OMRON TLT2F15

Slim Proximity Sensor
TL-T
Slim Model of Width 12 mm.
• Ideal for side-by-side mounting.
Be sure to read Safety Precautions on page 5.
Ordering Information
Appearance
Shielded
Unshielded
Sensing distance
2 mm
5 mm
Model
Output configuration
Output specifications
NPN
NO
TL-T2E1
NC
TL-T2E2
PNP
TL-T2F1
---
AC 2-wire models
TL-T2Y1
TL-T2Y2
DC 3-wire models
NPN
TL-T5ME1
TL-T5ME2
TL-T5MY1
TL-T5MY2
DC 3-wire models
AC 2-wire models
Note: Models with a different frequency are available. The model numbers are TL-T@@@5. (e.g., TL-T2E15).
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1
TL-T
Ratings and Specifications
Model TL-T2E1
TL-T2Y1
TL-T5ME1
TL-T5MY1
TL-T2E2
TL-T2Y2
TL-T5ME2
TL-T5MY2
Item
TL-T2F1
Sensing distance
2 mm±10%
5 mm±10%
Setting distance
0 to 1.6 mm
0 to 4 mm
Differential travel
10% max. of sensing distance
Ferrous metal (The sensing distance decreases with non-ferrous metal. Refer to Engineering Data on
Sensing object
page 3.)
Standard sensing object
Iron 12 × 12 × 1 mm
Iron 15 × 15 × 1 mm
E and F models: 800 Hz,
E models: 250 Hz,
Response frequency
Y models: 20 Hz
Y models: 20 Hz
Supply voltage
E and F models: 12 to 24 VDC (10 to 30 VDC), ripple (p-p): 20% max.
(operating voltage range) Y models:
100 to 220 VAC (90 to 250 VAC) 50/60 Hz
Current consumption
E and F models: 15 mA max. at 24 VDC
Leakage current
Y models: 2.5 mA max. at 200 VAC
Switching
E and F models: 100 mA max. at 12 VDC, 200 mA max. at 24 VDC
Y models:
10 to 200 mA
Control capacity
output
Residual
E and F models: 1.0 V max. with a load current of 100 mA and cord length of 2 m
voltage
Y models:
Refer to Residual Voltage (Typical) on page 3.
Indicators
Detection indicator (red)
E1 models: NO
Operation mode
E2 models: NC
(with sensing object apF1 models: NO Refer to I/O Circuit Diagrams Timing Chart on page 4.
proaching)
Y1 models: NO
Y2 models: NC
E models: Reverse connection protection and surge absorber
Circuit protection
Y models: Surge absorber
Ambient temperature
Operating/Storage: −25°C to 70°C (with no icing or condensation)
Ambient humidity
Operating/Storage: 35% to 95% (with no condensation)
Temperature influence
±10% max. of sensing distance at 23% in the temperature range of −25 to 70°C
E and F models: ±2.5% max. of sensing distance within a range of ±15% of the rated power supply voltage
Voltage influence
Y models:
±2.5% max. of sensing distance within a range of ±10% of the rated power supply voltage
Insulation resistance
50 MΩ min. (at 500 VDC) between case and current-carrying parts
E and F models: 1,000 VAC, 50/60 Hz for 1 min between case and current-carrying parts
Dielectric strength
Y models:
2,000 VAC, 50/60 Hz for 1 min between case and current-carrying parts
Vibration resistance
10 to 55 Hz, 1.5-mm double amplitude for 2 hours each in X, Y, and Z directions
(destruction)
Shock resistance
500 m/s2 for 10 times each in X, Y, and Z directions
(destruction)
Degree of protection
IEC IP67, in-house standard for oil-resistance
Connection method
Pre-wired Models (Standard cable length: 2 m)
Weight (packed state)
Approx. 70 g
Case
Heat-resistant ABS resin
Material
Sensing surface
Accessories
Instruction sheet
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2
TL-T
Engineering Data (Typical)
6
5
TL-T5M
4
Y
Iron
2
1.8
1.6
Stainless steel (SUS304)
Distance X (mm)
