What is a Photomicro Sensor?
Features
Photomicro Sensors have the following advantages over ordinary Photoelectric Sensors with built-in amplifiers
Many Different Shapes in One Model Series
The EE-SX67 Series, for example, has models with eight different slot configurations, allowing the customer to choose the best configuration for the installation position.
Low Price
Ratings and performances are limited to those required for building into equipment, and the required IP degree of protection is easier to achieve, making prices very reasonable.
Downsizing Is Possible with the Sensing Distances Required for Building into Equipment
The standard sensing distances (slot width) are specifically intended to be used for building into equipment. Slot-type Sensors, for example, have a 3.6 mm or 5 mm sensing distance. Diffuse-reflective and Limited Reflective Sensors have a sensing distance of less than 5 mm, and Retroreflective and Through-beam Sensors, have less than 1m.
Indicator Lighting Mode
The indicator on many Photomicro sensors lights when light is incident. Some Photomicro sensors have specific models on which the indicator lights when light is interrupted. When lighting the indicator for position adjustment applications of Slot-type Sensors, for example, it may be more convenient to use a model that lights the indicator when light is interrupted. When using the indicator to check the power supply status, on the other hand, it may be convenient to use a model that lights the indicator when the light is incident.
Other Specifications: Degree of Protection and Output Current
A waterproof structure is not required because it is assumed that the Photomicro sensors will be built into other equipment, and the output current rating can be kept low. Also, most models can operate on a 5-VDC power supply.
Operating Principles
1. Properties of Light
Rectilinear Propagation
When light travels through air or water, it always travels in a straight line. The slit on the outside of a Through-beam Sensor that is used to detect small objects is an example of how this principle is applied to practical use.
Refraction
Refraction is the phenomenon of light being deflected as it passes obliquely through the boundary between two media with different refractive indices.
Reflection (Regular Reflection, Retroreflection, and Diffuse Reflection)
A flat surface, such as glass or a mirror, reflects light at an angle equal to the incident angle of the light. This kind of reflection is called regular reflection. Retroreflectors (also called a corner cube) take advantage of this principle by arranging three flat surfaces perpendicular to each other. “Retro” means “to return toward the source.” The light reflected off the reflectors travels back towards the emitter, thus the term “retroreflective”.
Matte surfaces, such as white paper, reflect light in all directions. This scattering of light is called diffuse reflection. This principle is the sensing method used by Diffuse-reflective Sensors.
2. Light Sources
Light Generation
Non-modulated Light
Non-modulated light facilitates high-speed response by continuously radiating a constant amount of light. There is the drawback, however, of susceptibility to external light interference.
Modulated Light
Modulated light is not affected by sunlight, light from incandescent bulbs, and other external light interference. An LED emitter is pulse-lighted, and the received signal is processed to remove the DC component.
Classification
Classification by Sensing Method
(1) Slot Sensors
Slot Sensors are suitable for applications using a thin sensing object, or “dog,” that require a highly precise sensing position. Setup is easy because no optical axis adjustment is needed. There are many product variations. The necessary configuration, connection method, and other items can be selected from a wide array of models.
(2) Through-beam Sensors
Through-beam Sensors are suitable for applications that require relatively long sensing distances.
(3) Retroreflective Sensors
Retroreflective Sensors are suitable for applications that require relatively long sensing distances. They have the advantage of requiring less work for wiring and optical axis adjustment when compared to Through-beam Sensors.
(4) Diffuse-reflective Sensors
Diffuse-reflective Sensors are suitable for applications where the sensing object is thick and won’t fit into the slot of a Slot Sensor.
(5) Limited-reflective Sensors
Limited-reflective Sensors are basically the same as Diffuse-reflective Sensors, but they are suitable when background objects are present. (With Diffuse-reflective Sensors, the presence of a background object with a higher reflectivity than the sensing object (e.g., metals with mirror finishing) may cause sensing instability.)
Considerations when Choosing a Sensing Method
(1) Slot Sensors
- Shape, slot width, connection (pre-wired/connector)
- Presence or absence of external light interference (nonmodulated light/modulated light)
- Output configuration (Light-ON/Dark-ON, NPN/PNP)
- Indicator (Light-ON/Dark-ON)
(2) Through-beam Sensors
- Shape, sensing distance
- Output configuration (Light-ON/Dark-ON)
(3) Retroreflective Sensors
- Sensing distance
- Output configuration (Light-ON/Dark-ON)
(4) Diffusive/Limited-reflective Sensors
- Shape, sensing distance
- Presence or absence of background objects (Diffusereflective/Limited-reflective Sensors)
- External light interference (non-modulated light/modulated light)
- Output configuration (Light-ON/Dark-ON)
Interested to purchase our OMRON Photomicro Sensor? Feel free to contact us!