Proximity sensors Optical – Through-beam Inductive Capacitive

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Presentation transcript:

Proximity sensors Optical – Through-beam Inductive Capacitive Optical – Retro-reflective Reed switch Symbols Optical - Diffuse Inductive magnetic Connection

Optical sensors (Through-beam) Type : Through-beam

Optical sensors (Through-beam) Type : Through-beam Transmitter Receiver

Optical sensors (Through-beam) Type : Through-beam Transmitter Receiver

Optical sensors (Through-beam) Type : Through-beam Target Transmitter Receiver

Optical sensors (Through-beam) Type : Through-beam Transmitter Receiver

Optical sensors (Through-beam) Type : Through-beam Transmitter Receiver

Optical sensors (Through-beam) Type : Through-beam Transmitter Receiver

Optical sensors (Through-beam) Type : Through-beam Transmitter Receiver

Optical sensors (Through-beam) Type : Through-beam Transmitter Receiver

Optical sensors (Through-beam) Type : Through-beam Transmitter Receiver

Optical sensors (Through-beam) Type : Through-beam Transmitter Receiver

Optical sensors (Through-beam) Type : Through-beam Transmitter Receiver

Optical sensors (Through-beam) Type : Through-beam Target Transmitter Receiver Long sensing distance: up to 30 metres with some devices Will detect all but very transparent materials Must be accurately aligned

Optical sensors (Retro-reflective)

Optical sensors (Retro-reflective) Type : Retro reflective T R Transmitter /Receiver Reflector (prismatic)

Optical sensors (Retro-reflective) Type : Retro reflective T R Transmitter /Receiver Reflector (prismatic)

Optical sensors (Retro-reflective) Type : Retro reflective T R Transmitter /Receiver Reflector (prismatic)

Optical sensors (Retro-reflective) Type : Retro reflective Target T R Transmitter /Receiver Reflector (prismatic)

Optical sensors (Retro-reflective) Type : Retro reflective T R Transmitter /Receiver Reflector (prismatic)

Optical sensors (Retro-reflective) Type : Retro reflective T R Transmitter /Receiver Reflector (prismatic)

Optical sensors (Retro-reflective) Type : Retro reflective T R Transmitter /Receiver Reflector (prismatic)

Optical sensors (Retro-reflective) Type : Retro reflective T R Transmitter /Receiver Reflector (prismatic)

Optical sensors (Retro-reflective) Type : Retro reflective T R Transmitter /Receiver Reflector (prismatic)

Optical sensors (Retro-reflective) Type : Retro reflective T R Transmitter /Receiver Reflector (prismatic)

Optical sensors (Retro-reflective) Type : Retro reflective T R Transmitter /Receiver Reflector (prismatic) Sensing distance : 1/2 to 1/3 of through-beam type Not suitable for reflective or transparent targets Target should be larger than the reflector

Optical sensors (Diffuse) Type : Diffuse

Optical sensors (Diffuse) Target Type : Diffuse T R Transmitter /Receiver

Optical sensors (Diffuse) Type : Diffuse T R Transmitter /Receiver

Optical sensors (Diffuse) Type : Diffuse T R Transmitter /Receiver

Optical sensors (Diffuse) Type : Diffuse T R Transmitter /Receiver

Optical sensors (Diffuse) Type : Diffuse T R Transmitter /Receiver

Optical sensors (Diffuse) Type : Diffuse T R Transmitter /Receiver

Optical sensors (Diffuse) Type : Diffuse T R Transmitter /Receiver Sensing distance: much less than reflex type, actual distance depends on colour and reflective nature of the surface Larger targets result in longer sensing distances Not suitable for dirty environments

Inductive sensors

Inductive sensors High frequency magnetic field (300 to 800 kHz) Active surface Resonant circuit coil LED indicator Connection cable

Inductive sensors Target Sensor Oscillation Amplitude Sensor output signal ON OFF

Inductive sensors Target Sensor Oscillation Amplitude Sensor output signal ON OFF

Inductive sensors Target Sensor Oscillation Amplitude Sensor output signal ON OFF

Inductive sensors Target Sensor Oscillation Amplitude Sensor output signal ON OFF