Sensing Object Size and Material Influence
TL-T2
TL-T5M
Distance X (mm)
Distance X (mm)
Operating Range
TL-T2@/T5@
6
Iron
5
Stainless steel (SUS304)
4
1.4
X
@d
1.2
3
X
t = 1 mm
3
1
Brass
2
Aluminum
0.6
1
Brass
2
0.8
TL-T2
X
0.4
−6
−4
−2
0
4
2
6
8
0
5
Distance
Y (mm)
10
Residual Voltage (Typical)
TL-T@(M)Y@
at 100 VAC
TL-T@(M)Y@
Load voltage VL (V)
Residual output voltage
ON
100
V
15
20
25
at 200 VAC
Residual output voltage
200
ON
V
50
200 VAC
A
50
Residual load
voltage
0
5
10
100 150 200
Load current (mA)
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10
15
20
25
30
35
40
Side length of sensing object: d (mm)
Leakage Current (Typical)
TL-T@Y
R
6
A
AC
power
supply
5
4
0
2
1
Residual
load voltage
OFF
50
5
t = 1 mm
3
100 VAC
A
0
Side length of sensing object: d (mm)
Load voltage VL (V)
Sensing Head
Leakage current (mA)
0
−8
Aluminum
@d
1
5
10
OFF
50
100 150 200
Load current (mA)
0
90 100
150
200
250
Supply voltage (V)
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3
TL-T
I/O Circuit Diagrams
DC 3-wire Models
Operation
Output
mode
specifications
Models
Timing charts
Output circuits
Present
Sensing object
Not present
TL-T2E1
TL-T5ME1
NO
Load
(between brown
and black)
Operate
Reset
Output voltage
(between black
and blue)
Brown
H
+V
L
ON
Detection
indicator (red)
OFF
Sensing object
Present
NPN
Load
Proximity
Sensor
main
circuit
4.7 kΩ
2.2 Ω
Black *1
Out- *2
put
Tr
Not present
TL-T2E2
TL-T5ME2
NC
Load
(between brown
and black)
Blue
Operate
0V
Reset
Output voltage
(between black
and blue)
H
L
*1. 200 mA (load current)
*2. When a transistor is connected
ON
Detection
indicator (red)
OFF
Brown
+V
Present
Sensing object
Tr
Not present
NO
PNP
TL-T2F1
Load
(between brown
and black)
Operate
Reset
Output voltage
(between black
and blue)
H
L
Proximity
Sensor
main
circuit
4.7 kΩ
Black*2
2.2 Ω
Output *1
Load
Blue
0V
ON
Detection
indicator (red)
OFF
*1. 200 mA (load current)
*2. When a transistor is connected
AC 2-wire Models
Operation mode
Models
Timing charts
Output circuits
Present
Sensing object
Not present
NO
TL-T2Y1
TL-T5MY1
Operate
Load
Reset
Brown
ON
Detection indicator
(red)
Load
OFF
Proximity
Sensor
main
circuit
Blue
Present
Sensing object
Not present
NC
TL-T2Y2
TL-T5MY2
Load
Operate
Detection indicator
(red)
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Reset
ON
OFF
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4
TL-T
Safety Precautions
WARNING
This product is not designed or rated for
ensuring safety of persons.
Do not use it for such purposes.
Mutual Interference
When two or more Sensors are mounted face-to-face or sideby-side, separate them as shown below. The table below
indicates the minimum distances A and B.
• Do not short the load. Explosion or burning may
result.
• Do not supply power to the Sensor with no load
connected, otherwise internal parts may be
damaged or burnt.
Applicable Models: AC 2-wire Models
A
B
Mutual Interference
Precautions for Correct Use
Distance
Model
TL-T2
TL-T5
Do not use this product under ambient conditions that exceed
the ratings.
● Design
Effect of Surrounding Metals
• Be sure to separate the Sensor from surrounding metal
objects as shown in the following illustration.
(Unit: mm)
A
B
40 (10)
120 (60)
12 (0)
80 (40)
Note: Figures in parentheses will apply if the Sensors in use are different from
each other in response frequency.
