Pushbutton-type Photomicrosensor
EE-SA801
Using a pushbutton enables
accurately detecting difficult-to-detect
objects.
Conforms to standards for semiconductor FOUP cassettes
to enable accurately detecting FOUP cassettes without
being affected by the material, color, or reflectance of the
bottoms of the cassettes.
Thin design enables mounting in a wider range of
applications, e.g., on transfer arms.
Increased visibility with 4-direction indicator.
Optical detection of actuator operation provides a long life
(mechanical life: 5 million operations min.).
Models available with PNP or NPN output.
Be sure to read Safety Precautions
Ordering Information
List of Models
Note: 1. Distance from the top surface of the housing to the top of the actuator.
2. Output reverses between 3.5 and 4.5 mm.
3. Standard models are also available with 2-m cables. When ordering, add the cable length to the end of the model number (e.g., EE-SA801A 2M).
Appearance Sensing distance Sensing method Operation mode Cable length Model
NPN output PNP output
Pushbutton ON with no load
1 m
(See note 3.) EE-SA801A EE-SA801R
(See note 2.)
0 to 3.5 mm
(pressed position)
(See note 1.)
on page 5.
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(c)Copyright OMRON Corporation 2007 All Rights Reserved.
EE-SA801
Ratings and Specifications
Note: 1. Free position (FP): The position of the top of the actuator when no force is being applied to the actuator.
Operating position (OP): The position of the top of the actuator when the actuator is pressed and the output transistor changes from ON to OFF.
Total travel position (TTP): The position of the top of the actuator when the actuator is pressed as far as it can be pressed.
2. This does not indicate that the output will be ON from 3.5 to 4.5 mm, but rather that the output will change from ON to OFF at some point between 3.5 and
4.5 mm.
3. The force required to press the actuator from the FP to the OP.
Item Model NPN output EE-SA801A
PNP output EE-SA801R
Indicator Light red when actuator is pressed.
Operation
Specifica-
tions (See
note 1.)
Free position (FP) 5.0r0.4 mm
Operating position (OP) 3.5 to 4.5 mm (See note 2.)
Total travel position (TTP) 0 mm max.
Operating load (See note 3.) 3 N max. (typical: 0.5 N)
Supply voltage 12 to 24 VDCr10%, ripple (p-p): 10% max.
Current consumption 35 mA max.
Control output
NPN Models: NPN open collector, 5 to 24 VDC, 50 mA max.;
residual voltage of 0.4 V max. at 50-mA load current
PNP Models: PNP open collector, 5 to 24 VDC, 50 mA max.;
residual voltage of 0.4 V max. at 50-mA load current
External diagnosis input Input
NPN Models
Emission OFF: Shorted to 0 V or 0.5 V max. (source current: 30 mA max.)
Emission ON: Open (leakage current: 0.4 mA max.)
PNP Models
Emission OFF: Shorted to +DC or +DC-0.5 V max. (sink current: 30 mA max.)
Emission ON: Open (leakage current: 0.4 mA max.)
Response time 1 ms max.
Protection circuits Reversed power supply polarity protection
Ambient temperature range Operating: 25 to +55qC
Storage: 30 to +60qC (with no icing or condensation)
Ambient humidity range Operating: 5% to 85%
Storage: 5% to 95% (with no condensation)
Mechanical durability 5,000,000 operations min. (One operation is from the free position to operating position and
back to the free position.)
Vibration resistance Destruction: 10 to 500 Hz, 1.0-mm single amplitude or 150 m/s2 3 times each in X, Y, and Z
directions for 11 min. each
Shock resistance Destruction: 500 m/s2 for 3 times each in X, Y, and Z directions
Degree of protection IEC IP40
Connecting method Pre-wired (standard cable length: 1 m)
Weight Approx. 16.1 g
Material Case Polycarbonate
Actuator Polyacetal
Accessories Instruction Manual
TTP
OP
FP
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EE-SA801
I/O Circuit Diagrams
Model Operating Mode Timing chart Output circuit
EE-SA801A
ON with no load
EE-SA801R
Present
Absent
ON
OFF
ON
OFF
Operates
Releases
Push indicator
(red)
Sensing
object
Output transistor
Load
(e.g., relay)
Brown
White
Blue
Black
12 to
24 VDC
Push indicator (red)
Main
circuit
Load
(relay)
ZD
ZD
50 mA max.
(External
diagnosis
input)
(Control
output)
Z
D
Z
D
Brown
White
Blue
Black
12 to
24 VDC
Push indicator (red)
Main
circuit
Load
(relay)
50 mA max.