Inductive sensors Target Sensor Oscillation Amplitude Sensor output signal ON OFF

Inductive sensors Target Sensor Oscillation Amplitude Sensor output signal ON OFF

Inductive sensors Target Sensor Oscillation Amplitude Sensor output signal ON OFF

Inductive sensors Target Sensor Oscillation Amplitude Sensor output signal ON OFF

Inductive sensors Target Sensor Oscillation Amplitude Sensor output signal ON OFF

Inductive sensors Will detect any conductive material Quoted distances are for mild steel Sensor performance can be affected by: Temperature Target material Target dimensions

Reed switch

Reed switch Glass Tube filled with nitrogen Reed contacts LED indicator

Reed switch

Reed switch

Reed switch

Reed switch

Reed switch

Reed switch

Reed switch 24v

Reed switch 24v

Reed switch Interference from other magnetic fields must be avoided. If positioned in mid stroke, switching point will vary depending on direction of approach. Maximum current must be limited to avoid burning of the reed contacts.

Inductive magnetic sensor

Inductive magnetic sensor Connection cable Resonant circuit coil High frequency magnetic field LED Indicator

Inductive magnetic sensor

Inductive magnetic sensor

Inductive magnetic sensor

Inductive magnetic sensor

Inductive magnetic sensor

Inductive magnetic sensor

Inductive magnetic sensor Inductive principle of operation - but only reacts to magnetic fields Interference from other magnetic fields must be avoided. Solid state device - higher switching frequency - 1kHz

Capacitive sensor

Capacitive sensor Electrostatic field Sensor is looking for a change in capacitance in the active field Active surface Active electrode Earth electrode LED indicator Adjusting screw Connection cable

Capacitive sensor Target

Capacitive sensor

Capacitive sensor

Capacitive sensor

Capacitive sensor Detects any material denser than air (as long as there is enough of it) Can be adjusted for sensitivity Can be affected by dusty environments

Capacitive sensor Sensor is adjusted so that it does not ‘see’ the wall of the vessel.

Capacitive sensor As the level rises the fluid affects the sensor field.

Capacitive sensor Until the sensor switches.

Sensor symbols

Sensor symbols Inductive Capacitive + 18 to 30 Volts DC. Optical Output Magnetic Ultrasonic Normally open 0 V Normally closed

Sensor symbols Capacitive Sensor with Normally open function + 18 to 30 Volts DC. Output 0 V

Sensor connection

Sensor connection PNP Type Output is Positive Positive switching 24v DC PNP Type Output is Positive Positive switching + 18 to 30 Volts DC Output 0 V 0v

Sensor connection NPN Type Output switches through to 0v 24v DC NPN Type Output switches through to 0v Negative switching + 18 to 30 Volts DC Output 0 V 0v

Sensor connection

Sensor connection Inductive Capacitive + 18 to 30 Volts DC. Optical Output Magnetic Ultrasonic Normally open 0 V Normally closed

Inductive sensor Target Will detect any conductive material Quoted distances are for mild steel Sensor performance can be affected by:- Temperature Target material Target dimensions. Sensor Oscillation Amplitude Sensor output signal ON OFF

Capacitive sensor Detects any material denser than air. (as long as there is enough of it) Can be adjusted for sensitivity Can be affected by dusty environments

Optical sensors Type: Through-beam Long sensing distance : up to 30 metres with some devices Will detect all but very transparent materials Must be accurately aligned Target Transmitter Receiver

Optical sensors Type: Retro-reflective Sensing distance : 1/2 to 1/3 of through-beam type. Not suitable for reflective or transparent targets Target should be larger than the reflector T R Transmitter / Receiver Reflector (prismatic)

Optical sensors Type : Diffuse Sensing distance : much less than reflex type, actual distance depends on colour and reflective nature of the surface Larger targets result in longer sensing distances Not suitable for dirty environments T R Transmitter / Receiver

Reed switch Interference from other magnetic fields must be avoided. If positioned in mid stroke, switching point will vary depending on direction of approach. Maximum current must be limited to avoid burning of the reed contacts.

Inductive magnetic sensor Inductive principle of operation - but only reacts to magnetic fields Interference from other magnetic fields must be avoided Solid state device - higher switching frequency - 1kHz