● Mounting
• At the time of rear mounting, be sure that the tightening
torque does not exceed 0.59 N·m.
12 mm
15 mm
25 mm
Mounting screw
0.59 N·m
15 mm 15 mm
• At the time of side mounting, be sure that the tightening
torque does not exceed 0.78 N·m.
15 mm
15 mm
Mounting screw
0.78 N·m
• The TL-T2 will not be influenced by metal when it is
embedded in metal.
(Unit: mm)
Dimensions
Unless otherwise specified, the tolerance class IT16 is used for dimensions in this data sheet.
TL-T@
Indicator *2
Two, 3.1-dia. holes
*1
4
5
9
32±0.2
16±0.2
Two, M3, depth 6
6
Sensing surface
4
17±0.2
26
12
40
*1. DC-switching model: 4.0-dia.
vinyl-insulated round cable
with 3 conductors (Conductor
cross section: 0.2 mm2,
Insulator diameter: 1.2 mm),
Standard length: 2 m
AC-switching model: 4.0-dia.
vinyl-insulated round cable
with 2 conductors (Conductor
cross section: 0.3 mm2,
Insulator diameter: 1.3 mm),
Standard length: 2 m
*2. Detection indicator (red)
In the interest of product improvement, specifications are subject to change without notice.
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5
Proximity Sensors Technical Guide
For precautions on individual products, refer to the Safety Precautions
in individual product information.
General Precautions
WARNING
These products cannot be used in safety devices for
presses or other safety devices used to protect human
life.
These products are designed for use in applications
for sensing workpieces and workers that do not affect
safety.
Precautions for Safe Use
To ensure safety, always observe the following precautions.
●Wiring Considerations
Item
Power Supply Voltage
Do not use a voltage that exceeds the operating voltage range. Applying a voltage that is
higher than the operating voltage range, or using an AC power supply (100 VAC or higher)
for a Sensor that requires a DC power supply
may cause explosion or burning.
Load short-circuiting
Typical examples
DC 3-Wire NPN Output Sensors
DC 2-Wire Sensors
Load
Brown
Sensor
Load
Brown
Sensor
Black
Blue
Blue
• DC 2-Wire Sensors
• Even with the load short-circuit protection
function, protection will not be provided when
a load short circuit occurs if the power supply
polarity is not correct.
DC 3-Wire NPN Output Sensors
• Do not short-circuit the load. Explosion or
burning may result.
• The load short-circuit protection function operates when the power supply is connected
with the correct polarity and the power is
within the rated voltage range.
Load
Load
Brown
Sensor
Black
(Load short +
circuit)
−
Brown
Be sure that the power supply polarity and other wiring is correct. Incorrect wiring may cause
explosion or burning.
Blue
DC 3-Wire NPN Output Sensors
Load
Brown
Sensor
−
Black
+
Brown
Sensor
If the power supply is connected directly without a load, the internal elements may explode
or burn. Be sure to insert a load when connecting the power supply.
Load
Blue
+
−
Black
Blue
Connection without a Load
−
+
Sensor
Blue
Incorrect Wiring
(Load short circuit)
• DC 2-Wire Sensors
• Even with the load short-circuit protection
function, protection will not be provided if
both the power supply polarity is incorrect
and no load is connected.
AC 2-Wire Sensors
Brown
Sensor
Brown
−
+
Sensor
Blue
Blue
●Operating Environment
Do not use the Sensor in an environment where there are explosive or combustible gases.
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C-1
Proximity Sensors Technical Guide
Precautions for Correct Use
The following conditions must be considered to understand the conditions of the application and location as well as the relation to control
equipment.
●Model Selection
Item
Points of consideration
Specific condiDirection of obtions of object
ject movement
Check the relation between the sensing object
and the Proximity Sensor.
Sensing
object and
operating
condition of
Proximity
Sensor
Material, size,
shape, existence
of plating, etc.
Sensing object
Material, distance
to Sensor, orientation, etc.
Fluctuation in
transit point, allowable error, etc.
Sensing (set) distance, shape of Sensor (rectangular, cylindrical, throughbeam, grooved), influence of peripheral metal (Shielded Sensors, Nonshielded Sensors), response speed (response frequency), influence of
temperature, influence of voltage, etc.
