FME11L Module 2: Modern Pneumatic, Electropneumatic Fundamentals PDF

Summary

This document provides an overview of modern pneumatic and electropneumatic fundamentals, including pneumatic control, lessons, and FluidSIM. The document also touches upon components, advantages, and applications related to this subject.

Full Transcript

MODERN PNEUMATIC, ELECTROPNEUMATIC FUNDAMENTALS

Module 2:
MODERN PNEUMATIC,
ELECTROPNEUMATIC
FUNDAMENTALS
Lesson 1: Pneumatic Control
Lesson 2: Overview of FESTO Fluidsim

Lesson 3: Single/Double Acting Cylinders, (One Way) Flow
Control Valves,
Directional Control Valves
Lesson 4: Service units, DCV Actuation Types, Sensors, Shuttle
Valves, (Pneumatic OR), Two Pressure Valves (Pneumatic
AND), Compressed Air Supply Sources, Quick Exhaust Valves
Lesson 5: Solenoids, Impulse DCV vs Spring Return DCV,
Electric Input Elements, Electric Output Elements, Electro
Pneumatics

Lesson 6: Electric Control Circuits, On Delay Timer
MODERN PNEUMATIC, ELECTROPNEUMATIC FUNDAMENTALS

Lesson 1: REVIEW OF THE
PNEUMATIC CONTROL
The word ‘Pneuma’ means breath or air. Pneumatics is application of compressed
air in automation. In Pneumatic control, compressed air is used as the
working medium, normally at a pressure from 6 bar to 8 bar. Using Pneumatic
Control, maximum force up to 50 kN can be developed. Actuation of the
controls can be manual, Pneumatic or Electrical actuation. Signal medium
such as compressed air at pressure of 1-2 bar can be used [Pilot operated
Pneumatics] or Electrical signals [ D.C or A.C source- 24V – 230V ] can be used
[Electro pneumatics]

1.1 Characteristics of Compressed Air

The following characteristics of Compressed air speak for the application of
Pneumatics
Abundance of supply of air
Transportation
Storage
Temperature
Explosion Proof
Cleanliness
Speed
Regulation
Overload Proof

1.2 Selection Criteria for Pneumatic Control
System

Stroke
Force
Type of motion [Linear or Angular motion]
Speed
Size
Service
Sensitivity
Safety and Reliability
Energy Cost
Controllability
MODERN PNEUMATIC, ELECTROPNEUMATIC FUNDAMENTALS

Handling
Storage

1.3 Advantages of Pneumatic Control

Unlimited Supply
Storage
Easily Transportable
Clean
Explosion Proof
Controllable (Speed, Force)
Overload Safe
Speed of Working Elements

Disadvantages
Cost
Preparation
Noise Pollution
Limited Range of Force
(only economical up to 25 kN)

1.4 General Applications of Pneumatic Control

Clamping
Shifting
Metering
Orienting
Feeding
Ejection
Braking Bonding
Locking
Packaging
Feeding
Door or Chute Control
Transfer of Material
Turning or Inverting of Parts
Sorting of Parts
Stacking of Components
Stamping and Embossing of components

1.5 Applications in Manufacturing

Drilling Operation
MODERN PNEUMATIC, ELECTROPNEUMATIC FUNDAMENTALS

Turning
Milling
Sawing
Finishing
Forming
Quality Control

1.6 Structure of Pneumatic Control System

Figure 1.1 Structure of Pneumatic Control System

A typical Pneumatic control system comprises of the above groups of components. In
direct actuation controls signal processing group is not required. In electro pneumatic
Control signal processing can be carried out using combination of relays and contractors
or using PLC. The final control valves are solenoid actuated in the case of electro
pneumatic controls
MODERN PNEUMATIC, ELECTROPNEUMATIC FUNDAMENTALS

Lesson 2:
INTRODUCTION TO FLUIDSIM
2.1 About FluidSim
FluidSIM is a teaching tool for simulating pneumatics, hydraulics, electrics/electronics and
digital technique. It can be used in combi-nation with the Festo Didactic GmbH & Co. KG
training hardware, but also independently. FluidSIM was developed as a joint venture
between the University of Paderborn, Festo Didactic GmbH & Co. KG, Denkendorf, and Art
Systems Software GmbH, Paderborn.

For this course, we will only use the pneumatics feature of Fluidsim. Installers and manuals
have been provided to the class.