(External
diagnosis
input)
(Control
output)
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(c)Copyright OMRON Corporation 2007 All Rights Reserved.
EE-SA801
Operating Principles
This is a pushbutton-type sensor. An emitter (GaAs infrared LED) and
receiver (Si photo IC) are positioned across from each other inside the
sensor and light is received when there is no sensing object. When
the sensing object presses the actuator, the light path between the
emitter and receiver is broken so that the receiver no longer receives
light.
This Sensor provides an external diagnosis function and stability
checking function.
(1) External Diagnosis Function
The light emission from the LED can be stopped by using the
following circuit configuration. This enables checking the operation of
the receiver by turning the LED ON and OFF when there is no load.
(2) Stability Checking Function
The light intensity emitted by the LED can be reduced by 20% by
using the following circuit configuration. By doing so, the light
reception operation at 80% light intensity with no sensing object
(same as 100%, i.e., the output transistor should turn ON) can be
tested in advance to check for malfunctions caused by deterioration
of LED light intensity.
(3) Using Both Functions Simultaneously
Use the following circuit configuration when both the external
diagnosis function (Sig1) and the stability checking function (Sig2) are
required.
Note:Use a transistor that is capable of switching 50 mA at 10 V.
The resistor must have a power rating of 1/8 W min.
Emitter
Case
Without FOUP With FOUP
Actuator
Receiver
Sensing object
Emitter
Case Actuator
Receiver
External diagnosis
input
Control circuitsSensor
OUT
(See Note.)
EE-SA801A
External diagnosis
input
Sensor Control circuits
OUT
(See Note.)
EE-SA801R
OUT
430Ω
Control circuits
Sensor
External diagnosis
input
(See Note.)
(See Note.)
EE-SA801A
Sensor Control circuits
OUT
430Ω
External diagnosis
input
(See Note.)
(See Note.)
EE-SA801R
OUT
430Ω
Sig2
Sig1
Control circuits
Sensor
External diagnosis
input
(See Note.)
(See Note.)
(See Note.)
EE-SA801A
Sensor Control circuits
OUT
External diagnosis
input
430Ω
(See Note.)
(See Note.)
(See Note.)
Sig1
Sig2
EE-SA801R
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EE-SA801
Safety Precautions
Refer to Warranty and Limitations of Liability.
This product is not designed or rated for ensuring
safety of persons either directly or indirectly. Do not
use it for such purposes.
Make sure that the Photomicrosensor is used within the rated ambient
environment conditions.
Mounting
Mount the Photomicrosensor securely on a flat surface using M3 pan
head screws, and tighten the mounting screws using a tightening
force of 0.59 N·m max.
Adjustment
The EE-SA801 requires 10 ms to be in stable operation after power is
supplied. If separate power supplies are used for the EE-SA801 and
load, be sure to supply power to the EE-SA801 before supplying
power to the load.
Operating Environment
The EE-SA801 is not watertight. Do not use the EE-SA801
outdoors.
Do not use the EE-SA801 in places where water, oil, or chemical
may be sprayed onto the EE-SA801. The exterior coverings of the
EE-SA801 are made of polycarbonate. Keep the coverings away
from any alkaline, aromatic hydrocarbon, or aliphatic chloride
hydrocarbon solvents, all of which will damage the coverings.
Dimensions (Unit: mm)
Sensor
WARNING
Precautions for Correct Use
13±0.2
Indicator window
20±0.3
6.5±0.1
21.3±0.2
25±0.3
9±0.2
18±0.2
14
2.24
2.24
3
3
Four, R3
Six, R3
1,000±50
44
5±0.4 SR4
Indicator window
Indicator window
Two, 3.3-dia. holes with 6.3 countersinking, depth: 1.65
(14)
(2.8 dia.)
EE-SA801
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(c)Copyright OMRON Corporation 2007 All Rights Reserved.
Photomicrosensors Technical Guide
General Precautions Refer to Safety Precautions for individual models for specific precautions for each model.
These products cannot be used in safety devices for
presses or other safety devices used to protect human
life.
This product is designed for use in applications for
sensing workpieces and workers that will not affect
levels of safety.
To ensure safety, observe the following precautions.
Wiring
WARNING
Precautions for Safe Use
Item Examples
Power Supply
Do not apply any voltage exceed-
ing the operating voltage range.