Surrounding
metals
Output
Load
Power
supply
Switching element
Proximity
Sensor
Verify the electrical conditions of the control system
to be used and the electrical performance of the
Power
Proximity Sensor.
supply
Load
DC (voltage fluctuation, current capacity value)
AC (voltage fluctuation, frequency,
etc.)
Need for S3D2 Controller
Selecting the power
supply type
DC
DC + S3D2 Controller
AC
Resistive load - Non-contact control
system
Inductive load - Relay, solenoid, etc.
• Steady-state current, inrush current
• Operating, reset voltage (current)
Lamp load
• Steady-state current, inrush current
Open/close frequency
Selecting the power
supply type
DC
DC + S3D2 Controller
AC
Control output
Maximum current
(voltage)
Leakage current
Residual load voltage
{
{
• Water Resistance
Do not use the Sensor in water, rain, or outdoors.
The environmental tolerance of the Proximity Sensor
is better than that of other types of Sensors. However,
investigate carefully before using a Proximity Sensor
under harsh temperatures or in special atmospheres.
Environmental
conditions
Sensing distance
Sensing
distance
Proximity Sensor
Electrical
conditions
Transit interval,
speed, existence
of vibration, etc.
Peripheral metal
• Ambient Conditions
To maintain reliability of operation, do not use the
Temperature Highest or lowest Temperature influence, Sensor outside the specified temperature range or
and humidity values, existence high-temperature use, outdoors. Even though the Proximity Sensor has a
of direct sunlight, low temperature use, water-resistant structure, it must be covered to prevent direct contact with water or water-soluble cutetc.
need for shade, etc. ting oil. Do not use the Sensor in atmospheres with
vapors, in particular, strong alkalis or acNeed for water resis- chemical
Atmosphere Water, oil, iron
ids (nitric acid, chromic acid, or hot concentrated
tance or oil resistance, sulfuric acid).
powder, or other
special chemicals need for explosion• Explosive Atmospheres
proof structure
Do not use the Sensor in atmospheres where
Vibration and Size, duration
Need for strength,
there is a danger of explosion. Use an Explosionshock
mounting method
proof Sensor.
When deciding the mounting method, take into consideration not
only restrictions due to mechanical devices, but also ease of maintenance and inspection, and interference between Sensors.
Mounting
conditions
Wiring method,
existence of inductance surges
Connection
Wires
Wire type, length, oil-resistant
cable, shielded cable, robot
cable, etc.
Mounting procedure
Installation location
Conduits, ducts, pre-wired,
terminal wiring, ease of maintenance and inspection
Existence of mounting
brackets, direct mounting,
secured with bolts or screws
Ease of maintenance and
inspection, mounting space
Influence of
external
electromagnetic fields
• The influence within a DC magnetic field is 20 mT* max. Do not use the Sensor at a level higher than 20 mT.
• Sudden changes in the DC magnetic field may cause malfunction. Do not use the Sensor for applications that involve turning a
DC electromagnet ON and OFF.
• Do not place a transceiver near the Sensor or its wiring. Doing so may cause malfunction.
Other considerations
Cost feasibility: Price/delivery time
Life: Power-ON time/frequency of use
* mT (millitesla) is a unit for expressing magnetic flux density. One tesla is the equivalent of 10,000 gauss.
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C-2
Proximity Sensors Technical Guide
●Design
Sensing Object Material
Sensing distance X (mm)
8
Stainless steel
6
Brass
4
Aluminum
2
0
Copper
5 10 15 20 25 30 35 40 45 50 55
Side length (one side) of sensing object: d (mm)
Sensing object shape: Square
d=30mm
Reset
Operate
10
Steel
8
6
4
2
Aluminum
0 0.01
0.1
1
10
Thickness of sensing object: t (mm)
• Influence of Plating If the sensing object is plated, the sensing
distance will change (see the table below).
Effect of Plating (Typical)
(Reference values: Percent of non-plated sensing distance)
Sensing distance X (mm)
Size of Sensing Object
In general, if the object is smaller
than the standard sensing
object, the sensing distance
decreases.