2.2 The Pneumatic Components
In the succeeding parts of this lecture, the Pneumatic Components of Fluidsim will be
presented for your reference.

Supply Elements

1. Compressed air supply
The compressed air supply provides the needed compressed air. It contains a pressure control
valve that can be adjusted to output the desired operating pressure.

2. Compressor
The compressor provides the necessary compressed air. The pres- sure is restricted to the
preset operating pressure.

3. Compressor, adjustable
MODERN PNEUMATIC, ELECTROPNEUMATIC FUNDAMENTALS
The adjustable compressor provides the necessary compressed air, whereby the
maximum flow rate can be adjusted under
Actual operating conditions and in the simulation. The pressure is restrict- ed to the
preset operating pressure.

4. Air service unit, simplified representation
The service unit is made up of a compressed air filter with water separator and a pressure control
valve.

5. Air service unit
The service unit is made up of a compressed air filter with water separator and a pressure control
valve.

6. Start-up valve with filter control valve
The filter with water separator cleans the compressed air of dirt, pipe scale, rust and
condensate. The pressure regulator adjusts the compressed air supplied to the set operating pressure and
com- pensates for pressure fluctuations. The pressure gauge shows the preset pressure. The on/off valve
exhausts the entire control.

7. Manifold
The manifold enables a control system to be supplied with com- pressed air eight individual
connections.

8. Air pressure reservoir
The air pressure reservoir serves as compensation for pressure fluctuations and is utilized (as
a reservoir) for abruptly occurring air consumption. Large time delays can be attained when used in
conjunction with time delay- and throttle valves.

9. Air pressure reservoir (2 Connections)
The air pressure reservoir serves as compensation for pressure fluctuations and is utilized (as a reservoir) for abruptly
occurring air consumption. Large time delays can be attained when used in conjunction with time delay- und throttle
valves.

10. Filter
The compressed air filter removes contamination from the com- pressed air. The size of the filterable particles is dependent
upon the filter class.

11. Filter, manual condensate drain
The compressed air filter removes contamination from the com- pressed air. The size of the filterable particles is
dependent upon the filter class. Condensation, which can occur through sinking temperatures or the expansion of the
compressed air, can be man- ually drained off.

12. Filter, automatic condensate drain
The compressed air filter removes contamination from the com- pressed air. The size of the filterable particles is
MODERN PNEUMATIC, ELECTROPNEUMATIC FUNDAMENTALS
dependent upon the filter class. Condensation, which can occur through sinking temperatures or the expansion of the
compressed air, is automati- cally drained off.

13. Water separator
The water separator drains off accrued water.

14. Water separator, automatic condensate drain
The water separator drains off accrued water and is automatically emptied.

15. Lubricator
The lubricator enriches the compressed air with oil.

16. Cooler
The cooler cools the compressed air.

17. Adsorption dryer
The adsorption dryer reduces the humidity in the compressed air.

18. Connection (pneumatic)
A pneumatic connection is a place where a pneumatic line can be attached to. To simplify the line drawing process, a
connection appears as a small circle in Edit Mode. Pneumatic connections can be shut by means of a blind plug. An open
pneumatic connection may result in leaking air; FluidSIM-P thus pops up a warning mes- sage, if some pneumatic
connection was left open. Note that at each pneumatic connection values for the flow and pressure can be displayed.

19. Line (pneumatic)
A pneumatic line links two pneumatic connections. Note that a pneumatic connection may be a simple pneumatic
connection or a T-junction. A pneumatic line causes no pressure drop, i. e., it has no fluidic resistance. From a drawing
point of view, FluidSIM distin- guishes between control lines and main lines. The former is repre- sented by a dashed line,
the latter is represented by a solid line and establishes the default case.

20. T-junction (pneumatic)
A T-junction joins up to four pneumatic lines, thus having a single pressure potential. Note that T-junctions are introduced
automati-
cally by FluidSIM when dropping the line drawing cursor onto another line in Edit Mode.

Configurable Way Valves

21. Configurable 2/n way valve
MODERN PNEUMATIC, ELECTROPNEUMATIC FUNDAMENTALS

The configurable 2/n way valve is a way valve with two connec- tions, where both its body elements operation modes are
user- definable.

Additionally, the pneumatic connections can be closed with either blind plugs or exhausts.

22. Configurable 3/n way valve
The configurable 3/n way valve is a way valve with two connec- tions, where both its body elements operation modes are
user- definable.

Additionally, the pneumatic connections can be closed with either blind plugs or exhausts.

