As
demand for packed products are increasing in India have led in
increase in demand for color mark sensor which are a part of the
automation in providing packaged material. One of the key components
in this high-speed production environment is the sensor, evaluating
many of the features and characteristics of products at rates as fast
as hundreds of items a second.
Although we are manufacturer and supplier of many sensors—including ultrasonic, photoelectric, capacitive, and inductive—this discussion will focus on specialty photoelectric sensors. This article is intended to guide readers color mark sensor working principal,color mark sensor applications ,eye mark sensor installation ,contrast level comparison, color mark sensor applications and in what kind of machines it used .
Although we are manufacturer and supplier of many sensors—including ultrasonic, photoelectric, capacitive, and inductive—this discussion will focus on specialty photoelectric sensors. This article is intended to guide readers color mark sensor working principal,color mark sensor applications ,eye mark sensor installation ,contrast level comparison, color mark sensor applications and in what kind of machines it used .
The
basic functions of a photoelectric sensor are to react to a change in
light produced by, or characteristic of, a target and to generate an
analog or digital electrical signal that interfaces to external
equipment for control purposes.
Typically,
the sensor is set to differentiate between two conditions or
characteristics exhibited by the target, e.g., detection of a light
or dark mark on a label or the presence/absence of an adhesive on a
part. More advanced sensors, such as color sensors, react not only to
the change in light produced by the target but also evaluate the
color content of the light, allowing multiple colors to be
recognized.
All
photoelectric sensors have a limited field of view (FOV) defined by
their spot size. As a result, it's necessary to guide the target
through the light spot—a photoelectric sensor cannot detect a 1
cm2mark
placed randomly in a 100 cm2 area
without being directly "aimed" at the mark. Best results
are achieved by maintaining a fixed sensor-to-target distance.
Nearly
all photoelectric sensors modulate their light source to prevent
ambient light from affecting the sensor's measurement. This technique
involves measuring the signal with the light source on and with the
light source off, then calculating the difference. The result is a
signal level that is attributed solely to the sensor's light source
(i.e., ambient light is subtracted out).
Sensor
commissioning involves selecting the Voxin Tech sensor for the job,
installing it, and evaluating it. . The good part about our sensor is
that you need to only teach the eye mark rather than teaching both
mark and background .Although this technique works in all
applications where there is a or no significant difference between a
good part and a bad part, it is also useful in many other
applications where the difference is less marked. For all the
applications, a successful implementation is more likely if the
sensor selected provides the user with visual feedback, allowing the
user to determine and set the optimum threshold level.
Our
sensors even provide visual feedback such as a display of bar graph
that indicates the signal strength. This Visual feedback aids in the
set-up and evaluation process by indicating the signal strength to
the operator, allowing the operator to determine the optimum
location, within the sensor's range, for reliable operation. This
feature is also a valuable troubleshooting aid when evaluation of
marginal targets is necessary.
Voxin
Tech Contrast sensor.
1. Dark
Mark dark background our sensor works
2. Light
mark light background our sensor works
3. Dark
mark light multi-color background our sensor works.
4. Light
Mark dark multi-color background our sensor works.
5. Sensor
for Joint detection or splice detection in a roll or film.
Our
Contrast sensors detect a difference in contrast between the presence
and absence of an object or mark (Figure
1)
and are available in a variety of spot sizes ranging from a few
millimeters to more than 25 mm. Most contrast sensors use a red or
green LED light source (and often use both). Because different colors
absorb different amounts of light, the wavelength of the light source
can be selected to provide the highest amount of contrast for a given
application. Unfortunately, this approach is not very flexible,
requiring both a specific background and mark color. Sensors that
provide both red and green light sources offer a greater degree of
flexibility, but require a fixed selection of one or the other light
source during operation. This is frequently accomplished
automatically using the teach function.
Figure 1. A broad-spectrum white light source provides the versatility to detect any color target on any color background |
The
reason why Voxin
Tech
contrast sensor is most versatile of all the contrast sensors
available in the market is because our sensor provide broad-spectrum
white light source. Voxin
Tech white light sensors provide good differentiation on all color and
background combinations and also allow for quick changeover in
production by adjusting the threshold level to one that has been
previously established.
