A Guide to Photoelectric Sensors

In this section, we will look a little more closely at precisely how through-beam sensors, diffuse sensors and retroreflective sensors work.

A thru-beam or through-beam photoelectric sensor uses two separate modules to function, namely a transmitter and a receiver. These are positioned at either side of the area or object that the sensor is detecting. In most cases, this can either be a very small space, or a wider span.

The transmitter will emit a beam of infrared light in the direction of the receiver. The module can then determine whether any physical object is positioned in the path of the beam.

Certain models of through-beam sensors have more specialised uses and features, for example, the ability to isolate objects from their surroundings. This is known as background suppression. Background suppression can be very useful in environments where there’s a high degree of reflection, which may otherwise make it difficult to detect the true path of a light beam.

Advantages of a through-beam sensor include:

• Stable and reliable readings across a wide range of operational distances
• Ability to detect objects in a wide range of materials, colours, and positions
• No adverse effect on reading accuracy will usually be caused by changes in the light source or the movement or path of the object being sensed

Limitations of a through-beam sensor can include a more complex installation process since there will be wiring required at both ends.

A retro-reflective photoelectric sensor uses a separate reflecting module positioned on the other side of the area, span or objects being monitored. This bounces the emitted light beam back towards the transmitter module, which also houses the photosensor. A reading that interprets the intensity and behaviour of the reflected light is then taken back at the source.

Advantages of retroreflective sensors include:

• A relatively wide range of operating distances
• Easier to install and adjust, since only one end of the device requires wiring in - the reflector typically requires no power
• Not particularly affected by object colour or movement path
• Ability to detect translucent or transparent objects, since the light beam travels through the object twice

Limitations of retroreflective sensors include a potential dead zone at a very short range and the fact that they cannot be used to detect highly reflective objects. The latter is because the amount of light bouncing back from anything mirror-like would make it appear that no object was present.

A diffuse-reflective or diffuse sensor uses the fact that objects in the path of the transmitted beam will themselves reflect a certain amount of light at the sensor.

In other words, they work similarly to a retroreflective model, except they are self-contained and do not use a separate reflecting module. Instead, they simply detect how much light is thrown back after hitting an object. In the normal detecting mode, the diffuse sensor usually does not expect to receive any light back - when it does, this usually indicates an error state.

Advantages of diffuse sensors include:

• A wide range of operational distances (although it is less common for these types to be used at long range)
• Easy to mount and adjust, since the transmitter and receiver are again housed in the same module

Limitations of the diffuse-reflective sensor include the fact that the reliability of readings can be more easily impacted by the object’s shape, colour, material, and distance, as well as by various other environmental conditions. In short, for an object to be detected reliably, it must be able to bounce a reasonable amount of light back at the photosensor.

The majority of photoelectric sensor accessories are designed to improve the performance of sensors or to make mounting, installation and adjustment of the various sensor types easier. Performance-related accessories include items such as power supplies and adaptors while mounting and installation accessories include things like reflectors, reflective tape, and various sorts of plastic fibre-optic (or more heavy-duty glass fibre) cabling.

Numerous types of photoelectric sensor mounting brackets are sold online, to suit various sensor models and mounting locations.

Different mounting brackets can provide the ability for installers to affix different sensors in a range of positions - common options include axial, right-angled and swivel-mount installations. Popular materials for mounting brackets include plastic and plated or stainless steel, again depending on the type and location of install you are doing.

Photoelectric sensor reflectors and reflective tape are used for retroreflective sensors, which rely on bouncing the light beam back from the transmitter to the receiver. Different reflector materials can be chosen for better accuracy in detecting certain types of objects, although many are designed for multipurpose detection.

Physical reflectors are intended for more robust permanent installation and will often be better suited to use in more challenging industrial environments. Many models will include a high IP rating, and be designed specifically to withstand aggressive cleaning products and other potential sources of a chemical attack.

Photoelectric sensor reflective tape is more commonly chosen in scenarios where the installation is temporary. It can also be much cheaper and more convenient if you will frequently need to reposition or replace the reflector module due to various other environmental challenges.