23. Configurable 4/n way valve
The configurable 4/n way valve is a way valve with two connec- tions, where both its body elements operation modes are
user- definable.

Additionally, the pneumatic connections can be closed with either blind plugs or exhausts.

24. Configurable 5/n way valve
The configurable 5/n way valve is a way valve with two connec- tions, where both its body elements operation modes are
user- definable.

Additionally, the pneumatic connections can be closed with either blind plugs or exhausts.

25. Configurable 6/n way valve
The configurable 6/n way valve is a way valve with two connec- tions, where both its body elements operation modes are
user- definable.

Additionally, the pneumatic connections can be closed with either blind plugs or exhausts.

26. Configurable 8/n way valve
The configurable 8/n way valve is a way valve with two connec- tions, where both its body elements operation modes are
user- definable.

Additionally, the pneumatic connections can be closed with either blind plugs or exhausts.

Mechanically Operated Directional Valves

27. 3/2-way roller lever valve, normally closed
The roller lever valve is operated by pressing on the lever, for example through the use of a switching cam of a cylinder.
The flow passes through from 1 to 2. After releasing the lever, the valve returns to its initial position through the use of
a return spring.
Connection 1 is shut. In the Simulation Mode, the valve can be switched manually by clicking on the component, thus not
requiring a cylinder to operate the valve. This valve is derived from a config- urable 3/n way valve. You find this valve in the
component library
“Frequently used Way Valves”, under the menu.
MODERN PNEUMATIC, ELECTROPNEUMATIC FUNDAMENTALS

28. 3/2-way roller lever valve, normally open
The roller lever valve is operated by pressing on the lever, for example through the use of a switching cam of a cylinder.
Connec- tion 1 is shut. After releasing the lever, the valve returns to its initial position through the use of a return spring.
The flow may pass through freely from 1 to 2. In the Simulation Mode, the valve can be switched manually by clicking on
the component, thus not requiring a cylinder to operate the valve. This valve is derived from a configurable 3/n way valve.
You find this valve in the component
library “Frequently used Way Valves”, under the menu.

29. 3/2-way idle return roller valve, normally closed
The idle return roller valve is operated when the roller is driven in a specific direction by the switching cam of a cylinder. After
releasing the roller, the valve returns to its initial position through the use of a return spring. Connection 1 is shut. When the
roller is driven in
the opposite direction, the valve is not operated. In the Simulation Mode, the valve can be switched manually by clicking on
the com- ponent, thus not requiring a cylinder to operate the valve. This valve is derived from a configurable 3/n way
valve. You find this valve in the component library “Frequently used Way Valves”,
under the menu.

30. Pressurizing valve
The pressurizing valve with plunger control is operated by the surface of the cylinder cam. When the plunger is
operated, com- pressed air flows freely until the nozzle is closed. A signal up to the level of the boost pressure is
assembled at exit connection 2. In the Simulation Mode, the valve can be switched manually by click- ing on the
component, thus not requiring a cylinder to operate the valve.

31. Pneumatic proximity switch, solenoid operated
A permanent solenoid found on the piston of a cylinder drives this 3/2 pneumatic directional valve and triggers the control
signal. The flow passes freely from 1 to 2. In the Simulation Mode, the valve can be switched manually by clicking on the
component, thus not requiring a cylinder to operate the valve. This valve is derived from a configurable 3/n way valve. You
find this valve in the component
library “Frequently used Way Valves”, under the menu.

32. 3/2-way valve with pushbutton, normally closed
Pressing the pushbutton operates the valve. The flow passes freely from 1 to 2. Releasing the pushbutton allows the valve to
return to its starting position through the use of a return spring. Connection
1 is shut. By holding down the Shift key and simultaneously
clicking on the component with the mouse cursor, FluidSIM keeps the valve in permanent operating position. Simply
clicking on the component cancels the operated state and returns the valve to its starting position. This valve is derived
from a configurable 3/n way valve. You find this valve in the component library “Frequently used
Way Valves”, under the menu.

