Electro-Pneumatics PDF

Summary

This document provides an overview of electro-pneumatic systems, covering components like sensors, relays, and switches. The content explains the functions and operation of different types of electro-pneumatic systems, offering insights into the field of engineering.

Full Transcript

ELECTRO-
PNEUMATICS
BEE 417L
ELECTRO-PNEUMATICS

ELECTRO—PNEUMATIC TERM IS DEFINED FROM THE WORDS ELECTRO WHICH
MEANS ELECTRICAL AND PNEUMATIC WHICH MEANS PRESSURIZED AIR.
USED IN PRODUCTION, ASSEMBLY, PHARMACEUTICAL, CHEMICAL AND PACKAGING
SYSTEM.
COMMONLY USED IN MANY AREAS OF INDUSTRIAL LOW-COST AUTOMATION.
THE CONTROL OF PNEUMATIC COMPONENTS BY ELECTRICAL IMPULSES
(ELECTRICAL SIGNAL) IS KNOWN AS ELECTRO-PNEUMATIC.
THE ELECTRO-PNEUMATIC EQUIPMENT AND SYSTEM IS AN INTEGRATION OF
ELECTRICAL AND MECHANICAL COMPONENTS WITH A COMPRESSED AIR SOURCE.
ADVANTAGES

GREATER RELIABILITY
REDUCED INSTALLATION COMPLEXITY
THE CONTROL SYSTEM CAN BE EASILY MODIFIED
AND ADAPTED
EASY HANDLING
SECURE MOUNTING
ENVIRONMENTALLY-FRIENDLY COUPLING SYSTEM
IN ELECTRO PNEUMATIC CONTROLS, MAINLY
THREE IMPORTANT STEPS ARE INVOLVED

SIGNAL INPUT DEVICES
SIGNAL GENERATION SUCH AS SWITCHES AND CONTACTOR, VARIOUS TYPES
OF CONTACT AND PROXIMITY SENSORS.

SIGNAL PROCESSING
USE OF A COMBINATION OF CONTACTORS OF RELAY OR USING
PROGRAMMABLE LOGIC CONTROLLERS.

SIGNAL OUTPUTS
OUT PUTS OBTAINED AFTER PROCESSING ARE USED FOR ACTIVATION OF
SOLENOIDS, INDICATORS OR AUDIBLE ALARMS.
SIGNAL FLOW IN
ELECTROPNEUMATIC SYSTEM
SIGNAL FLOW IN
ELECTROPNEUMATIC SYSTEM
COMPONENTS OF ELECTRO-
PNEUMATIC SYSTEM

THE ELECTRO PNEUMATIC SYSTEM IS NORMALLY
CONSISTS OF THE FOLLOWING ITEMS:

1. DC POWER SUPPLY
2. SWITCHES
3. RELAYS
4. SOLENOID VALVES
5. SENSOR
POWER SUPPLY
SWITCHES

SWITCHES ARE INSTALLED IN AN ELECTRIC CIRCUIT
TO CONNECT OR INTERRUPT THE ELECTRIC
CURRENT.

CONTROL SWITCHES
PUSH BUTTON SWITCHES
PUSH BUTTON SWITCHES

THESE SWITCHES ARE ACTIVATED MANUALLY AND USED
CONNECT OR DISCONNECT THE ELECTRIC CURRENT IN
HE CONTROL CIRCUIT. THERE ARE THREE TYPED OF THE
PUSH BUTTON SWITCHES:

NORMALLY OPEN CONTACT(MAKE)
NORMALLY CLOSE CONTACT (BREAK)
CHANGEOVER CONTACT (TWO WAY)
NORMALLY OPEN CONTACT(MAKE)
NORMALLY CLOSE CONTACT (BREAK)
CHANGEOVER CONTACT (TWO WAY)
PUSH BUTTONS ARE OF TWO TYPES
I) MOMENTARY PUSH BUTTON
II) MAINTAINED CONTACT OR DETENT PUSH BUTTON
MOMENTARY PUSH BUTTONS RETURN TO THEIR UNACTUATED POSITION
WHEN THEY ARE RELEASED.
MAINTAINED (OR MECHANICALLY LATCHED) PUSH BUTTONS HAS A LATCHING
MECHANISM TO HOLD IT IN THE SELECTED POSITION.
THE CONTACT OF THE PUSH BUTTONS, DISTINGUISHED ACCORDING TO THEIR
FUNCTIONS,
I) NORMALLY OPEN (NO) TYPE
II) NORMALLY CLOSED (NC) TYPE
III) CHANGE OVER (CO) TYPE.
LIMIT SWITCHES
THE LIMIT SWITCH IS ACTUATED WHEN A MACHINE PART OR A
WORK-PIECE IS IN A CERTAIN POSITION. NORMALLY, ACTUATION
IS AFFECTED BY A CAM OR CYLINDER PISTON.
DETENT SWITCHES

THESE SWITCHES KEEP THE
SELECTED POSITION; THE
SWITCH POSITION
REMAINS UNCHANGED
UNTIL A NEW SWITCH
POSITION IS SELECTED. IT
IS CALLED DETENT SWITCH
OR A LATCHING SWITCH.
 LIMIT SWITCHES

ANY SWITCH THAT IS ACTUATED DUE TO THE POSITION OF A FLUID
POWER COMPONENT (USUALLY A PISTON ROD OR HYDRAULIC MOTOR
SHAFT OR THE POSITION OF LOAD IS TERMED AS LIMIT SWITCH. THE
ACTUATION OF A LIMIT SWITCH PROVIDES AN ELECTRICAL SIGNAL THAT
CAUSES AN APPROPRIATE SYSTEM RESPONSE. LIMIT SWITCHES
PERFORM THE SAME FUNCTION AS PUSH BUTTON SWITCHES. PUSH
BUTTONS ARE MANUALLY ACTUATED WHEREAS LIMIT SWITCHES ARE
MECHANICALLY ACTUATED.
LIMIT SWITCHES

LIMIT SWITCHES ARE NORMALLY CHANGEOVER CONTACTS AND
CAN BE CONNECTED ACCORDING TO THE REQUIRED CONTROL
CIRCUIT. THE LIMIT SWITCH CAN BE USED IN CIRCUIT ACCORDING
TO ONE OF THE FOLLOWING:

❖ NORMALLY OPEN SWITCH

❖ NORMALLY CLOSED SWITCH

❖ CHANGEOVER SWITCH
 LIMIT SWITCHES

THERE ARE TWO TYPES CLASSIFICATION OF LIMIT
SWITCHES DEPENDING UPON METHOD OF
ACTUATIONS OF CONTACTS
A) LEVER ACTUATED CONTACTS
B) SPRING LOADED CONTACTS
LEVER TYPE LIMIT SWITCHES
PRESSURE SWITCHES

A PRESSURE SWITCH IS A PNEUMATIC-ELECTRIC SIGNAL
CONVERTER. PRESSURE SWITCHES ARE USED TO SENSE A
CHANGE IN PRESSURE, AND OPENS OR CLOSES AN
ELECTRICAL SWITCH WHEN A PREDETERMINED PRESSURE IS
REACHED.
 TEMPERATURE SWITCH
TEMPERATURE SWITCHES AUTOMATICALLY SENSES A CHANGE IN
TEMPERATURE AND OPENS OR CLOSES AN ELECTRICAL SWITCH
WHEN A PREDETERMINED TEMPERATURE IS REACHED. THIS SWITCH
CAN BE WIRED EITHER NORMALLY OPEN OR NORMALLY CLOSED.
TEMPERATURE SWITCHES CAN BE USED TO PROTECT A FLUID
POWER SYSTEM FROM SERIOUS DAMAGE WHEN A A COMPONENT
SUCH AS A PUMP OR A STRAINER OR COOLER BEGINS TO
MALFUNCTION.
REED PROXIMITY SWITCHES