Applying any excessive voltage or
supplying AC power (100 VAC or
higher) to a DC-type sensor may
cause the Sensor to explode or
burn.
Load Short-circuit
Do not short-circuit the load.
Doing so may cause the Sensor to
explode or burn.
Wiring
Be sure to wire the Sensor correct-
ly and be careful not to connect the
polarities incorrectly, otherwise the
Sensor may explode or burn.
Connection with No Load
If connected to the power supply
without any load, internal elements
may explode or burn. Make sure
that a proper load is connected to
the Sensor.
AND Connections
Do not use AND connections such
as in the example shown in the di-
agram here. Voltage will be ap-
plied to the Vcc terminal without
the GND terminal of Sensor 2 be-
ing securely grounded, and may
cause the Sensor to fail.
Depending on the model used, in-
rush current to Sensor 2 when
Sensor 1 is turned ON may cause
product failure.
DC 3-Wire NPN Output Sensors
Load
Sensor
Brown
Blue
Black
DC 3-Wire NPN Output Sensors
Brown
Blue
Black
(Load short-circuit)
Load
Sensor
Load
Sensor
Brown
Blue
Black
DC 3-Wire NPN Output Sensors
(Example) Wrong polarity
Load
Sensor
Brown
Blue
Black
Sensor
Load
Brown
Black
Blue
DC 3-Wire NPN Output Sensors
(Example) Wrong polarity or wrong wiring
Sensor
Brown
Blue
Black
12 to 24 VDC
0V
DC 3-Wire NPN Output Sensor
SensorSensor
Blue (GND)
Blue (GND)
Black (OUT)
Black
(OUT)
5 to 24 VDC
0V
Load
Brown
(Vcc)
Brown
(Vcc)
Sensor 1 Sensor 2
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Photomicrosensors Technical Guide
Installation
The Photomicrosensors with Non-modulated Light (models that
begin with EE-SX or EE-SY) are built into the device being used
and are, therefore, not equipped to deal with interference from an
external light source. When using a Photomicrosensor with Non-
modulated Light in an area exposed to an incandescent light or
other external light interference, install so as to minimize the effects
of external light sources.
Mount the Photomicrosensors securely on a flat surface
Mount the Photomicrosensors with M3 screws, using a spring
washer to ensure the screws will not become loose. Use a
tightening force of 0.59 N·m max.
Note: Be sure to read the precautions for the model being used before
tightening the screws.
Install so that nothing can collide with the sensing section of the
Photomicrosensor. Damage to the sensing surface will cause
inferior performance.
Before using the Photomicrosensor, check to be sure that it has not
become loose due to vibration or shock.
Wiring
Surge
If there is surge in the power supply line, try connecting a capacitor
(with a capacitance of 0.1 to 1 μF) or a Zener diode (ZD in the
diagram below, with a rated voltage of 30 to 35 V). Use the Sensor
only after confirming that the surge has been removed.
When driving a small inductive load, such as a relay, wire as shown
below. (Be sure to connect a diode to absorb the reverse voltage.)
Separate the wiring for the Photomicrosensor from high-voltage
lines or power lines. If the wiring is routed in the same conduit or
duct as such lines, the Photomicrosensor may malfunction or may
be damaged by inductive interference.
Make sure that the connectors (either dedicated or commercially
available) are securely locked.
Voltage Output
A Sensor with an open-collector output can be connected to a
counter with a voltage input by connecting a resistor between the
power source and output. Select a resistor with reference to the
following example. The resistance of the resistor is generally 4.7 kΩ
and its wattage is 1/2 W for a supply voltage of 24 V and 1/4 W for
12 V.
<Example>
If resistance R = 4.7 kΩ for the EE-SX670, the input voltage at the
high level is as follows:
And the input voltage and load current at the low level are as
follows:
Input voltage VL 0.4 V (Residual voltage for 40-mA load current)
Note: Refer to the ratings of the Sensor for the residual voltage of the load
current.
Handling Methods when Wiring
Do not apply stress (external force) to the terminals as shown in the
figure below. Stress may damage the terminals.
