficient size to provide an
output if a steady state deviation exists viz to reduce the offset to zero. Such a signal can be provided by
an integer or which gives a constantly increasing output for a steady value input. Such an arrangement is
known as proportional +integral controller and should reduce any steady state deviation to zero.
Procedure:-
1. Connections are given as shown in figure.
2. Set the process fast/slow switch (SW4) and controller fast/slow switch (SW3) in fast position.
3. Keep the set value pot to zero.
4. Apply a square wave of 2V P-P at around 50 Hz.
5. Adjust the proportional band control until the system settles with 2 to 3 overshoots.
6. Now connect the integral section as shown I figure-36.
7. Slowly reduce the integral action time until the deviation falls to zero.
8. Monitor both the set value disturbance socket and PV socket. The typical output waveform is as
shown in figure.
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DDEEPPAARRTTMMEENNTT OOFF EELLEECCTTRROONNIICCSS && IINNSSTTRRUUMMEENNTTAATTIIOONN EENNGGIINNEEEERRIINNGG
Tabulation:-
S. No. Proportional
band PB
Integral time Peak
Overshoot
MP
Rise time Tr Setting time
Ts
Conclusion:-
By suitable adjustment of an integrator section output the steady state deviation can be reduced to zero.
In consequence the measured value becomes much closer to set value.
Too much integral term however causes the system to go into oscillation. Generally speaking an increase
in integral time reduces the steady state deviation but increases the time of the system takes to settle.
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Experiment-8 Aim of the experiment:- To study the response of P+I+D controller in a process.
Summary:-
As seen in experiment no 5 the integral control improves the performance of the control system in some
respects, I.e. it reduces the steady state deviation, but has the disadvantage of slowing down the over all
response time.
If a system is required to follow a sudden change in set value this would give rse to a rapid
change in the deviation. Although this deviation change is rapid the system response rather slowly, so if
at this time the controller output can be boosted, the speed of the system response will be improved.
If the deviation is differentiated, i.e. rate of change of measured, and a signal is produced
proportional to this and than added to the signal from the proportional and integrator sections, some
improvements may results such an arrangement is known as three term controller or PID controller.
PID Controller Response:
Procedure:-
1. Connections are given as shown in figure.
2. Set the process fast/slow switch (SW4) and controller fast/slow switch (SW3) in fast position.
3. Keep the set value pot to zero.
4. Apply a square wave of 2V P-P at around 50 Hz.
5. Now patch I and I’ and adjust the integral time until the steady state deviation is zero.
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6. Now note down the number of overshoots before the system settles.
7. Now connect D and D’ and increase the derivative time and note down the effect of the system
response.
Tabulation:-
Proportional
band
Integral
time
Rise time Tr Peak time
Tp
Setting time
Ts
Peak
overshoot
Conclusion:
The response of the P-I-D controller studied successfully.
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Experiment-9 Aim of the Experiment:
To study the action of ON/ OFF control of a temperature control system using VTCS-02
Equipment Required:
1. Temperature control system (VTCS02)
2. Patch Cords
3. Heater setup
4. Thermistor Sensor
Theory:
Two position control is a position type of controller action in which the manipulated variable is quickly
changed to either a maximum or minimum value depending on whether the process variable is greater or
lesser than the set point.
Without Overlap:
In a two step-controller the output signal changes from one predetermined value to another when the
deviation changes sign. This leads to a system in which the controlled condition alternates above and
below a mean value at a frequency determined by the energy level at which the correcting elements
operate.
With
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overlap applied the controller changes to its higher value when the process variable falls below a lower
limit and to its lower value when the process variable exceeds an upper limit.
Over lap:
Over lap is the region in which the control causes the manipulated variable to maintain its previous
value until the controlled variable has moved slightly beyond the set point.
Small overlap is not preferred because it will introduce oscillation as and reduce the life of final control
element.