REED SWITCHES ARE MAGNETICALLY

ACTUATED PROXIMITY SWITCHES. REED

SWITCHES ARE SIMILAR TO RELAYS,

EXCEPT A PERMANENT MAGNET IS USED

INSTEAD OF A WIRE COIL
RELAYS
A RELAY IS DEFINED AS AN ELECTROMAGNETICALLY
ACTUATED SWITCH.
RELAYS

WHEN THE VOLTAGE IS APPLIED TO A
SOLENOID COIL TERMINALS (A1, A2) IN
IT WILL BECOME AN ELECTROMAGNET
WHICH IN TURN ATTRACTS THE
CONTACTS OF THE RELAY EITHER
CLOSING OR OPENING THEM. THE
SPRING RETURNS THE CONTACTS TO
THE INITIAL POSITION IMMEDIATELY
AFTER DISCONNECTING THE VOLTAGE
AT THE COIL TERMINALS.
 SOLENOIDS
ELECTRICALLY ACTUATED DIRECTIONAL CONTROL VALVES FORM THE INTERFACE
BETWEEN THE TWO PARTS OF AN ELECTRO-PNEUMATIC CONTROL. THE MOST
IMPORTANT TASKS OF ELECTRICALLY ACTUATED DCVS INCLUDE.
I) SWITCHING SUPPLY AIR ON OR OFF
II) EXTENSION AND RETRACTION OF CYLINDER DRIVES
ELECTRICALLY ACTUATED DIRECTIONAL CONTROL VALVES ARE SWITCHED WITH THE AID
OF SOLENOIDS. THEY CAN BE DIVIDED INTO TWO GROUPS:
I) SPRING RETURN VALVES ONLY REMAIN IN THE ACTUATED POSITION AS LONG AS
CURRENT FLOWS THROUGH THE SOLENOID
II) DOUBLE SOLENOID VALVES RETAIN THE LAST SWITCHED POSITION EVEN WHEN NO
CURRENT FLOWS THROUGH THE SOLENOID.
3/2 WAY SINGLE SOLENOID VALVE,
SPRING RETURN
2/2 SOLENOID OPERATED VALVE
5/2 WAY SINGLE SOLENOID VALVE,
SPRING RETURN
5/2 WAY SINGLE DOUBLE SOLENOID
VALVE
THE SYMBOLS FOR THE VARIOUS
SOLENOID/PILOT ACTUATED VALVES
 RELAYS
A RELAY IS AN ELECTRO MAGNETICALLY ACTUATED SWITCH. IT IS A SIMPLE
ELECTRICAL DEVICE USED FOR SIGNAL PROCESSING. RELAYS ARE DESIGNED
TO WITHSTAND HEAVY POWER SURGES AND HARSH ENVIRONMENT
CONDITIONS. WHEN A VOLTAGE IS APPLIED TO THE SOLENOID COIL, AN
ELECTROMAGNET FIELD RESULTS. THIS CAUSES THE ARMATURE TO BE
ATTRACTED TO THE COIL CORE. THE ARMATURE ACTUATES THE RELAY
CONTACTS, EITHER CLOSING OR OPENING THEM, DEPENDING ON THE
DESIGN. A RETURN SPRING RETURNS THE ARMATURE TO ITS INITIAL
POSITION WHEN THE CURRENT TO THE COIL IS INTERRUPTED.
CROSS SECTIONAL VIEW OF A RELAY
 TIMER OR TIME DELAY RELAYS

TIMERS ARE REQUIRED IN CONTROL SYSTEMS TO EFFECT TIME
DELAY BETWEEN WORK OPERATIONS. THIS IS POSSIBLE BY
DELAYING THE OPERATION OF THE ASSOCIATED CONTROL ELEMENT
THROUGH A TIMER. MOST OF THE TIMERS WE USE IS ELECTRONIC
TIMERS. THERE ARE TWO TYPES OF TIME RELAY

I) PULL IN DELAY ( ON –DELAY TIMER)
II) DROP –OUT DELAY (OFF DELAY TIMER)
 TIMER OR TIME DELAY RELAYS

IN THE ON-DELAY TIMER, SHOWN IN FIGURE CC, WHEN PUSH BUTTON PB IS PRESSED (ON), CAPACITOR C IS

CHARGED THROUGH POTENTIOMETER R1 AS DIODE D IS REVERSE –BIASED. THE TIME TAKEN TO CHARGE THE

CAPACITOR, DEPENDS ON THE RESISTANCE OF THE POTENTIOMETER (R1) AND THE CAPACITANCE(C) OF THE

CAPACITOR. BY ADJUSTING THE RESISTANCE OF THE POTENTIOMETER, THE REQUIRED TIME DELAY CAN BE SET.

