| Industrial Safety
Systems |
| In automated
production and logistics, effective accident and personnel protection is top
priority. As a specialist in sensor manufacturing, SICK has developed and
manufactured over many years pioneering products for safeguarding hazardous
zones and for access protection. |
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| Opto-electronic protective device |
| Intelligent, opto-electronic safety devices like laser
scanner, light grids and light curtains can be used for safeguarding dangerous
points, hazardous areas and access control – both vertically and horizontally.
These non-contact devices are selfmonitoring, can be tested and they correspond
with worldwide safety standards. |
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| Non-contact safety switches |
| Stricter safety regulations, and the need for tamper-proof
safety at work, now make modern safety switches indispensable. Interlock
expertise from SICK opens up numerous new opportunities for use. |
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| Electromechanical safety switches |
| SICK products easily withstand harsh conditions such as
impacts and vibrations. Opening, closing and locking is reliably guaranteed over
a long lifetime. SICK safety switches are available in plastic or metal
versions. |
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| Safety control solution |
| There is a growing importance put on integrating
intelligent safety systems in automated environments. With intelliface, the
intelligent interface technology for safety engineering. SICK provides you with
a whole range of interface products that were developed especially for linking
to safety products and machinery. |
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| Industrial Sensors,
Machine Vision and Data Transmission |
| The SICK Range: as
diverse as the tasks that they are expected to perform Detecting, counting,
classifying and position objects; identifying shape, position, differenced in
colour and surface characteristics; checking the presence of objects;
controlling processes using colour contrasts; detecting the invisible markings;
the SENSICK range of optical and inductive sensors is as diverse as the tasks
they are expected to perform. |
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| Encoder from SICK|STEGMANN |
High-precision displacement and angle measurement.
- Incremental encoders
- Single turn absolute encoders
- Multiturn absolute encoders
- I ncremental wire draw encoder
- Absolute wire draw encoders
- Linear Encoder |
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| Motor Feedback System |
The SinCos® und DiCoder® motor feedback
systems are used worldwide in many different applications and environments.
Writing motor-specific data to the electronic type label and programming are
important features of these series. |
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Positioning Drive
Integral Drive |
| This HIPERDRIVE® format adjustment drive is the result of
the logical and complete integration of power gearbox, brushless DC motor,
absolute value encoder and the control and power electronics in one drive. |
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| Ultrasonic Sensor |
SICK’s ultrasonic sensors UM 30 and UM 18 detect objects
and measure distances with high accuracy.
- Ultrasonic proximity switch
- Ultrasonic double-sheet detection |
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| Inductive Proximity Sensor |
| High switching frequencies and high continuous currents
characterize many SICK inductive sensors. They are available as DC2-wire
conductors, DC3-wire conductors, DC4-wire conductors, AC/DC2-wire conductors,
AC2-wire conductors and NAMUR sensors in accordance with EN 50 227. |
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| Capacitive proximity sensor |
Capacitive proximity sensors are able to detect both
non-metallic as well as metallic objects. Capacitive proximity sensors can for
example be used in the following applications:
- level control
- presence control
- level control of bulk solids
- final inspection of packaging procedures |
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| Magnetic Proximity Sensor |
Magnetic sensors have a broad range of applications. For
example:
- Object detection through plastic containers/pipes
- Object detection in aggressive media through protective Teflon walls
- Object detection in high-temperature areas
- Pig technology
- Recognition of coding using magnets |
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| Magnetic Cylinder Sensor |
SICK offers special magnetic cylinder sensors used to
detect the position of pistons in pneumatic cylinders.
SICK magnetic cylinder sensors are fully electronic and are encapsulated in
special housings which can be attached simply to the pneumatic cylinders. |
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| Photoelectric Proximity Switches |
- Foreground suppression
- Background suppression
- Background blanking
- Energetic
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| Photoelectric Reflex Switches |
| Sender and receiver in one housing. A reflector is
required. Different reflector sizes for different ranges and object sizes. |
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| Through-Beam Photoelectric Switches |
The through-beam photoelectric
switch consists of two devices: the sender and receiver. The separate device
configuration makes large scanning ranges possible. The use of laser diodes
allows greater scanning ranges
while simultaneously maintaining a high resolution. Focus ranges can be set with
high precision. |
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| Photoelectric Switches with Fibre-Optic Cables |
| Sender and receiver in one housing. 2 fibre-optic cables,
scanning or through-beam principle possible.