33. 3/2-way valve with pushbutton, normally open
Pressing the pushbutton operates the valve. Connection 1 is shut. Releasing the pushbutton allows the valve to returns to its
starting position through the use of a return spring. The passes freely from
1 to 2. By holding down the Shift key and simultaneously click-
ing on the component with the mouse cursor, FluidSIM keeps the valve in permanent operating position. Simply clicking
on the component cancels the operated state and returns the valve to its starting position. This valve is derived from a
configurable 3/n way valve. You find this valve in the component library “Frequently used
Way Valves”, under the menu.
MODERN PNEUMATIC, ELECTROPNEUMATIC FUNDAMENTALS

34. 3/2-way valve with selection switch or striking button
Pressing the red striking button operates the valve. The flow passes freely from 1 to 2. Releasing the button has no effect;
the valve remains in its operating position. Turning the button to the right

sets the striking button back to its original position and the valve returns to its starting position through the use of a return
spring. Connection 1 is shut. This valve is derived from a configurable 3/n way valve. You find this valve in the component
library “Frequently
used Way Valves”, under the menu.

35. 5/2-way valve, with selection switch
Turning the selection switch operates the valve. The flow passes freely from 1 to 4. Releasing the switch has no effect; the
valve remains in its operating position. Turning the switch back to its original position allows the flow to pass freely from
1 to 2. This valve is derived from a configurable 5/n way valve. You find this valve in the component library “Frequently
used Way Valves”,
under the menu.

Solenoid Operated Directional Valves

36. 3/2-way solenoid valve, normally closed
The solenoid valve is controlled by applying a voltage signal at the solenoid coil. The flow passes freely from 1 to 2. By
stopping the signal the valve is set back to its starting position through the use of a return spring. Connection 1 is shut. If no
signal is applied to the valve, it can be manually operated. This valve is derived from a configurable 3/n way valve. You
find this valve in the component
library “Frequently used Way Valves”, under the menu.

37. 3/2-way solenoid valve, normally open
The solenoid valve is controlled by applying a voltage signal at the solenoid coil. Connection 1 is shut. By stopping the signal
the valve is set back to its starting position through the use of a return spring. The flow passes freely from 1 to 2. If no
signal is applied to the valve, it can be manually operated. This valve is derived from a configurable 3/n way valve. You find
this valve in the component
library “Frequently used Way Valves”, under the menu.

38. 5/2-way solenoid valve
The solenoid valve is controlled by applying a voltage signal at the solenoid coil. The flow passes freely from 1 to 4. By
stopping the signal the valve is set back to its starting position through the use of a return spring. The flow passes freely
from 1 to 2. If no signal is applied to the valve, it can be manually operated. This valve is derived from a configurable 5/n
way valve. You find this valve in the component library “Frequently used Way Valves”, under the
menu.

39. 5/2-way solenoid impulse valve
The solenoid valve is controlled by applying a voltage signal at the solenoid coil (flow passes from 1 to 4) and remains in this
operat- ing position even when the signal is cut off. Only by applying an opposite signal will the valve return to its starting
position (flow passes freely from 1 to 2). If no signal is applied to the valve, it can be manually operated. This valve is
derived from a configurable 5/n way valve. You find this valve in the component library “Fre-
quently used Way Valves”, under the menu.

40. 5/3-way solenoid valve, mid-Position closed
MODERN PNEUMATIC, ELECTROPNEUMATIC FUNDAMENTALS
The solenoid valve is controlled by applying a voltage signal at the solenoid coil (flow passes from 1 to 4 or from 1 to 2). By
stopping the signal the valve is set back to its starting position through the use of a return spring. Connections 1, 2, and 4
are shut. If no signal is applied to the valve, it can be manually operated. This valve is
derived from a configurable 5/n way valve. You find this valve in the component library “Frequently used Way Valves”,
under the
menu.

20.1.1 Pneumatically Operated Directional Valves

41. 3/2-way valve, pneumatically operated, normally closed
The pneumatic valve is controlled by applying a pilot pressure at connection 12. The flow passes freely from 1 to 2. By
stopping the signal the valve is set back to its starting position through the use of a return spring. Connection 1 is shut. This
valve is derived from a configurable 3/n way valve. You find this valve in the component
library “Frequently used Way Valves”, under the menu

42. 3/2-way valve, pneumatically operated, normally open
The pneumatic valve is controlled by applying a pilot pressure at connection 10. Connection 1 is shut. By stopping the
signal the valve is set back to its starting position through the use of a return spring. The flow passes freely from 1 to 2. This
valve is derived from a configurable 3/n way valve. You find this valve in the component
library “Frequently used Way Valves”, under the menu.

