FR2459983A1 - Optical detection of passage of bright object - using detector which operates in reflex mode for positioning adjustment and using IR beam - Google Patents

Abstract

A shiny object such as a car body or bright steel sheet is detected by its passage through a luminous or infra red beam. Two emission and reception assemblies operate in a reflex mode to simplify positioning alignment. An opto electronic assembly comprises an emitting diode (3) and a receiver element (4). A beam separates (5) is associated with each emitter and receiver. A two position switch allows the detector to operate in a reflex mode whereby the emitter and receiver are synchronous with one phase (Q1) to permit alignment of the beam with the aid of a catadioptric element. A second switch position allows the detector to operate in the normal manner synchronised from a second phase (Q2). The receiver output operates a relay circuit (1) when an object is detected.

Description

 The present invention relates to a device for detecting an object by obscuring a light beam or not, for example infrared.

 I1 is known to use devices, type dams, comprising a transmitter and a receiver distant from each other, object detection being by breaking the beam from the transmitter and normally striking the receiver actuating any suitable relay.

 Difficulties arise when, for example, the beam corresponds to invisible radiation, in particular infrared radiation, since it is then particularly difficult to align the transmitter and the receiver.

 The device according to the invention offers all the advantages of the light barrier, namely certain obscuring of the beam by an opaque object, whatever its surface condition (shiny, polished or painted sheet metal in the case of car bodies).

 In addition, it eliminates the difficulties, or even the impossibility of long-range alignment, of an infrared beam.

 More specifically, the device according to the invention allowing the detection of an object by occultation of a beam, is notably remarkable in that it comprises two optoelectronic assemblies arranged opposite, each assembly associated with a transmission and reception circuit, comprising a transmitter, a receiver and a separating plate, at least one of said assemblies operating in reflex during the installation and adjustment of said device.

 According to one embodiment, the two assemblies are capable of operating in reflex, a switch which is provided with each assembly allowing the reflex-barrage switching.

 According to another embodiment, the reception and transmission circuits are synchronized over two phases.

 Advantageously, in the latter case, synchronization takes place directly on the supply network.

Other advantages and characteristics will emerge more clearly on reading the description which follows, made with reference to the figures given for information and in no way limitative, among which - FIG. 1 is a diagram illustrating the device according to one embodiment.
tion of the invention, - Figure 2 shows an example of synchronization, - Figure 3 shows the installation of the device of Figure 1, and - Figure 4 is a diagram illustrating the device according to another mode of
realization of the invention.

 With reference to FIG. 1, an embodiment of the device according to the invention will now be described.

 Optoelectronic assemblies 1, 2, each comprising for example a transmitting diode 3, a receiving element 4, a separating plate 5 (devices known elsewhere), are each associated with an electronic transmitting and receiving device which, at in turn, activates an output relay 1 ', 2'.

 Furthermore, a synchronization circuit generates, from the supply network, pulses q 1 and q 2 out of phase with each other.

 By way of example, FIG. 2 shows a phase shift of Xt / 2 between te 1 and Q 2. In this FIG. 2, curve I represents the rectified sector, curves II and III respectively illustrating the emission pulses of the assemblies 1 and 2. The pulses L41, being synchronous with the passage to zero of the alternations of the supply network, the pulses Q 2 are offset by </ 2 with respect to q 1.

 In addition, a two-position switch placed on each sensor (optoelectronic assembly) allows the operation of each of the sensors, either in reflective function or in barrier function.

 Each switch being placed in position 1, the two sensors operate in reflex; when the switches are in position 2, the sensor 1 sends synchronous pulses to (21. Conversely, transmission 2 and reception 1 are synchronized with Q 2.

 The installation of the device described above will now be explained, reference being made to FIG. 3.

 I1 is first of all reminded that the device according to the invention being intended for the realization of a dam of great range (10 m. And more), it would be physically impossible to proceed with the alignment of a traditional dam ( transmitter and receiver) over such a distance due to the infrared emission (invisible) of the light beam.

After mechanical assembly of said device, the setting mode is as follows - the switch of sensor 1 is placed in position 1 (sensor 1 operates
then in reflex, its emission and its reception are synchronous to Coq1).

- a reflector 6 is placed in place of the optics of the sensor 2.

- the orientation of the sensor 1 is sought so as to obtain the engagement
its relay 1 '; this operation being carried out, the sensor beam
1 is able to cover the optics of the sensor 2.

- we proceed in the same way to align the sensor 2, by placing a reflector,
not shown, on the optics of the sensor 1.

- the two sensors 1 and 2 being aligned by means of retro-reflectors,
the two switches in position 2. Two dams are thus produced
crossed operating alternately one on ttl, the other on 2; that
is to say that a selection over time is obtained between the beams
sensors 1 and 2, each of them working half the time and alternating
tively.

 In order to avoid an additional electrical connection between the sensors 1 and 2, the synchronization signals are generated from the AC supply sector.

In addition to this type of synchronization on the network line, with synchronization of the pulses with respect to the network sinusoid, other modes of synchronization can be provided, namely - a mode of synchronization by connecting cable between the two sensors,
this synchronization being independent of the network sinusoid.

- a synchronization mode using the trunk which, by circuits
appropriate, allows the transmission and reception of sync pulses,
but always without necessarily having a temporal coincidence with the
network sine wave.

 In addition, at the limit, it is possible not to synchronize the receiver with respect to the transmitter; in this case, the receiver is sensitive to repeated light pulses but not referenced in time.

 The latter solution further simplifies the circuits and no electrical connection between the sensors is necessary.

 The device of FIG. 1 uses two reflex sensors switchable in a barrier; it is also possible to use a device where only one sensor is reflex, this is what appears in FIG. 4.

 The sensor 7 is a reflex system; its emission E1 meets the reflector 8 placed in front of the optics of the sensor 9, only when adjusting in the direction of the sensor 7.

 The presence of the reflector 8 causes reception R2 through the optics of the sensor 7. This reception acts on an indicator light 10, the lighting intensity of which is proportional to the level of the reception signal R2.

 When the indicator light 10 is fully illuminated, the reflector 8 is removed, the emission E1 causes the reception R1 which, amplified, activates the relay 11.

 Preferably, the optics of the sensor 9 have a large aperture, which prevents precise alignment of this sensor.

 The assembly then constitutes a simple barrier, one of the elements of which is a reflex sensor driving a warning light. This set has the advantage of leading to an economical production compared to the device of FIG. 1, while retaining the main advantages.

 In addition, the various synchronization modes, or the possible non-synchronization, described for the device of FIG. 1 are of course applicable to the device of FIG. 4.

Claims (8)

 1. Device for object detection by occultation of a beam, characterized in that it comprises two optoelectronic assemblies arranged opposite, each assembly, associated with a transmission and reception circuit, comprising a transmitter, receiver and separating plate, at least one of said assemblies operating in reflex during the installation and adjustment of said device.  2. Device according to claim 1, characterized in that the assembly operating in reflex is provided with a light sensitive to the lighting and making it possible to determine its maximum illumination corresponding to the optimal alignment of the two sets.  3. Device according to claim 2, characterized in that the optics of the other assembly has a large opening.  4. Device according to claim 1, characterized in that the two assemblies are capable of operating in reflex, a switch which is provided with each assembly allowing reflex switching - barrier.  5. Device according to claim l, characterized in that the reception and transmission circuits are synchronized to the network and out of phase with each other.  6. Device according to claim 5, characterized in that the phase shift is </ 2.  7. Device according to one of claims 5 or 6, characterized in that the synchronization is done according to the trunk.  8. Device according to one of claims 5 or 6, characterized in that the synchronization is done using an additional line.