• Design the setup for an object
size that is the same or greater
than the standard sensing
object size from the graphs
showing the sensing object
size and sensing distance.
• When the size of the standard
sensing object is the same or
less than the size of the
standard sensing object,
select a sensing distance with
sufficient leeway.
• The thickness of ferrous metals
(iron, nickel, etc.) must be 1 mm
or greater.
• For non-magnetic metal, a
sensing distance equivalent to a
magnetic body can be obtained
when the coating thickness is
0.01 mm or less. With pulseresponse models (e.g., E2V),
however, the characteristics may
vary. Be sure to check the
catalog information for the
relevant model.
When the coating is extremely
thin and is not conductive, such
as a vacuum deposited film,
detection is not possible.
Sensing distance X (mm)
Thickness of Sensing Object
The sensing distance varies greatly depending on the material of the
sensing object. Study the engineering data for the influence of
sensing object material and size and select a distance with sufficient
leeway.
• In general, if the
Example: E2-X10D@
sensing object is a non14
t=1mm
X
magnetic metal (for
12
d
example, aluminum),
the sensing distance
Steel
10
decreases.
(SPCC)
Thickness and base material of
plating
No plating
Side length (one side)
of sensing object: d (mm)
Sensing Standard Stability
distance sensing
becomes object
short
Steel
Brass
100
100
Zn 5 to 15 μm
90 to 120
95 to 105
Cd 5 to 15 μm
100 to 110
95 to 105
Ag 5 to 15 μm
60 to 90
85 to 100
Cu 10 to 20 μm
70 to 95
95 to 105
Cu 5 to 15 μm
-
95 to 105
Cu (5 to 10 μm) + Ni (10 to 20 μm)
70 to 95
-
Cu (5 to 10 μm) + Ni (10 μm)
+ Cr (0.3 μm)
75 to 95
-
Mutual Interference
• Mutual interference refers to a state where a Sensor is affected by
magnetism (or static capacitance) from an adjacent Sensor and the
output is unstable.
• One means of avoiding interference when mounting Proximity
Sensors close together is to alternate Sensors with different
frequencies. The model tables indicate whether different
frequencies are available. Please refer to the tables.
• When Proximity Sensors with the same frequency are mounted
together in a line or face-to-face, they must be separated by a
minimum distance. For details, refer to Mutual Interference in the
Safety Precautions for individual Sensors.
Power Reset Time
A Sensor is ready for detection within 100 ms after turning ON the
power. If the load and Sensor are connected to separate power
supplies, design the system so that the Sensor power turns ON first.
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C-3
Proximity Sensors Technical Guide
Turning OFF the Power
An output pulse may be generated when the power is turned OFF, so
design the system so that the load or load line power turns OFF first.
Influence of Surrounding Metal
Countermeasures for Leakage Current (Examples)
AC 2-Wire Sensors
Connect a bleeder resistor to bypass the leakage current flowing in
the load so that the current flowing through the load is less than the
load reset current.
The existence of a metal object other than the sensing object near the
sensing surface of the Proximity Sensor will affect detection performance, increase the apparent operating distance, degrade temperature characteristics, and cause reset failures. For details, refer to the
influence of surrounding metal table in Safety Precautions for individual Sensors.
The values in the table are for the nuts provided with the Sensors.
Changing the nut material will change the influence of the surrounding
metal.
Power Transformers
Be sure to use an insulated transformer for a DC power supply. Do
not use an auto-transformer (single-coil transformer).
Precautions for AC 2-Wire/DC 2-Wire Sensors
Surge Protection
Although the Proximity Sensor has a surge absorption circuit, if there
is a device (motor, welder, etc.) that causes large surges near the
Proximity Sensor, insert a surge absorber near the source of the
surges.
Influence of Leakage Current
Even when the Proximity Sensor is OFF, a small amount of current
runs through the circuit as leakage current.
For this reason, a small current may remain in the load (residual
voltage in the load) and cause load reset failures. Verify that this
voltage is lower than the load reset voltage (the leakage current is
less than the load reset current) before using the Sensor.