WHEN THE CAPACITOR IS CHARGED SUFFICIENTLY, COIL K IS ENERGIZED, AND ITS CONTACTS ARE OPERATED

AFTER THE SET TIME DELAY. WHEN THE PUSH BUTTON IS RELEASED (OFF), THE CAPACITOR DISCHARGES QUICKLY

THROUGH A SMALL RESISTANCE (R2) AS THE DIODE BY PASSES RESISTOR R1, AND THE CONTACTS OF RELAY (K)

RETURN TO THEIR NORMAL POSITION WITHOUT ANY DELAY.
 TIMER OR TIME DELAY RELAYS

IN THE OFF-DELAY TIMER, THE CONTACTS ARE OPERATED

WITHOUT ANY DELAY WHEN THE PUSH BUTTON IS PRESSED

(ON).

THE CONTACTS RETURN TO THE NORMAL POSITION AFTER

THE SET DELAY WHEN THE PUSH BUTTON IS RELEASED

(OFF
ELECTRONIC SENSORS

INDUCTIVE, OPTICAL AND CAPACITIVE PROXIMITY SWITCHES ARE
ELECTRONIC SENSORS. THEY NORMALLY HAVE THREE ELECTRICAL
CONTACTS. ONE CONTACT FOR SUPPLY VOLTAGE , OTHER FOR GROUND
AND THIRD FOR OUTPUT SIGNAL. IN THESE SENSORS, NO MOVABLE
CONTACT IS SWITCHED. INSTEAD, THE OUTPUT IS EITHER ELECTRICALLY
CONNECTED TO SUPPLY VOLTAGE OR TO GROUND. THERE ARE TWO
TYPES OF ELECTRONIC SENSORS WITH REGARD TO THE POLARITY
OF OUTPUT VOLTAGE.
POSITIVE SWITCHING SENSORS: IN THIS OUTPUT VOLTAGE IS
ZERO IF NO PART IS DETECTED IN THE PROXIMITY. THE
APPROACH OF A WORK PIECE OR MACHINE PART LEADS TO
SWITCH OVER OF THE OUTPUT, APPLYING THE SUPPLY
VOLTAGE.
NEGATIVE SWITCHING SENSORS: IN THIS THE SUPPLY VOLTAGE
ARE APPLIED TO THE OUTPUT IF NO PART IS DETECTED
IN THE PROXIMITY. THE APPROACH OF A WORK PIECE OR
MACHINE PART LEADS TO SWITCH OVER OF THE OUTPUT,
SWITCHING THE OUTPUT VOLTAGE TO 0 VOLTS.
A) INDUCTIVE SENSORS
INDUCTIVE SENSOR USE CURRENTS INDUCED BY MAGNETIC
FIELD TO DETECT THE NEARBY METAL OBJECTS
A) INDUCTIVE SENSORS
INDUCTIVE SENSOR USE CURRENTS INDUCED BY MAGNETIC
FIELD TO DETECT THE NEARBY METAL OBJECTS
FACTORS INFLUENCES THE SENSING DISTANCE
THE SWITCHING DISTANCE OF INDUCTIVE SENSORS DEPENDS ON THE CONDUCTIVITY
AND PERMEABILITY OF THE METAL PART WHOSE PRESENCE OR ABSENCE TO BE
DETECTED

ANOTHER FACTOR WHICH AFFECTS THE SENSING RANGE OF INDUCTIVE SENSORS IS THE DIAMETER
OF SENSING COIL. A
SMALL SENSOR WITH A COIL DIAMETER 0F 18MM HAS A TYPICAL RANGE OF 1MM, WHILE A LARGE
SENSOR WITH
CORE DIAMETER OF 75MM HAS A SENSING RANGE UP TO 50MM OR EVEN MORE
FACTORS INFLUENCES THE SENSING DISTANCE
THE SWITCHING DISTANCE OF INDUCTIVE SENSORS DEPENDS ON THE CONDUCTIVITY
AND PERMEABILITY OF THE
METAL PART WHOSE PRESENCE OR ABSENCE TO BE DETECTED