43. 5/2-way valve, pneumatically operated
The pneumatic valve is controlled by applying a pilot pressure at connection 14. The flow passes freely from 1 to 4. By
stopping the signal the valve is set back to its starting position through the use of a return spring. The flow passes freely
from 1 to 2. This valve is derived from a configurable 5/n way valve. You find this valve in the component library
“Frequently used Way Valves”, under the
menu.

44. 5/2-way impulse valve, pneumatically operated
The pneumatic valve is controlled by applying reciprocal pilot pressures at connection 14 (flow passes from 1 to 4) and
connec- tion 12 (flow passes from 1 to 2). The valve’s operating position remains until an opposite signal is received by
the valve. This valve is derived from a configurable 5/n way valve. You find this valve in the component library “Frequently
used Way Valves”, under the
menu.

45. 5/3-way pneumatic valve, mid-Position closed
The pneumatic valve is controlled by applying reciprocal pilot pressures at connection 14 (flow passes from 1 to 4) and
connec- tion 12 (flow passes from 1 to 2). By stopping the signals the valve is set back to its starting position through the
use of a return spring. Connections 1, 2, and 4 are shut. This valve is derived from

a configurable 5/n way valve. You find this valve in the component
library “Frequently used Way Valves”, under the menu.

46. Low pressure amplifier unit, 2 compartments
Each of the two double-level low pressure amplifier units has the function of a 3/2 directional valve that is normally closed.
The signal at connection 12 is raised to a higher boost pressure level through the use of a double-level amplifier and is put out
by con- nection 2.
MODERN PNEUMATIC, ELECTROPNEUMATIC FUNDAMENTALS

Shutoff Valves and Flow Control Valves

47. Shuttle valve
The shuttle valve is switched based on the compressed air entering into either input connection 1 and leaving via an output
connection
2. Should both input connections begin receiving compressed air, the connection with the higher pressure takes
precedence and is put out (OR function).

48. Quick exhaust valve
The compressed air passes from connection 1 to connection 2. If the pressure should decrease at connection 1, then the
com- pressed air from connection 2 will escape to the outside via the installed silencer.

49. Two pressure valve
The two pressure valve is switched based on the compressed air entering into both input connections 1 and leaving via an
output connection 2. Should both input connections begin receiving com- pressed air, the connection with the lower
pressure takes prece- dence and is put out (AND function).

50. Check valve
If the inlet pressure at 1 is higher than the outlet pressure at 2, then the check valve allows the flow to pass, otherwise it
blocks the flow.

51. Check valve, spring loaded
If the inlet pressure at 1 is higher than the outlet pressure at 2 and the nominal pressure, then the check valve allows the flow
to pass, otherwise it blocks the flow.
s

52. Check valve with pilot control
If the entering pressure at connection 1 is higher that the outgoing pressure at 2, the check valve allows the flow to pass
freely. Other- wise, the valve stops the flow. Additionally, the check valve can be opened via the control line 12. This action
allows the flow to pass freely in both directions.

53. Check valve with pilot control, spring loaded
If the inlet pressure at 1 is higher than the outlet pressure at 2 and the nominal pressure, then the check valve allows the
flow to pass, otherwise it blocks the flow. Additionally, the check valve can be released using the pilot line 12, thus
enabling the flow in both directions.

54. Pilot to close check valve
If the inlet pressure at 1 is higher than the outlet pressure at 2, then the non-return valve allows the flow to pass, otherwise it
blocks the flow. Additionally, the non-return valve can be closed using the pilot line 10.
MODERN PNEUMATIC, ELECTROPNEUMATIC FUNDAMENTALS

55. Pilot to close check valve, spring loaded
If the inlet pressure at 1 is higher than the outlet pressure at 2 and the nominal pressure, then the non-return valve allows
the flow to pass, otherwise it blocks the flow. Additionally, the non-return valve can be closed using the pilot line 10.

56. Nozzle
The nozzle represents a pneumatic resistance.

57. Throttle valve
The setting of the throttle valve is set by means of a rotary knob. Please note that by the rotary knob no absolute resistance
value can be set. This means that, in reality, different throttle valves can generate different resistance values despite
identical settings.

58. Orifice
The orifice represents a pneumatic resistance.

59. Orifice, adjustable
The orifice represents a variable pneumatic resistance.

60. One-way flow control valve
The one-way flow control valve is made up of a throttle valve and a check valve. The check valve stops the flow from
passing in a cer- tain direction. The flow then passes though the throttle valve. The cross-section of the throttle is
adjustable via a regular screw. In the opposite direction the flow can pass through the check valve.