Using an Electronic Device as the Load for an AC 2-Wire
Sensor
When using an electronic device, such as a Timer, some types of
devices use AC half-wave rectification. When a Proximity Sensor is
connected to a device using AC half-wave rectification, only AC halfwave power will be supplied to the Sensor. This will cause the Sensor
operation to be unstable. Also, do not use a Proximity Sensor to turn
the power supply ON and OFF for electronic devices that use DC halfwave rectification. In such a case, use a relay to turn the power supply
ON and OFF, and check the system for operating stability after
connecting it.
Examples of Timers that Use AC Half-wave Rectification
Timers: H3Y, H3YN, H3RN, H3CA-8, RD2P, and H3CR (-A, -A8, -AP,
-F, -G)
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When using an AC 2-Wire Sensor, connect a bleeder
resistor so that the Proximity Sensor current is at least 10
mA, and the residual load voltage when the Proximity
Sensor is OFF is less than the load reset voltage.
Load
AC power supply
voltage Vs
Bleeder resistor R
Calculate the bleeder resistance and allowable power using the
following equation.
Vs
R≤
10 - I
P
I
(kΩ)
P>
Vs2
(mW)
R
: Watts of bleeder resistance (the actual number of watts
used should be several times this number)
: Load current (mA)
It is recommend that leeway be included in the actual values used.
For 100 VAC, use 10 kΩ or less and 3 W (5 W) or higher, and for 200
VAC, use 20 kΩ or less and 10 W (20 W) or higher. If the effects of
heat generation are a problem, use the number of watts in
parentheses ( ) or higher.
DC 2-Wire Sensors
Connect a bleeder resistor to bypass the leakage current flowing in
the load, and design the load current so that (leakage current) × (load
input impedance) < reset voltage.
Load
Bleeder resistor R
Vs
Calculate the bleeder resistance and allowable power using the
following equation.
Vs
R≤
iR - iOFFR
(kΩ)
P>
Vs2
R
(mW)
P
: Watts of bleeder resistance (the actual number of watts
used should be several times this number)
iR : Leakage current of Proximity Sensor (mA)
iOFF : Load reset current (mA)
It is recommend that leeway be included in the actual values used.
For 12 VDC, use 15 kΩ or less and 450 mW or higher, and for 24
VDC, use 30 kΩ or less and 0.1 W or higher.
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C-4
Proximity Sensors Technical Guide
Loads with Large Inrush Current
Loads, such as lamps or motors, that cause a large inrush current* will
weaken or damage the switching element. In this situation, use a
relay.
<Removing>
• While pressing the Amplifier Unit in the direction of (3), lift the fiber
plug in the direction of (4) for easy removal without a screwdriver.
* E2K, TL-N@Y: 1 A or higher
●Mounting
Mounting the Sensor
(4)
When mounting a Sensor, do not tap it with a hammer or otherwise
subject it to excessive shock. This will weaken water resistance and
may damage the Sensor. If the Sensor is being secured with bolts,
observe the allowable tightening torque. Some models require the
use of toothed washers.
For details, refer to the mounting precautions in Precautions for
Correct Use in individual product information.
DIN Track (3)
Set Distance
The sensing distance may vary due to fluctuations in temperature and
voltage. When mounting the Sensor, it is recommend that installation
be based on the set distance.
Mounting/Removing Using DIN Track
(Example for E2CY)
<Mounting>
(1)Insert the front of the Sensor into the special Mounting Bracket
(included) or DIN Track.
(2)Press the rear of the Sensor into the special Mounting Bracket or
DIN Track.
Rear
Front
(1)
(2)
Mounting track (yellow)
DIN Track (or Mounting Bracket)
• When mounting the side of the Sensor using the special Mounting
Bracket, first secure the Amplifier Unit to the special Mounting
Bracket, and then mount the special Mounting Bracket with M3
screws and flat washers with a diameter of 6 mm maximum.
Flat washers (6 dia. max.)
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C-5
Proximity Sensors Technical Guide
●Wiring Considerations
AND/OR Connections for Proximity Sensors
Model
Type of
connection
Connection
Description
Load
Keep the number of connected Sensors (N) within the range of the following
equation.