Procedure:
1. Interface the heater, blower, Thermistor with VTCS-02
2. Keep the ON-OFF/ PID switch in ON-OFF position, SW-1 should be in downward direction.
3. Keep the overlap POT at minimum position
4. Set the desired temperature (35-95oC) by varying the set value POT
5. Switch on the heater and blower. Blower should not be switched on before heater switching.
6. Tune the overlap to maintain the process variable at set point.
7. View the response for different set points and throttle opening.
Results:
Thus the ON-OFF control action on temperature process control system was studied.
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Experiment-10 Aim of the Experiment:
To study the action of proportional control on a temperature control system using VTCS-02
Equipment Required:
5. Temperature control system (VTCS02)
6. Patch Cords
7. Heater setup
8. Thermistor Sensor
9. Blower
Theory:
Two position controls applied to a process results in a continuous oscillation in the quantity to be
controlled. This draw back was overcome by a continuous control action which could maintain a
continuous balance of the input and output. Proportional control is defined as follows.
“It is a controller action in which there is a continuous linear relation between the value of the controlled
variable and position of the final controlled element within the proportional band.”
Controller Output = kp (Err) + Bias.
PB = (Full Scale Deviation / KC) × 100
Offset, the sustained deviation always present in proportional control is dependent on the proportional
bandwidth. As proportional band is decreased, deviation is reduced until a point is reached at which the
system become unstable.
PPRROOCCEESSSS CCOONNTTRROOLL LLAABB ((CCPPEENN 99440055)) MMAANNUUAALL
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DDEEPPAARRTTMMEENNTT OOFF EELLEECCTTRROONNIICCSS && IINNSSTTRRUUMMEENNTTAATTIIOONN EENNGGIINNEEEERRIINNGG
Procedure:
8. Interface the heater, blower, Thermistor with VTCS-02
9. Keep the ON-OFF/ PID switch in PID position, SW-2 should be in downward direction.
10. Patch the proportional control section (P-P1)
11. Set the desired temperature (35-95oC) by varying the set value POT
12. Switch on the heater and blower. Blower should not be switched on before heater switching.
13. Tune the proportional band to maintain the process variable at set point.
14. View the response for different set points and proportional band.
Supply Disturbance:
A step change in set point is produced by SW-2 toggle, switch and immediate change in controller
output and delayed responses in measured value due to distance/ velocity and transfer lag.
Results:
Thus the proportional control action on temperature process control system was studied.
PPRROOCCEESSSS CCOONNTTRROOLL LLAABB ((CCPPEENN 99440055)) MMAANNUUAALL
28
DDEEPPAARRTTMMEENNTT OOFF EELLEECCTTRROONNIICCSS && IINNSSTTRRUUMMEENNTTAATTIIOONN EENNGGIINNEEEERRIINNGG
Experiment-11 Aim of the Experiment:
To study the action of PID controller on a temperature control system using VTCS-02
Equipment Required:
10. Temperature control system (VTCS02)
11. Patch Cords
12. Heater setup
13. Thermistor Sensor
14. Blower
Theory:
BiasErrdtddtErrErrKC
T
pO +++= ∫ )()()(0
The three mode controller contains the stability of proportional control and the ability to eliminate offset because
of reset (integral). Control and the ability provide an immediate correction for the magnitude of a disturbance
because of rate (derivative) control.
Procedure:
1. Interface the heater, blower, Thermistor with VTCS-02
2. Keep the ON-OFF/ PID switch in PID position, SW-2 should be in downward direction.
PPRROOCCEESSSS CCOONNTTRROOLL LLAABB ((CCPPEENN 99440055)) MMAANNUUAALL
29
DDEEPPAARRTTMMEENNTT OOFF EELLEECCTTRROONNIICCSS && IINNSSTTRRUUMMEENNTTAATTIIOONN EENNGGIINNEEEERRIINNGG
3. Patch the proportional control section (P-P1), (I-I1) and (D-D1)
4. Set the desired temperature (35-95oC) by varying the set value POT
5. Switch on the heater and blower. Blower should not be switched on before heater switching.
6. Tune the proportional band, Ti, Td potentiometers to maintain the process variable at set point.
7. View the response for different set points and PID values.
Supply Disturbance:
A step change in set point is produced by SW-2 toggle, switch and immediate change in controller
output and delayed responses in measured value due to distance/ velocity and transfer lag.