ANOTHER FACTOR WHICH AFFECTS THE SENSING RANGE OF INDUCTIVE SENSORS IS THE
DIAMETER OF THE SENSING COIL. A SMALL SENSOR WITH A COIL DIAMETER 0F 18MM
HAS A TYPICAL RANGE OF 1MM, WHILE A LARGE SENSOR WITH CORE DIAMETER OF
75MM HAS A SENSING RANGE UP TO 50MM OR EVEN MORE
B) CAPACITIVE SENSORS
CAPACITIVE SENSORS ARE ABLE TO DETECT MOST MATERIALS AT
DISTANCES UP TO A FEW CENTIMETRES.
C) OPTICAL PROXIMITY SENSORS
LIGHT SENSORS HAVE BEEN USED FOR ALMOST A CENTURY - ORIGINALLY PHOTOCELLS
WERE USED FOR APPLICATIONS SUCH AS READING AUDIO TRACKS ON MOTION
PICTURES. BUT MODERN OPTICAL SENSORS ARE MUCH MORE SOPHISTICATED
OPTICAL SENSORS REQUIRE BOTH A LIGHT SOURCE (EMITTER) AND DETECTOR.
OPPOSED MODE OPTICAL SENSOR
EMITTER AND DETECTOR IN ONE

UNIT
 POLARIZED LIGHT IN

RETROREFLECTIVE SENSORS
DIFFUSE SENSORS
DIFFUSE SENSORS USE LIGHT FOCUSED OVER A GIVEN RANGE, AND A
SENSITIVITY ADJUSTMENT IS USED TO SELECT A DISTANCE. THESE
SENSORS ARE THE EASIEST TO SET UP, BUT THEY REQUIRE WELL
CONTROLLED CONDITIONS. FOR EXAMPLE IF IT IS TO PICK UP LIGHT
AND DARK COLORED OBJECTS PROBLEMS WOULD RESULT.
DIFFUSE SENSOR
ELECTRIC COUNTERS
AN ELECTRIC COUNTER CONSIST OF A COIL, ASSOCIATED CIRCUITS AND
CONTACTS, A RESET COIL, MANUAL RESET, RELEASE BUTTON AND A DISPLAY
WINDOW. PRESSURE THE RELEASE BUTTON OF THE COUNTER AND
ENTERING THE DESIRED COUNT VALVE SET THE PRE-DETERMINING
COUNTER. THE PRE-DETERMINED COUNT VALVE IS DISPLAYED IN THE
WINDOW.
THERE ARE TWO TYPES OF COUNTERS
1. UP COUNTER
2. DOWN COUNTER
UP COUNTER

AN UP COUNTER COUNTS ELECTRICAL SIGNAL UPWARDS
FROM ZERO. FOR EACH ELECTRICAL COUNTING PULSE
INPUT TO AN UP-COUNTER COIL, THE COUNTER VALUE IS
INCREMENTED BY 1. WHEN THE PREDETERMINED VALVE
HAS BEEN REACHED, THE RELAY PICKS UP AND THE
CONTACT SET IS ACTUATED
UP COUNTER
DOWN COUNTER

AN DOWN COUNTER COUNTS ELECTRICAL SIGNAL DOWNWARDS FROM
PRESET VALVE. IF THE COUNT VALVES OF ZERO IS REACHED THE RELAY
PICKS UP AND THE CONTACT SET IS ACTUATED. THE COUNTER CAN BE
RESET MANUALLY BY PRESSING THE RESET BUTTON OR ELECTRICALLY
BY APPLYING A RESET PULSE TO THE RESET COIL. THE PRE-DETERMINED
VALUE IS MAINTAINED WHEN THE COUNTER IS RESET.
DOWN COUNTER
SAFETY OPERATION
DIRECT CONTROL OF SINGLE ACTING CYLINDER
INDIRECT CONTROL OF SINGLE ACTING CYLINDER
INDIRECT CONTROL OF SINGLE ACTING CYLINDER