VS - N × VR ≥ Operating load voltage
+
-
AND (series
connection)
Vs
+
It is possible, however, that the indicators may not light correctly and error
pulses (of approximately 1 ms) may be generated because the rated power
supply voltage and current are not supplied to individual Proximity Sensors.
Verify that this is not a problem before operation.
-
DC 2-Wire
Load
+
Vs
OR (parallel
connection)
N : Number of Sensors that can be connected
VR: Residual output voltage of Proximity Sensor
VS: Power voltage
Keep the number of connected Sensors (N) within the range of the following
equation.
N × i ≤ Load reset current
N: Number of Sensors that can be connected
i: Leakage current of Proximity Sensor
+
Example: When an MY (24-VDC) Relay is used as the load, the maximum
number of Sensors that can be connected is 4.
<TL-NY, TL-MY, E2K-@MY@, TL-T@Y>
The above Proximity Sensors cannot be used in a series connection. If needed, connect through relays.
Load
VS
X2
X1
AND (series
connection)
Load
X1
VS
X2
Load
<E2E-X@Y>
For the above Proximity Sensors, the voltage VL that can be applied to the
load when ON is VL = VS - (Output residual voltage × Number of Sensors), for
both 100 VAC and 200 VAC.
The load will not operate unless VL is higher than the load operating voltage.
This must be verified before use.
When using two or more Sensors in series with an AND circuit, the limit is three
Sensors. (Be careful of the VS value in the diagram at left.)
VL
VS
VS ≥ 100V
AC 2-wire
In general it is not possible to use two or more Proximity Sensors in parallel
with an OR circuit.
(B)
OR (parallel
connection)
A parallel connection can be used if A and B will not be operated simultaneously and there is no need to hold the load. The leakage current, however,
will be n times the value for each Sensor and reset failures will frequently occur.
("n" is the number of Proximity Sensors.)
Load
X1
X2
(A)
Load
(B)
X1 X2
AC power supply
voltage Vs
(A)
If A and B will be operated simultaneously and the load is held, a parallel connection is not possible.
If A and B operate simultaneously and the load is held, the voltages of both A
and B will fall to about 10 V when A turns ON, and the load current will flow
through A causing random operation. When the sensing object approaches B,
the voltage of both terminals of B is too low at 10 V and the switching element
of B will not operate. When A turns OFF again, the voltages of both A and B
rise to the power supply voltage and B is finally able to turn ON.
During this period, there are times when A and B both turn OFF (approximately
10 ms) and the loads are momentarily restored. In cases where the load is to
be held in this way, use a relay as shown in the diagram at left.
Note: When AND/OR connections are used with Proximity Sensors, the effects of erroneous pulses or leakage current may prevent use. Verify that there are no
problems before use.
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C-6
Proximity Sensors Technical Guide
Model
Type of
connection
Connection
(A)
AND (series
connection)
(B)
+
+
Description
Keep the number of connected Sensors (N) within the range of the following
equation.
iL + (N - 1) × i ≤ Upper limit of Proximity Sensor control output
VS - N × VR ≥ Operating load voltage
i
OUT
iL
Load
i
Vs
OUT
Example: A maximum of two
Sensors can be used when an
MY (24-VDC) Relay is used for
the load.
Note: When an AND circuit is connected, the operation of Proximity Sensor B
causes power to be supplied to Proximity Sensor A, and thus erroneous
pulses (approximately 1 ms) may be generated in A when the power is
turned ON. For this reason, take care when the load has a high
response speed because malfunction may result.
-
DC 3-wire
N : Number of Sensors that can be connected
VR: Residual output voltage of Sensor
VS: Power supply voltage
i : Current consumption of Sensor
iL: Load current
+
OUT
OR (parallel
connection)
Load
Vs
+
OUT
For Sensors with a current output, a minimum of three OR connections is possible. Whether or not four or more connections is possible depends on the
model.
Note: When AND/OR connections are used with Proximity Sensors, the effects of erroneous pulses or leakage current may prevent use. Verify that there are no
problems before use.