61. Pneumatic counter
The counter registers pneumatic signals starting at a predeter- mined number and counting backwards. If zero is
reached, then the counter releases an output signal. This output signal continues until the counter is reset either by hand
or from at signal at connec- tion 10.

62. Time delay valve, normally closed
The time delay valve is actuated by a pneumatic signal at port 1 after a preset time delay has elapsed. It is returned to the
normal position via return spring when the signal is removed. The time delay is infinitely adjustable by means of a regulating
screw. The time delay is reset automatically within 200 ms.

63. Time delay valve, normally open
MODERN PNEUMATIC, ELECTROPNEUMATIC FUNDAMENTALS

After the pilot signal is applied at port 10, a preset time elapses before the pneumatic timer is actuated. It returns to its
initial position via a return spring once the signal is removed. The time delay is infinitely adjustable by means of a
regulating screw. The time delay is reset automatically within 200 ms.

64. Ring sensor
The ring sensor is a non-contact pneumatic signal output module. It is supplied with low pressure at connection 1. If, due to
an object, the entering air flow is disturbed, a low pressure signal will be put out by connection 2. To simulate an object in
the air flow, as pre- sented above, simply click on the component during FluidSIM Simulation Mode.

Pressure Operated Switches

65. 2-way pressure regulator valve
The pressure regulator valve regulates the compressed air supply to the preset nominal pressure and equalizes pressure
fluctuations. The valve closes when the pressure at connection 2 exceeds the nominal pressure. The setting for the real
components is compo- nent dependent and cannot be changed.

2- way pressure regulator valve, adjustable
The pressure regulator valve regulates the compressed air supply to the preset nominal pressure and equalizes pressure
fluctuations. The valve closes when the pressure at connection 2 exceeds the nominal pressure.

66. Pressure regulator valve with manometer
The pressure control valve regulates the supplied pressure based on the adjustable operating pressure and the variations
in the pressure. The manometer displays the pressure at connection 2.
3- way pressure regulator valve
The pressure regulator valve regulates the compressed air supply to the preset nominal pressure and equalizes pressure
fluctuations. The compressed air is discharged via connection 3 when the pres- sure at connection 2 exceeds the nominal
pressure. The setting for the real components is component dependent and cannot be changed.

67. 3-way pressure regulator valve, adjustable
The pressure regulator valve regulates the compressed air supply to the preset nominal pressure and equalizes pressure
fluctuations. The compressed air is discharged via connection 3 when the pres- sure at connection 2 exceeds the nominal
pressure.

68. Closing pressure compensator
The pressure compensator represents a pressure dependent pneumatic resistance. The pressure compensator closes
when the pressure difference p3-p4 exceeds the nominal pressure. A pres- sure regulating valve is implemented by the
combination of connec- tions 2 and 3. The nominal pressure setting of the real components is component dependent and
cannot be changed.

69. Closing pressure compensator, adjustable
The pressure compensator represents a pressure dependent pneumatic resistance. The pressure compensator closes
when the pressure difference p3-p4 exceeds the nominal pressure. A pres- sure regulating valve is implemented by the
MODERN PNEUMATIC, ELECTROPNEUMATIC FUNDAMENTALS
combination of connec- tions 2 and 3.

70. Opening pressure compensator
The pressure compensator represents a pressure dependent pneumatic resistance. The pressure compensator opens
when the pressure difference p3-p4 exceeds the nominal pressure. A se- quence valve is implemented by the combination
of connections 1 and 3. The nominal pressure setting of the real components is component dependent and cannot be
changed.

71. Opening pressure compensator, adjustable
The pressure compensator represents a pressure dependent pneumatic resistance. The pressure compensator opens
when the pressure difference p3-p4 exceeds the nominal pressure. A se- quence valve is implemented by the combination
of connections 1 and 3.

Pressure Operated Switches

72. Analog pressure sensor
The pressure sensor measures the pressure and operates the pressure switch when the adjustable switching pressure
has been exceeded.

73. Vacuum switch
The vacuum switch operates the linked pressure switch, when the pressure falls below the adjustable switching pressure. If
the sym- bol is used as a pressure switch the respective switch is operated when the pressure exceeds the switching
pressure.

74. Differential pressure switch
The differential pressure switch can be employed as a pressure switch (connection P1), a vacuum switch (connection P2)
or as a differential pressure switch (P1-P2). The respective pneumatic to electric converter is operated when the
difference in pressure between P1-P2 exceeds the adjustable switching pressure.