Sensors for hazardous areas according to Directive 94/9/EC (ATEX)6
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| Roller Conveyor |
| These non-contact sensors, which were specially developed
for handling systems, detect the conveyed object from between the rollers. |
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| Contrast Scanner |
| At a constant scanning distance, up to 30 gray tones from
a scale ranging from black to white can be distinguished. This property is
essential for detecting contrast marks, for example printed color bars. |
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| Colour Sensors |
| Colour sensors function using a special three-colour
method. They cast light (red, blue, green) on the objects to be tested,
calculate the chromaticity co-ordinates from the reflected radiation and compare
them with previously stored reference tristimulus values. If the tristimulus
values are within the set tolerance range, a switching output is activated. |
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| Luminescence Scanner |
| Luminescence scanners react to luminescent pigments which
are activated by the UV light source in the scanner. The light, which is then
reflected, is received and eveluated by the luminescence scanner. |
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| Photoelectric Fork Sensor |
| These sensors, which function as two-unit through-beam
systems, combine a sender and receiver in a single housing. The distance between
the sender and receiver is determined by the shape of the housing and is
referred to as the fork width. |
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| Automation Light Grids |
Two-dimensional detection range for a wide rang of
applications:
- recording and counting of irregular objects
- measuring and sorting of different heights
- presence and protrusion monitoring
- slack monitoring |
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| Distance sensor and measuring device |
| Distance sensors transmit light onto an object or
reflector and evaluate the reflected beam of light. In the process they
transform the distance thus determined into a proportional electrical signal |
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| Data Transmission System |
| SICK ISD systems together with infrared light can be used
to form cable-free transmission links for serial data in full-duplex mode - this
does always with trailing cables. A link always consists of one device pair (2
device units) with different carrier frequencies. |
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| Machine Vision |
| The Machine Vision Sensors integrate imager technology,
lighting, display and evaluation hard- and software in one compact housing. |
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| Position Finder |
| The DMP 2 position finder is an optoelectronic sensor
which is used for fine positioning in handling and warehousing systems. At, for
example, transfer and docking stations, varying temperature- or load-dependent
geometrical variations make fine positioning essential. |
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| Light Section Sensor |
| The laser line hitting the object is then displayed upon
a square receiver array as a contour corresponding to the object´s height
profile. This allows height profiles to be monitored, newspapers counted,
filling levels detected or the alignment of objects to be ascertained and
checked for presence. |
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| AS-lnterface® |
| The Actuator-Sensor Interface, called AS-lnterface® for
short, is a system with which simple, binary and analog terminals – sensors,
actuators and control units – can be networked via a cable on the lowest field
level with the first control level. |
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| Auto Ident |
Laser-supported
sensor systems and RFID
from the Auto Ident Division are used to reliably identify, classify, measure,
and detect the position of objects in automated processes. |
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| 2D-Code-Reader |
| Higher automation, optimisation of processes, complete
traceability, cost reduction of call-backs, secure identification, reliable
process control as well as protection from plagiarism. |
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| Fixmounted Barcode Scanner |
Barcode reading devices are now indispensable for
modern object identification.
SICK offers solutions for the most varied of applications
involving automatic identification. |
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| RFID |
| Logistics, curier express parcel services, automobile
manufacture - RFID can be utilized to identify pallets, ensure smooth transport
of totes or match the content to the right transport box. |
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| Robotics |
In the internal transport logistics and in harbours laser
measurement systems are important pillars of modern automation concepts.
Whether it is for automated guided vehicles (AGV) or industrial- and service
robots our SICK-Sensors perform tasks for navigation, object recognition and for
automated palletising. |
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