Results:
Thus the proportional control action on temperature process control system was studied.
PPRROOCCEESSSS CCOONNTTRROOLL LLAABB ((CCPPEENN 99440055)) MMAANNUUAALL
30
DDEEPPAARRTTMMEENNTT OOFF EELLEECCTTRROONNIICCSS && IINNSSTTRRUUMMEENNTTAATTIIOONN EENNGGIINNEEEERRIINNGG
EXPERIMENT-12 Aim of the Experiment:
To study the opening v/s flow characteristics of the control valve.
Apparatus Required:
1. Compressor
2. Pump
3. Control Valve
4. Level Indicator
Theory:
The control valve is essentially a variable resistance to the flow of a fluid, in which the resistance and
therefore the flow can be changed by a signal from a process controller.
The control valve consists of an actuator and a valve. The valve itself divided into the body and the trim.
The body consists of housing for mounting the actuator and connections for attachment of the trim,
which is enclosed within the body. The body consists of a plug, a valve seat and a valve steam. The
actuator moves the valve steam as the pressure on a spring loaded diaphragm. The steam moves a plug
in a valve seat in order to change the resistance to flow through the valve. When a valve is supplied by
the manufacturer the actuator and the valve are attached to each other to form one unit.
Valve Characteristics:
The function of the control valve is to vary the flow of the fluid through the valve by means of a change
of pressure to the valve top. The relation between the flow through the valve and the valve steam
position is called Valve Characteristics.
In general the flow through a control valve for a specific fluid at a given temperature can be expressed:
Q=f (L, P0, P1).
Where Q=Volumetric flow rate
L=Valve steam position
P0=Up steam pressure
P1=Down Steam pressure.
Valve can be dividing into 3 types decreasing sensitivity, linear and Increasing sensitivity. Fractional
flow m is plotted against fractional lift x. For the decreasing sensitivity, the sensitivity decreases with m.
For the linear type sensitivity is constant and the characteristic curve is a straight line. For the increasing
sensitivity type, the sensitivity increases with flow m.
PPRROOCCEESSSS CCOONNTTRROOLL LLAABB ((CCPPEENN 99440055)) MMAANNUUAALL
31
DDEEPPAARRTTMMEENNTT OOFF EELLEECCTTRROONNIICCSS && IINNSSTTRRUUMMEENNTTAATTIIOONN EENNGGIINNEEEERRIINNGG
Control Valve:
The relation between flow and steam position for a valve installed in a process line will be called the
effective valve characteristic.
PPRROOCCEESSSS CCOONNTTRROOLL LLAABB ((CCPPEENN 99440055)) MMAANNUUAALL
32
DDEEPPAARRTTMMEENNTT OOFF EELLEECCTTRROONNIICCSS && IINNSSTTRRUUMMEENNTTAATTIIOONN EENNGGIINNEEEERRIINNGG
Procedure:
1. Fill the reservoir with water and then switch on the compressor pump.
2. Open the two valves of water and air to the control valve (Cn) to permit the follow of air and
water.
3. Close the valve Cn in air at zero pressure, and then note the maximum flow from Rota meter.
4. Note and tabulate the different valve opening flow rate.
5. Close the air and water inlet valve.
6. Open the valve Cn at high pressure. Then measure the minimum flow rate at maximum lift of
valve
7. Again tabulate the different valve opening flow rate. And Plot the graph.
Tabulation:
Air to Open:
Scale of control
valve
Flow rate in LPH %ge of Lift %ge of Flow
Air to Close:
Scale of control
valve
Flow rate in LPH %ge of Lift %ge of Flow
Conclusion
The control valve CV1 was found to be Linear one where the valve CV2 equal percentage type.