World-beam, Qs30 – universal voltage, Overview – Banner WORLD-BEAM QS30 Series User Manual

WORLD-BEAM

®

QS30 – Universal Voltage

2

P/N 119166 rev. B

Banner Engineering Corp. • Minneapolis, MN U.S.A.

www.bannerengineering.com • Tel: 763.544.3164

Overview

QS30 Series self-contained fixed-field sensors are small, powerful, visible red diffuse

mode sensors with far-limit cutoff (a type of background suppression). Their high excess

gain and fixed-field technology allow them to detect objects of low reflectivity that are

directly in front of another surface, while ignoring the surface in the background.
The cutoff distance is fixed. Backgrounds and background objects must always be placed

beyond the cutoff distance.

Fixed-Field Sensing – Theory of Operation

In operation, the QS30FF compares the reflections of its emitted light beam (E) from an

object back to the sensor’s two differently-aimed detectors R1 and R2 (see Figure 2). If

the near detector (R1) light signal is stronger than the far detector (R2) light signal (see

object A, closer than the cutoff distance), the sensor responds to the object. If the far

detector (R2) light signal is stronger than the near detector (R1) light signal (see object B,

object beyond the cutoff distance), the sensor ignores the object.
The cutoff distance for model QS30FF sensors is fixed at 200, 400 or 600 millimeters (8",

16", or 24"). Objects lying beyond the cutoff distance are ignored, even if they are highly

reflective. However, it is possible to falsely detect a background object, under certain

conditions (see Background Reflectivity and Placement).
In the drawings and discussion on these pages, the letters E, R1, and R2 identify how the

sensor’s three optical elements (Emitter “E”, Near Detector “R1”, and Far Detector “R2”)

line up across the face of the sensor. The location of these elements defines the sensing

axis (see Figure 2). The sensing axis becomes important in certain situations, such as

those illustrated in Figures 5 and 6.

Sensor Setup

Sensing Reliability

For best sensing reliability, the sensor-to-object distance should be positioned to

maximize excess gain. The excess gain curves for these products are shown on page 5.

Sensing at higher excess gains will make maximum use of each sensor’s available

sensing power. The background must be placed beyond the cutoff distance; more

reflective backgrounds must be placed further back. Following these two guidelines will

improve sensing reliability.

Background Reflectivity and Placement

Avoid mirror-like backgrounds that produce specular reflections. False sensor response

will occur if a background surface reflects the sensor’s light more strongly to the near

detector, or “sensing” detector (R1) than to the far detector, or “cutoff” detector (R2).

The result is a false ON condition (Figure 3). Use diffusely-reflective (matte) background

to cure this problem, or angle either the sensor or the background (in any plane) so

the background does not reflect light back to the sensor (see Figure 4). Position the

background as far beyond the cutoff distance as possible.
An object beyond the cutoff distance, either stationary (and when positioned as shown

in Figure 5), or if it moves past the face of the sensor in a direction perpendicular to the

sensing axis, can cause unwanted triggering of the sensor if it reflects more light to the

near detector than to the far detector. The problem is easily remedied by rotating the

sensor 90° (Figure 6). The object then reflects the R1 and R2 fields equally, resulting in

no false triggering. A better solution, if possible, may be to reposition the object or the

sensor.

Sensing

Axis

R1

R2

E

As a general rule, the most reliable sensing

of an object approaching from the side occurs

when the line of approach is parallel to the

sensing axis.

Figure 2. Fixed-field sensing axis

R1

R2

Lenses

Object

A

Object B

or

Background

Sensing

Range

Cutoff

Distance

E

Receiver

Elements

Near

Detector

Far

Detector

Emitter

Object is sensed if amount of light at R1

is greater than the amount of light at R2

Figure 1. Fixed-field concept