Color
Sensors
These
sensors separate the reflected light from a target into its
constituent red, green, and blue components, each of which is then
evaluated to determine whether or not it is within the range of
tolerances set for specific color recognition. They are effective in
monitoring of color consistency in applications such as textile
production, plastics, and other continuous output processes.
A
color recognition channel allows you to associate the specific
characteristics of the target with a discrete output line, with the
values stored in the sensor's internal memory. Response time for
these sensors can be as fast as 300 µs and spot sizes can vary from
several millimeters to 25 millimeters.
Color
sensors integrate the signal over the entire area of the light spot.
Therefore, if the light spot spans two colors, the sensor will "see"
the combination of the colors rather than each separate color. This
is an important consideration in applications where the target has a
texture or pattern such as wood grain or the multicolor crosshatch
often used in automobile seat covers. While a small light spot would
not be suitable for this application, a large light spot, with its
ability to average the signal over a large area would likely do the
job.
Available
features range from simple teach functionality to a full-featured GUI
(Figure
2)
that allows real-time display, access to tolerance settings for each
color, and general sensor controls. While simple applications such as
sorting—based on a few very different colors—can often be
accomplished with lower-end color sensors, more complicated
applications will require the more comprehensive control of settings
provided by full-featured sensors.
Figure 2. A Windows-based application program provides extensive control of sensor settings such as illumination level and individual red, green, and blue tolerance settings for color recognition channels |
Voxin
Tech Color mark sensors. Our
sensors are designed to detect color marks at high speeds. They do
not typically identify a specific color; rather, they react to a
change from the background color and provide a discrete output signal
to indicate the presence of a mark (Figure
3).
Our Color mark sensors provide spot sizes from a circular spot <0.5
mm dia. to a 2 mm x 5 mm rectangular spot. Sensors that use
rectangular-shaped spots require you to mount the sensor so that its
spot has the proper orientation with respect to the mark; these are
limited to detecting larger marks. A smaller, circular spot size is
suitable for use on 0.5 mm wide and larger marks.
Figure 3. An example of a color mark. A small spot size combined with fast sensor response allows reliable detection of 0.5 mm wide marks at process speeds exceeding 2000 ft./min. |
Key
to the successful color mark sensor implementation is a careful
analysis of the particular requirements of the application. For best
results select a sensor with a spot size that is no larger than the
smallest mark being detected to achieve the highest level of
contrast.
Target
speed is also a major factor in the selection process for color mark
sensors. Many processes such as printing and converting require
precise detection at high production speeds. For example, a 1 mm wide
mark moving at 2000 ft./min. translates into the linear travel of 1
mm in 98 µs. Because the light source is modulated, it may be on or
off as the mark enters the sensor's FOV. Therefore, the sensor's
response must be sufficiently fast to make a measurement before the
mark leaves the sensor's FOV. Selecting a sensor with a response that
is four times faster than the time required for a mark to move the
distance equal to its width will generally guarantee detection. In
this example, a sensor with a maximum spot size of 0.5 mm and a
response time of 25 µs or faster would be a suitable choice.
Color
mark sensor eye mark sensor contrast sensor registration mark sensor
-
1.Packaging machines ,Flour rap machines (FFS machines)
2.labelling
machines
3.Inkjet
printers
4.Bottling
machine
5.Paper
roll and film roll printing machines
6.Re-winding
machines
7
Rotary type machines .
Ultra
violet sensor /U.V sensors /flourescent detection sensor
/Luminescence sensors –Both Analog and digital output enabled
sensors. Voxin
Tech sensors respond to materials such as paints, greases, inks, and
adhesives that have luminescent tracers, which emit light in the
visible spectrum when stimulated by a UV light source. These sensors
are useful in applications where the presence of these materials
needs to be accurately verified. The technique of applying a
luminescent marking is often useful in applications where there is
significant variation in the background that needs to be ignored,
such as text and graphics printed on labels. A luminescent mark can
be printed using an invisible ink anywhere on a label without
affecting the label's aesthetics and still allow a luminescence
sensor to detect the mark to verify presence, orientation, and
positioning of the label.