Extending Cable Length
The cable of a Built-in Amplifier Sensor can be extended to a
maximum length of 200 m with each of the standard cables (excluding
some models).
For Separate Amplifier Sensors (E2C-EDA, E2C, E2J, E2CY), refer
to the specific precautions for individual products.
Example of Connection with S3D2 Sensor Controller
DC 2-Wire Sensors
Using the S3D2 Sensor Controller
Operation can be reversed with the signal input
switch on the S3D2.
Bending the Cable
Blue 0 V
If you need to bend the cable, we recommend a bend radius that is at
least 3 times the outer diameter of the cable (with the exception of
coaxial and shielded cables).
7
8
9
10 11 12
Brown OUT
Cable Tensile Strength
In general, do not subject the cable to a tension greater than that
indicated in the following table.
Cable diameter
Tensile strength
Less than 4 mm
30 N max.
4 mm min.
50 N max.
Note: Do not subject a shielded cable or coaxial cable to tension.
S3D2
4
5
6
1
2
3
Connecting to a Relay Load
Brown
X
24 VDC
Blue
Separating High-voltage Lines
Using Metal Conduits
If a power line is to be located near the Proximity Sensor cable, use a
separate metal conduit to prevent malfunction or damage. (Same for
DC models.)
Note: DC 2-Wire Sensors have a residual voltage of 3 V. Check the operating
voltage of the relay before use.
The residual voltage of the E2E-XD-M1J-T is 5 V.
DC 3-Wire Sensors
Operation can be reversed with the signal input
switch on the S3D2.
Blue 0 V
Black OUT
Brown +12 V
S3D2
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7
8
9
10 11 12
4
5
6
1
2
3
(c)Copyright OMRON Corporation 2008 All Rights Reserved.
C-7
Proximity Sensors Technical Guide
●Operating Environment
Water Resistance
Do not use the Sensor in water, rain, or outdoors.
Ambient Conditions
Do not use the Sensor in the following environments.
Doing so may cause malfunction or failure of the Sensor.
1. To maintain operational reliability and service life, use the Sensor
only within the specified temperature range and do not use it
outdoors.
2. The Sensor has a water resistant structure, however, attaching a
cover to prevent direct contact with water will help improve
reliability and prolong product life.
3. Avoid using the Sensor where there are chemical vapors,
especially strong alkalis or acids (nitric acid, chromic acid, or hot
concentrated sulfuric acid).
●Maintenance and inspection
Periodic Inspection
To ensure long-term stable operation of the Proximity Sensor, inspect
for the following on a regular basis. Conduct these inspections also
for control devices.
1. Shifting, loosening, or deformation of the sensing object and
Proximity Sensor mounting
2. Loosening, bad contact, or wire breakage in the wiring and
connections
3. Adherence or accumulation of metal powder
4. Abnormal operating temperature or ambient conditions
5. Abnormal indicator flashing (on setting indicator types)
Disassembly and Repair
Do not under any circumstances attempt to disassemble or repair the
product.
Quick Failure Check
You can conveniently check for failures by connecting the E39-VA
Handy Checker to check the operation of the Sensor.
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C-8
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
specified) 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 certification documents identifying ratings and limitations of use that apply to the
products. This information by itself is not sufficient 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 specifications 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 significant construction changes are made.
However, some specifications of the product may be changed without any notice. When in doubt, special model numbers may be assigned to fix
or establish key specifications for your application on your request. Please consult with your OMRON representative at any time to confirm actual
specifications 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
OMRON shall not be responsible for the user's programming of a programmable product, or any consequence thereof.
COPYRIGHT AND COPY PERMISSION
This catalog shall not be copied for sales or promotions without permission.
This catalog is protected by copyright and is intended solely for use in conjunction with the product. Please notify us before copying or reproducing this
catalog in any manner, for any other purpose. If copying or transmitting this catalog to another, please copy or transmit it in its entirety.
2008. 9
OMRON Corporation
In the interest of product improvement, specifications are subject to change without notice.
Industrial Automation Company
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(c)Copyright OMRON Corporation 2008 All Rights Reserved.