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Chapter 5
Non-return, flow and pressure valves,valve combinations
Festo Didactic TP101
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5.1 Non-return valves
Non-return valves are devices which preferentially stop the flow in onedirection and permit flow in the opposite direction. The pressure on thedownstream side acts against the restrictive component, therebyassisting the sealing effect of the valve.
Check valves can stop the flow completely in one direction. In theopposite direction the flow is free with a minimal pressure drop due tothe resistance of the valve. Blocking of the one direction can be
effected by cones, balls, plates or diaphragms.
Elements fitted at a three way junction which have non-returncharacteristics and direct the movement of signal air. The two valveshere referred to as junction elements have logic characteristics whichdetermine the passage of two input signals. The dual pressure valve
requires two signals (AND function) to produce an output and theshuttle valve requires at least one signal input (OR function) to producean output. These are processing elements whereby two signals areprocessed internally and the resulting signal is output at port 2.
TP101 Festo Didactic
Check valves
Fig. 5.1Non-return valve
Junction elements
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The dual pressure valve has two inlets 1 and 1(3) and one outlet A.Compressed air flows through the valve only if signals are applied toboth inlets. One input signal at 1 or 1(3) blocks the flow due to thedifferential forces at the piston slide. If signals are applied to both 1 and1(3), the signal which is last applied passes to the outlet. If the inputsignals are of different pressures, the larger of the two pressures closesthe valve and the smaller air pressure is transferred to the outlet 2. Thedual pressure valve is used mainly for interlocking controls, safetycontrols, check functions and logic AND operations.
Festo Didactic TP101
Dual pressure valve:logic AND function
Fig. 5.2Dual pressure valve:logic AND function
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The dual pressure valve circuit is equivalent to the two input signallingdevices in series, i.e. one after the other (3/2-way valve, normallyclosed position). The signal output is passed all the way through only ifboth signal elements are operated.
TP101 Festo Didactic
Fig. 5.3Circuit diagram withdual pressure valve
Fig. 5.4Circuit diagram:
series AND function
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A disadvantage of the switching variant is that in practice this oftenleads to extremely long lines between the valves. Moreover, the signalfrom valve 1S2 cannot be used in another logic, since the valve 1S2 isonly pressurised if valve 1S1 is actuated.
This non-return element has two inlets 1 and 1(3) and one outlet 2. Ifcompressed air is applied to the first inlet 1, the valve seat seals theopposing inlet 1(3), the air flows from 1 to 2. Inlet 1 is closed, if airpasses from 1(3) to 2. A signal is generated at the outlet. When the airflow is reversed, i.e. a cylinder or valve is exhausted, the seat remains
in its previously assumed position because of the pressure conditions.
This valve is also called an OR element. If a cylinder or control valve isto be actuated from two or more positions, one or more shuttle valvesshould be used.
Festo Didactic TP101
Shuttle valve:logic OR function
Fig. 5.5Shuttle valve:logic OR function
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In the example shown, a cylinder is to be advanced using two handoperated valves, which can be fitted at different distances from thecylinder. Without the use of the shuttle valve, the compressed air wouldmainly flow via port 3 of the valve 1S2, if the valve 1S1 is actuated.
Shuttle valves can be linked to create additional logic OR conditionse.g. as shown below: if any of three push buttons are operated, thecylinder is to extend.
TP101 Festo Didactic
Fig. 5.6Controlling a cylinder with
two input elements
Fig. 5.7Controlling a cylinder with
three input elements
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Quick-exhaust valves are used to increase the piston speed ofcylinders. This enables lengthy return times to be avoided, particularlywith single-acting cylinders. The principle of operation is to allow thecylinder to retract at its near maximum speed by reducing theresistance to flow of the exhausting air during motion of the cylinder. Toreduce resistance, the air is expelled to atmosphere close to thecylinder via a large orifice opening. The valve has a closable supplyconnection 1, a closable exhaust 3 and an outlet 2.
Festo Didactic TP101
Quick exhaust valve
Fig. 5.8Quick exhaust valve:flow from 1 to 2
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If pressure is applied at port 1, then the sealing disc covers the exhaust3, whereby the compressed air passes from 1 to 2. If pressure is nolonger applied at 1, then the air from 2, moves the sealing disc againstport 1 and closes this, whereby the exhaust air immediately vents toatmosphere. There is no need for the air to pass through a long andpossibly restricted path to the directional control valve via theconnecting lines. It is advantageous to mount the quick-exhaust valvedirectly on the cylinder or as near to it as possible.