Precautions for Correct Use
ZD
ZD: Zener diode
L
OUT
0.1 to 1μF
OUT
+V
0V
D
Relay
X
SW
main
circuit
Tr
+Vcc
EE-SX670
Counter
(Voltage input)
Insert a resistor
Output
0V 0V
R
24 V
Power supply
Z
Input terminal (CP)
Input impedance:
approx. 4.7 kΩ
Input voltage VH=Z
R+Z Vcc = 4.7k
4.7k + 4.7k × 24V
=12V
Load current IC = Vcc
R== 5.1mA 40mA
Vcc
R
Terminal Terminal
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Photomicrosensors Technical Guide
Design Considerations
Precautions for Photomicrosensors with Modulated Light
When using Photomicrosensors with Modulated Light (models that
begin with EE-SP), the design must take into account the effects of
power source and cable length. Photomicrosensors with Modulated
Light are more easily affected than Photomicrosensors with Non-
modulated Light (models that begin with EE-SX or EE-SY).
Photomicrosensors with Modulated Light that are easily affected:
EE-SPX301/401, EE-SPY30@/40@,
E-SPZ301@/401@, EE-SPY31@/41@,
EE-SPX303/403, EE-SPW311/411,
EE-SPX74@/84@, EE-SPX@@@-W
Photomicrosensors with Modulated Light that are not easily
affected:
EE-SPX613, EE-SPY801/802
Reasons for Interference from Power and Cable Length on
Photomicrosensors with Modulated Light
As explained in Principles, an LED emitter is pulse-lighted to produce
modulated light. A large current momentarily flows to the
Photomicrosensor in sync with this pulse timing. This causes a
pulsating consumption current.
A photoelectric sensor incorporates a capacitor with sufficient
capacity, and is virtually unaffected by the pulse of the consumption
current. With a small Photomicrosensor, however, it is difficult to have
a capacitor with a sufficient capacity. Accordingly, when the cable
length is long or depending on the type of power source, it may
become impossible to keep up with the pulse of the consumption
current and operation may become unstable.
Countermeasures
<Adding a Capacitor>
Attach a capacitor of 10 μF min. (e.g., a film capacitor) to the wires
as close as possible to the Sensor. (Use a capacitor with a
dielectric strength that is at least twice the Sensor's power supply
voltage. Do not use tantalum capacitors. A short-circuit may cause
the capacitor to ignite due to the large current flow.)
<Cable Length>
Design the configuration so that the maximum total cable length for
the Photomicrosensor with Modulated Light is 2 m.
When using a cable longer than 2 m, attach a capacitor (e.g., an
aluminum electrolytic capacitor) with a capacity of approximately
10
μ
F to the wires as shown below. The distance between the
terminal and the capacitor must be within 2 m. Make sure that the
total cable length is no longer than 5 m. To use a cable length longer
than 5 m, use a PLC or other means to read the sensor output and
then transmit the signals using a PLC's communications. Although
cables are capable of being extended longer than 5 m, performance
is likely to be affected by noise interference from adjacent cables and
other devices. Voltage drops due to the resistance of the cable
material itself will also influence performance. Therefore, factors,
such as the difference in voltage between the end of the cable and
the sensor and noise levels, must be given full consideration.
Note: The length that cables can be extended depends on the
Photomicrosensor model and cable specifications. Refer to the specific
precautions for each Photomicrosensor being used before extending
cables. The Photomicrosensors with Non-modulated Light (models that
begin with EE-SX or EE-SY) are not easily affected by the cable length.
(Effective extensions from 20 to 50 m are possible.)
Emitter
(LB)
Main
circuit
5 to 24
VDC
10 μF or
higher
Current
Vcc
OUT
GND
2 m max.
Capacitance
of 10 μF min.
12 to 24 VDC
0V
Extension cable
OUT
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Photomicrosensors Technical Guide
<Countermeasures for Switching Power Supplies>
Take either of the following countermeasures as required if
connecting a Photomicrosensor with Modulated Light to a switching
power supply.
(1) Attach a capacitor of 10 μF min. to the wires as close as possible
to the Photomicrosensor. (Use a capacitor with a dielectric
strength that is at least twice the Photomicrosensor's power
supply voltage. Do not use tantalum capacitors. A short-circuit
may cause the capacitor to ignite due to the large current flow.)
(2) Connect to the 0-V line of the power source or connect to the
power source via a capacitor of approximately 0.47 μF to reduce
the impedance of the mounting base to prevent inductive noise
from entering the mounting base.
(3) Connect the noise filter terminal (neutral terminal to ACG) of the
switching power supply to the case (FG) and 0-V terminal of the
power supply.
<Countermeasures to Handle Inductive Noise>
(4) Insert a plastic insulator of approximately 10 mm between the
Sensor and the mounting base.
