M186E Datasheet, PDF(3/8 Page) List of Unclassifed Manufacturers – Stainless Steel 18 mm Barrel-style DC Photoelectric Sensors

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M186E Datasheet, PDF (3/8 Pages) List of Unclassifed Manufacturers – Stainless Steel 18 mm Barrel-style DC Photoelectric Sensors

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EZ-BEAM M18 Series Sensors

Infrared, 880 nm

M18 Series Fixed-Field Mode

Models

M18SN6FF25

M18SN6FF25Q

M18SP6FF25

M18SP6FF25Q

Cutoff

Point

Cable

Supply

Voltage

With 25 mm Far Limit Cutoff

Output

Type

2 m (6.5')

4-Pin Euro-style QD

NPN

25 mm

(1")

10-30V dc

2 m (6.5')

4-Pin Euro-style QD

PNP

Excess Gain

Performance based on 90% reflectance white test card

1000

E 100

M18 Series

Fixed-field mode

with 25 mm far

limit cutoff

G 10

.1 mm

.004 in

1 mm

10 mm

.04 in

.4 in

DISTANCE

100 mm

4 in

With 50 mm Far Limit Cutoff

M18SN6FF50

M18SN6FF50Q

2 m (6.5')

4-Pin Euro-style QD

NPN

50 mm

(2")

10-30V dc

M18SP6FF50

M18SP6FF50Q

2 m (6.5')

4-Pin Euro-style QD

PNP

1000

E 100

G 10

.1 mm

.004 in

M18 Series

Fixed-field mode

with 50 mm far

limit cutoff

1 mm

10 mm

.04 in

.4 in

DISTANCE

100 mm

4 in

With 100 mm Far Limit Cutoff

M18SN6FF100

M18SN6FF100Q

2 m (6.5')

4-Pin Euro-style QD

NPN

100 mm

(4")

10-30V dc

M18SP6FF100

M18SP6FF100Q

2 m (6.5')

4-Pin Euro-style QD

PNP

1000

E 100

G 10

.1 mm

.004 in

M18 Series

Fixed-field mode

with 100 mm far

limit cutoff

1 mm

10 mm

.04 in

.4 in

DISTANCE

100 mm

4 in

* 9 m (30') cables are available by adding suffix âW/30â to the model number of any cabled sensor (e.g., M18SN6FF25 W/30).

A model with a QD connector requires an optional mating cable. See page 6 for more information.

The excess gain curves above show

excess gain vs. sensing distance for M18

Series fixed-field sensors with 25-, 50- and

100-millimeter cutoffs. Maximum excess

gain for the 25-mm models occurs at a

lens-to-object distance of about 7 mm; for

the 50-mm models, at about 10 mm; and

for the 100-mm models, at about 20 mm.

Sensing at or near these distances will

make maximum use of each sensorâs

available sensing power.

Backgrounds and background objects

must always be placed beyond the cutoff

distance.

These excess gain curves were generated

using a white test card of 90% reflectance.

Objects with reflectivity of less than 90%

reflect less light back to the sensor, and

thus require proportionately more excess

gain in order to be sensed with the same

reliability as more reflective objects. When

sensing an object of very low reflectivity, it

may be especially important to sense it at or

near the distance of maximum excess gain.

The effects of object reflectivity on cutoff

distance, though small, may be important

for some applications. Sensing of objects

of less than 90% reflectivity causes the

cutoff distances to be âpulledâ slightly

closer to the sensor. For example, an

excess gain of 1 for an object that reflects

1/10 as much light as the 90% white card

is represented by the heavy horizontal

graph line at excess gain = 10. An object

of this reflectivity results in far limit cutoffs

of approximately 20, 40 and 70 mm (for

25-, 50- and 100-mm cutoff models,

respectively).

Objects with reflectivity greater than 90%

return more light to the sensor. For this

reason, highly reflective backgrounds or

background objects such as mirrors, pol-

ished metal, and other sources of specular

reflections require special consideration. If

it is necessary to use a highly reflective

background, it should be placed as far

beyond the cutoff distance as possible and

angled to direct reflected light away from

the sensor (see page 4).

Banner Engineering Corp. â¢ Minneapolis, U.S.A.

Website: http://www.baneng.com â¢ Tel: 888.373.6767

page 3

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