TP101 Festo Didactic
Fig. 5.9
Quick exhaust valve:exhaust from 2 to 3
Fig 5.10Circuit diagram withquick exhaust valve
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, . .
5.2
. .
. . , .
Festo Didactic TP101
Shut-off valves
Fig. 5.11Stop cock
Throttle valve,bi-directional
Fig. 5.12Throttle valve
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:
: , .
: , .
. , . . , . , .
TP101 Festo Didactic
One-way flowcontrol valve
Fig. 5.13One-way flow
control valve
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, :
, .
.
. .
Festo Didactic TP101
Supply air throttling
Fig. 5.14Supply air throttling
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, . , . -inder . . -haust . ,
TP101 Festo Didactic
Exhaust air throttling
Fig. 5.15Exhaust air throttling
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, . . , , .
Festo Didactic TP101
Mechanicallyadjustable one-wayflow control valve
Fig. 5.16Mechanicallyadjustable one-wayflow control valve
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5.3
. :
-
-
-
, 2,6 " ". , . .
, . - . , . .
TP101 Festo Didactic
Pressure regulatingvalve
Fig. 5.17Pressure regulating valve
Pressure limiting valve
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. , .
1 2 . 2 12. 1 2.
Festo Didactic TP101
Pressure sequencevalve
Fig. 5.18Adjustable pressure
sequence valve
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o (- ).
, , . .
:
- :
- :
- 5/4-way :
- 8- :
- : -
- :
TP101 Festo Didactic
Fig. 5.19Circuit diagram with
pressure sequence valve
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- :
Festo Didactic TP101
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3/2-way , . 3/2-way . 0-30 .
, . switch- , .
TP101 Festo Didactic
Time delay valve
Fig. 5.20Time delay valve:normally closed
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The following operational principle applies for a time delay valve with a3/2-way valve in normally closed position: The compressed air issupplied to the valve at connection 1. The control air flows into thevalve at 12 through a one-way flow control valve and depending on thesetting of the throttling screw, a greater or lesser amount of air flows perunit of time into the air reservoir. When the necessary control pressurehas built up in the air reservoir, the pilot spool of the 3/2-way valve ismoved downwards. This blocks the passage from 2 to 3. The valve discis lifted from its seat and thus air can flow from 1 to 2. The time requiredfor pressure to build up in the air reservoir is equal to the control time
delay of the valve.If the time delay valve is to switch to its initial position, the pilot line 12must be exhausted. The air flows from the air reservoir to atmospherethrough the bypass of the one-way flow control valve and then to theexhaust line. The valve spring returns the pilot spool and the valve discseat to their initial positions. Working line 2 exhausts to 3 and 1 isblocked.
Festo Didactic TP101
Operational principle
Fig. 5.21Time delay valve:
normally open
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The normally open time delay valve includes a 3/2-way valve which isopen. Initially the output 2 is active. When the valve is switched by 10the output 2 is exhausted to 3 and 1 is closed. The result is that theoutput signal is turned off after a set time delay.
The time delay corresponds to the pressure build up in the reservoiragain. If the air at port 10 is removed, then the 3/2-way valve assumesthe normal position.
The circuit below utilises two time delay valves, one a normally closedvalve (1V2) and the other a normally open valve (1V1). Upon operationof the start button 1S1, the signal generated passes through the valve
1V1 and initiates the movement of cylinder extension (1A) via the 14port of the control element 1V3. The time delay valve 1V1 has a shorttime delay set of 0.5 seconds. This is long enough to initiate the startsignal but then the 14 signal is cancelled by the 10 pilot signal of thetime delay valve. The cylinder operates limit valve 1S2. The time delayvalve 1V2 receives a pilot signal which after the preset time opens thevalve. This supplies the 12 signal which reverses the valve and retractsthe cylinder. A new cycle can only be started via the start button andrenewed actuation of the valve 1S1.
TP101 Festo Didactic
Fig. 5.22
Circuit diagram withtime delay valve
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The following illustrations show the time behaviour of circuits with timedelay valves.
Fig. 5.23Time response of circuits
with time delay valves
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