<Effects of Inductive Noise>
When there is inductive noise in the Sensor mounting frame (metal),
the output of the Sensor may be affected. In this case, ensure that there
is no electrical potential difference between the Sensor 0-V terminal
and the Sensor mounting frame, or put a 0.47-
μ
F capacitor between
the 0-V terminal and the frame.
Precautions for Reflective Photomicrosensors
<Sensing Distance>
The Reflective Photomicrosensor model is based on sensing a
sheet of white paper with a reflection factor of 90%. The sensing
distance varies with the other conditions of the objects being
detected.
<Typical Example>
EE-SPY30/40 Series
<Background Objects>
Use the Sensor only after carefully studying the possibility of light
entering the Sensor due to light being reflected off background objects.
Decrease reflection from the background object, e.g., by providing
a sufficient distance to the background or by using a black sponge
as the background.
The line connected as mentioned above should be
grounded or connected to the mounting base to
ensure stable operation. (Recommended by power
supply manufacturers.)
2 m max.
Capacitance
of 10 μF min.
12 to 24 VDC
0V
Extension cable
OUT
0V
G
C
(0.47μF)
Switching
power supply
Mounting
base
Sensor +V
To the Sensor
Sensor To the
power supply
+V
G
0V
ACG
FG
Grounding
Switching power supply
Input
Mounting
base
Power
supply
Sensor
Mounting frame
0.47μF
0V
12 to 24 VDC
Sensing object
White paper
(reflection factor: 90%)
15
10
5
0
1
2
2
2
3
2
5
2
7
2
10
2
20
2
30
2
50
2
Sensing area L2 (mm2)
Sensing distance (mm)
L
L
Sensing object
Background object
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Photomicrosensors Technical Guide
PLC Connections
Relay Connections
Counter Connections
NPN open-
collector
output
a
NPN voltage
output
PNP open-
collector
output
Main
circuit
Black (OUT)
12 to 24 VDC
Brown (Vcc)
Blue (GND)
Internal circuits
IN
COM
Main
circuit
Black (OUT)
12 to 24 VDC
Brown (Vcc)
Blue (GND)
Internal circuits
IN
COM
Main
circuit
Black (OUT)
12 to 24
VDC
Brown (Vcc)
Blue (GND)
Internal circuits
IN
COM
Operating from same power supply Operating from different power supplies
NPN open-
collector
output
Main
circuit
Black
(OUT)
Brown (Vcc)
Blue (GND)
Relay
Main
circuit
Brown (Vcc)
Blue (GND)
Black
(OUT)
Relay
No-voltage Input Transistor input (voltage input)
NPN open-
collector
output
NPN voltage
output
Main
circuit
Black (OUT)
Brown (Vcc)
Blue (GND)
CP1(N)
CP2(N)
(Reset)
Input
common
5 to 24 VDC
Black (OUT)
12 to 24
VDC
Brown (Vcc)
Blue (GND)
(+)
()
(CP1)
(CP2)
(Reset)
Main
circuit
5 to 24
VDC
External
resistance
Note: Refer to the information
on the specific model for
details on calculating
external resistance.
Black (OUT)
Brown (Vcc)
Blue (GND)
Main
circuit
CP1(N)
CP2(N)
(Reset)
Input
common
5 to 24 VDC
Black (OUT)
12 to 24
VDC
Brown (Vcc)
Blue (GND)
(+)
()
(CP1)
(CP2)
(Reset)
Main
circuit
5 to 24
VDC
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Photomicrosensors Technical Guide
Other Precautions
Do not disconnect the Connector from the Sensor when power is
supplied to the Sensor. Doing so may damage the Sensor.
Avoid installing the Sensor in the following locations to prevent
malfunction or product failure:
(1) Location exposed to high concentrations of dust, oil mist, etc.
(2) Locations exposed to corrosive gases
(3) Locations exposed directly or indirectly to water, oil, or
chemical spray
(4) Outdoors or locations exposed to intensive light, such as direct
sunlight
Be sure to use the Sensor under the rated ambient temperature.
The Sensor may be dissolved by exposure to organic solvents,
acids, alkali, aromatic hydrocarbons or chloride resin
hydrocarbons, causing deterioration in characteristics. Do not
expose the Sensor to such chemicals.
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2007.12
OMRON Corporation
Industrial Automation Company
http://www.ia.omron.com/ (c)Copyright OMRON Corporation 2007 All Rights Reserved.
In the interest of product improvement, specifications are subject to change without notice.
Read and Understand This Catalog
Please read and understand this catalog before purchasing the products. Please consult your OMRON representative if you have any questions or
comments.