Vacuum Technique

75. Vacuum suction nozzle
The vacuum suction nozzle creates its vacuum based on the ejector principle. In this case, compressed air flows from
connection 1 to 3

76. Vacuum suction nozzle
MODERN PNEUMATIC, ELECTROPNEUMATIC FUNDAMENTALS

The vacuum suction nozzle creates its vacuum based on the ejector principle. In this case, compressed air flows from
connection 1 to 3, creating a vacuum at connection 1v. A sucker can be connected to the vacuum connection 1v. Stopping
the input of compressed air at connection 1 stops any suction also.

77. Vacuum generator with ejector pulse
Vacuum generator with ejector pulse

78. Sucker
The sucker can be used in connection with the vacuum suction nozzle to suck in objects.

In order to put down or to lift the sucker in FluidSIM click on the component in simulation mode.

79. Suction gripper
Suction gripper with vacuum security valve.

80. Adjustable vacuum actuator valve
The vacuum actuator valve is employed through the conversion of a vacuum signal. As soon as the vacuum reaches the
adjustable value at connection 1v, the attached valve body is switched.

Valve Groups

81. Pressure sequence valve
The sequence valve is operated when the control pressure at con- nection 12 has been reached. The flow passes freely
from 1 to 2. Removing the signal allows the valve to return to its starting posi- tion through the use of a return spring.
Connection 1 is shut. The pressure of the control signal is infinitely adjustable via a pressure setting screw.

82. Time delay valve, normally closed
The time delay valve is made up of a pneumatically operated 3/2- way valve, a one-way flow control valve, and small air
accumulator. When the necessary pressure is reached at the control connection 12 of the unit, the 3/2-way valve
switches and the flow passes freely from 1 to 2.

83. Time delay valve, normally open
The time delay valve is made up of a pneumatically operated 3/2- way valve, a one-way flow control valve, and small air
accumulator. When the necessary pressure is reached at the control connection 10 of the unit, the 3/2-way valve switches
and stops the flow from passing between 1 and 2.

84. Stepper module, type TAA
The stepper module is made up of a memory unit (3/2-way impulse valve), an AND and an OR component, a viewable
MODERN PNEUMATIC, ELECTROPNEUMATIC FUNDAMENTALS
announcement, and an auxiliary manual operation.

85. Stepper module, type TAB
The stepper module is made up of a memory unit (3/2-way impulse valve), an AND and an OR component, a viewable
announcement, and an auxiliary manual operation.

86. Quickstepper
The Quickstepper is a ready to be fitted, mechanical/pneumatic control device with 12 in- and outputs. The outputs are
successive- ly synchronized with the input signals.

87. Two-hand control block ZSB
The two-hand control block ZSB is a pneumatic AND function.

Continuous valves

88. 5/3-way proportional valve
The proportional valve transforms an analog electrical input signal into corresponding opening cross-sections at the
outputs. At half nominal voltage i.e. 5 V, the pneumatic mid-position is taken. Here all leading edges are closed, so that no
air flows through the valve. Beneficial static and dynamic characteristics with minimal hystere- sis (less than 0,3 %), short
actuating time (typically 5 ms), and a higher upper frequency limit (approx. 100 Hz), are achieved
through an integrated electronic position control for the slide distance. Thus the valve, as control element and
especially in combination with a higher ranked position controller, is suitable for the positioning of a pneumatic cylinder.

Actuators

89. Configurable cylinder
The configurable cylinder can be customized via its properties dialog. Almost any combination of piston type (single-
acting, dou- ble-acting), the specification of the piston rods (double ended, with magnetic coupling or slide) and the
number (none, one, two) is possible. An end position cushioning (without, with, adjustable) can also be defined.
FluidSIM automatically adjusts the symbol according to the preset configuration. In addition, a load to be moved
(including possible static and sliding friction) and a variable force profile can be defined in the properties dialog. In the
compo- nent library of FluidSIM there are several pre-configured cylinders that can be inserted in your circuit and directly
used. Should no suitable symbol be available, then simply choose the component with the most similarity to the required
component, open the prop- erties dialog and adjust the configuration accordingly.

90. Single acting cylinder
The piston rod of a single acting cylinder is operated by the input of compressed air at the front end position. When the
compressed air is shut off, the piston returns to its starting position via a return spring. The piston of the cylinder
contains a permanent solenoid which can be used to operate a proximity switch.