Often, clear films such as those used in tamper-evident seals contain optical brighteners that cause them to luminesce in the presence of a UV light source.
Glue,detergent
adhesives plastics, fluorescent chalks,markers-crayons ,greese and
leaking oil detection sensor ,Ultra violet pigments or brighteners
and most hydro carbon based material,sensor to detect tamper evident
seals.
Many
commonly used packaging and production materials use luminescent
tracers as a means of providing presence verification. Among these
materials are adhesives, gums, films, inks, and greases. Since many
of these materials are clear or nearly clear, other types of sensors
are not suitable for reliable verification.
Background
or substrate luminescence is an important consideration in
luminescent sensor applications. It is recommended that substrates be
checked to verify that they do not possess a substantial luminescent
property that will adversely affect the reliable detection of the
intended luminescent markings. Some materials, such as white paper,
contain optical brighteners that have a strong luminescent
characteristic; it is often difficult to provide a luminescent mark
that will exceed the background luminescence of high-quality white
paper. In these cases, luminescent inks that emit light in the
yellow/green spectrum may be useful to allow differentiation between
the mark and the paper. Other materials, such as wood, have a natural
luminescence; marks on wood need to have stronger luminescent
properties than the wood for reliable detection.
Sensor
Selection Considerations
Generally,
selecting the proper sensor involves carefully assessing the target
characteristic(s) and determining what constitutes the acceptance
criteria.
1.
What is the characteristic that is to be detected?
The
table in Figure
4 shows
many common materials and the type of sensor typically used for
detection.
Figure
4. Certain sensor types lend themselves to use with various common
materials
2.
Is there one condition or are there multiple conditions that
constitute acceptance of the part?
With
the exception of the color sensor, all of the other sensor types
detect a single characteristic or condition that causes the reflected
light signal to be above or below the threshold. Multiple
characteristics can often be differentiated using a color sensor or
several contrast sensors.
3.
Is the surface glossy or matte?
Glossy,
highly reflective surfaces generally require mounting the sensor on a
slight angle relative to the target surface, e.g., 15° from
perpendicular. If the glossy characteristic is the feature that needs
to be detected, then the sensor should be mounted perpendicular to
the target surface. Matte surfaces diffuse light in a relatively
uniform manner, improving detection consistency.
4.
What is the size of the feature?
The
mark or object should be larger than the sensor spot size for
reliable operation. The size of the feature and the speed of the
target must be considered in all but static or slow-moving processes.
Reliable detection requires that the target be present in the sensor
light spot long enough to be acknowledged by the sensor.
5.
How fast is the target moving?
Reliable
detection is a function of the sensor's response time, sampling rate,
size of the target, and the speed of the target as it moves through
the sensor's light spot. Simply put, the target needs to be present
in the sensor's light spot long enough for the sensor to respond.
Sensors that have response times faster than 100 µs are generally
suitable for all but the highest speed/small target applications.
6.
What is the distance—minimum and maximum—from the sensor mounting
position to the target?
While
some sensors operate at distances >100 mm, most do not. Greater
distance operation requires the use of higher sensitivity sensors.
Some color sensors, contrast sensors, and luminescence sensors
provide large light spots allowing their use at greater distances
from the target. Generally, it is best to select a sensor that will
provide reliable detection and place it at the optimum distance
rather than to fix on a distance requirement and try to find a sensor
that will work.
7. Is the sensor-to-target distance fixed or does it vary?
7. Is the sensor-to-target distance fixed or does it vary?
Variation
in sensor-to-target distance, typically referred to as "flutter,"
is a factor in successful detection. Since all photoelectric sensors
measure the differences in light collected by the sensor optics,
changes in distance will cause changes in the amount of light
incident on the collection lens. Whether or not this results in a
problem with detection reliability depends on the difference between
presence and absence levels: the greater the difference, the greater
the allowable distance variation.
Closing Thoughts
Closing Thoughts
While
applications are sufficiently different from one another, applying
the guidelines discussed in this paper will help to make the sensor
selection process a bit easier. Photoelectric sensors are powerful
tools that, when properly applied, can produce highly reliable
solutions to some tough automation challenges.