Warranty and Limitations of Liability
WARRANTY
OMRON's exclusive warranty is that the products are free from defects in materials and workmanship for a period of one year (or other period if
speci ed) from date of sale by OMRON.
OMRON MAKES NO WARRANTY OR REPRESENTATION, EXPRESS OR IMPLIED, REGARDING NON-INFRINGEMENT, MERCHANTABILITY, OR
FITNESS FOR PARTICULAR PURPOSE OF THE PRODUCTS. ANY BUYER OR USER ACKNOWLEDGES THAT THE BUYER OR USER ALONE
HAS DETERMINED THAT THE PRODUCTS WILL SUITABLY MEET THE REQUIREMENTS OF THEIR INTENDED USE. OMRON DISCLAIMS ALL
OTHER WARRANTIES, EXPRESS OR IMPLIED.
LIMITATIONS OF LIABILITY
OMRON SHALL NOT BE RESPONSIBLE FOR SPECIAL, INDIRECT, OR CONSEQUENTIAL DAMAGES, LOSS OF PROFITS, OR COMMERCIAL
LOSS IN ANY WAY CONNECTED WITH THE PRODUCTS, WHETHER SUCH CLAIM IS BASED ON CONTRACT, WARRANTY, NEGLIGENCE, OR
STRICT LIABILITY.
In no event shall responsibility of OMRON for any act exceed the individual price of the product on which liability is asserted.
IN NO EVENT SHALL OMRON BE RESPONSIBLE FOR WARRANTY, REPAIR, OR OTHER CLAIMS REGARDING THE PRODUCTS UNLESS
OMRON'S ANALYSIS CONFIRMS THAT THE PRODUCTS WERE PROPERLY HANDLED, STORED, INSTALLED, AND MAINTAINED AND NOT
SUBJECT TO CONTAMINATION, ABUSE, MISUSE, OR INAPPROPRIATE MODIFICATION OR REPAIR.
Application Considerations
SUITABILITY FOR USE
OMRON shall not be responsible for conformity with any standards, codes, or regulations that apply to the combination of products in the customer's
application or use of the product.
At the customer's request, OMRON will provide applicable third party certi cation documents identifying ratings and limitations of use that apply to the
products. This information by itself is not suf cient for a complete determination of the suitability of the products in combination with the end product,
machine, system, or other application or use.
The following are some examples of applications for which particular attention must be given. This is not intended to be an exhaustive list of all possible
uses of the products, nor is it intended to imply that the uses listed may be suitable for the products:
• Outdoor use, uses involving potential chemical contamination or electrical interference, or conditions or uses not described in this catalog.
• Nuclear energy control systems, combustion systems, railroad systems, aviation systems, medical equipment, amusement machines, vehicles, safety
equipment, and installations subject to separate industry or government regulations.
• Systems, machines, and equipment that could present a risk to life or property.
Please know and observe all prohibitions of use applicable to the products.
NEVER USE THE PRODUCTS FOR AN APPLICATION INVOLVING SERIOUS RISK TO LIFE OR PROPERTY WITHOUT ENSURING THAT THE
SYSTEM AS A WHOLE HAS BEEN DESIGNED TO ADDRESS THE RISKS, AND THAT THE OMRON PRODUCT IS PROPERLY RATED AND
INSTALLED FOR THE INTENDED USE WITHIN THE OVERALL EQUIPMENT OR SYSTEM.
Disclaimers
CHANGE IN SPECIFICATIONS
Product speci cations and accessories may be changed at any time based on improvements and other reasons.
It is our practice to change model numbers when published ratings or features are changed, or when signi cant construction changes are made.
However, some speci cations of the product may be changed without any notice. When in doubt, special model numbers may be assigned to x
or establish key speci cations for your application on your request. Please consult with your OMRON representative at any time to con rm act ua l
speci cations of purchased product.
DIMENSIONS AND WEIGHTS
Dimensions and weights are nominal and are not to be used for manufacturing purposes, even when tolerances are shown.
ERRORS AND OMISSIONS
The information in this catalog has been carefully checked and is believed to be accurate; however, no responsibility is assumed for clerical,
typographical, or proofreading errors, or omissions.
PERFORMANCE DATA
Performance data given in this catalog is provided as a guide for the user in determining suitability and does not constitute a warranty. It may represent
the result of OMRON’s test conditions, and the users must correlate it to actual application requirements. Actual performance is subject to the OMRON
Warranty and Limitations of Liability.
PROGRAMMABLE PRODUCTS
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