91. Single acting cylinder with return spring
The piston of the single acting cylinder is extended to its back position by the input of compressed air. When the
compressed air is switched off, a return spring moves the piston back to its front position.
MODERN PNEUMATIC, ELECTROPNEUMATIC FUNDAMENTALS

92. Double acting cylinder
The piston rod of a double acting cylinder is operated by the recip- rocal input of compressed air at the front and back of the
cylinder. The end position damping is adjustable via two regular screws. The piston of the cylinder contains a permanent
solenoid which can be used to operate a proximity switch.

93. Double acting cylinder with in and out piston rod
The in and out piston rod of the double acting cylinder is controlled by alternating the compressed air input. The
cushioning can be adapted with two adjustment screws.

94. Double acting cylinder with two in and out piston rods and
single trestle.
This twin cylinder has two in and out piston rods that move in parallel and that are coupled by a trestle. The construction
guaran- tees minimum torsion when positioning and moving tools or as- semblies. Moreover, coming along with the
same construction height, the double piston rod conveys the double force as com- pared to standard cylinders.

95. Double acting cylinder with two in and out piston rods and
double trestle.
This twin cylinder has two in and out piston rods that move in parallel and that are coupled by a double trestle. The
construction
guarantees minimum torsion when positioning and moving tools or assemblies. Moreover, coming along with the
same construction height, the double piston rod conveys the double force as com- pared to standard cylinders.

96. Multiple position cylinder
By connecting two cylinders of same piston diameter but different maximum stroke three piston stop positions
can be realized. From the first stop position the third stop can be reached either directly or via the
intermediate stop. Note that the maximum stroke of the second piston must be larger than the preceding one.
When moving back, an intermediate stop requires a particular control. The shorter maximum stroke is half of
the other maximum stroke.

97. Linear drive with solenoid coupling
The sliding of the piston in the double rod cylinder is controlled by a reciprocal input of compressed air.

98. Pneumatic linear drive with shape-fitting adaptor
The sledge of the double acting cylinder without a piston rod is controlled by alternating the compressed air
input. This type of linear drive conveys forces by means of a shape-fitting piston- sledge construction. The
slitted cylinder prohibits the torsion of the slider.

99. Pneumatic linear drive with shape-fitting adaptor
The sledge of the double acting cylinder without a piston rod is controlled by alternating the compressed air
input. This type of linear drive conveys forces by means of a shape-fitting piston- sledge construction. The
slitted cylinder prohibits the torsion of the slider.
INDUSTRIAL AUTOMATION
MODULE 2 Modern Pneumatic, Electro Pneumatic Fundamentals

100. Air motor
The air motor transforms pneumatic energy into mechanical energy.

101. Semi-Rotary actuator
The semi-rotary actuator is controlled by a reciprocal input of compressed air. In the end positions the
semi-rotary actuator can activate switches or valves via labels.

Measuring Instruments

102. Manometer
The manometer displays the pressure at its connection.

103. Differential pressure gauge
The differential pressure gauge displays the pressure difference between the adjacent pressures at the left
and the right connection.

104. Pressure indicator
An optical signal is activated when the pressure at the connection to the pressure indicator exceeds the
preset switching pressure.

105. Pressure sensor, analog
This symbol represents the pneumatic part of the analog pressure sensor. The analog pressure sensor
measures the adjacent pres- sure and transforms it into a proportional electrical voltage signal. In the
process, only pressures in the specified pressure ranges are considered. Within this range, the pressure in
the voltage range from 0 V to 10 V is represented, i.e. the minimum pressure delivers 0 V and the maximum
pressure 10 V.

106. Analog pressure sensor
This symbol represents the pneumatic part of the analog pressure sensor.

107. Flow meter
The flow meter measures the flow rate. Either the current flow or the total quantity flowed can be displayed.
The component image is automatically adjusted accordingly

19
INDUSTRIAL AUTOMATION
MODULE 2 Modern Pneumatic, Electro Pneumatic Fundamentals

108. Flow meter, analog
This symbol represents the pneumatic part of the analog flow meter. The analog flow meter measures the
volumetric flow and transforms it into a proportional electrical voltage signal. In the process, only flow rates
in the specified pressure ranges are con- sidered. Within this range, the flow rate in the voltage range from 0
V to 10 V is represented, i.e. the minimum volumetric flow delivers 0 V and the maximum volumetric flow 10
V.

20