FR2635871A1 - Method for detecting splices on a moving tape (strip) - Google Patents

Abstract

The invention relates to a method for inspecting moving tapes (strips) with a view to detecting splices. The method consists in passing the tape (strip) in front of two detection units (1, 2) each comprising an emitter and a receiver, and in measuring the difference in density between the two tape (strip) portions placed respectively under each emitter/receiver unit. Application to photographic products in tape (strip) form.

Description

METHOD FOR DETECTION OF SPLITS ON A STRIP
MOVING
The invention relates to a method of inspecting moving bands for the detection of seams on said bands, which method makes it possible in particular to distinguish between a seam and an existing wetting front, for example, on products. photographic in bands.

 Many types of moving tape inspection devices are known. Generally, these devices use a light source which constantly irradiates one side of the strip and photosensitive means which receive the beam coming from the light source by being either reflected or transmitted by this strip.

The intensity of the beam detected by the photosensitive means is modulated by the variations in uniformity of the strip and this intensity is transmitted into signals which are used to determine the location of the defects. These defects may consist of variations in the thickness of the strip or in variations in the thickness of the product deposited on the strip. Usually these inspection devices are calibrated or adapted manually, that is to say the detection of faults is obtained by comparing the signals from the photosensitive means with predetermined constants. U.S. Patent 3,534,402 discloses a device for inspecting a moving web in which light sources are constantly irradiating the moving web to obtain information representative of the uniformity of the density of the moving web. This information is sent to a fault detection circuit.

 U.S. Patent 4,323,786 describes a device for detecting the presence of a bond on a moving strip comprising a light source directed on said strip and reflected successively on two detectors spaced in the direction of movement of the band. The modification of the luminous flux received by each detector makes it possible to detect said cut and to measure the speed of movement of the cut to control the manufacturing apparatuses as a function of the position of said cut.

 However, for certain applications and in particular in the field of photography, any change in density does not necessarily correspond to the detection of a seam to be treated as such. For example, there is what is commonly called a "wetting front" which corresponds to the leading edge of the photographic emulsion deposited on the strip and which in conventional fault detection systems is not taken properly considered. the passage of this wetting front is interpreted in the same way as any other defect (glue, transverse stripe, etc.) since when it passes we will record a change in density which will be interpreted and treated as a glue. '' This is not without problems when you know that the detection of a glitch modifies the operating conditions of the machines.

 It is therefore one of the objects of the present invention to detect the presence of a collage on a photographic strip and to allow a differentiation between said collages and the wetting fronts.

 It is also an object of the present invention to allow the detection of a break on a band moving at high speed; in one embodiment, it is between 50 and 200 m / min. Other objects of the invention will appear in the description which follows.

 The method according to the invention is a method of detecting seams between two contiguous bands in which the seam has a density different from that of the two bands and is caused to pass successively past two detection units each comprising a transmitter and a receiver placed in look, said method being characterized in that said sizing is detected by measuring the density difference between the two portions of band placed respectively under each transmitter / receiver group.

In the description which follows, reference will be made to the figures in which
- Figure 1 shows in schematic form a particular device for implementing the method according to the invention
- Figure 2 illustrates the response of the electronics to the passage of a bond in front of the device for implementing the method (Figure 2a) and to the passage of a wetting front (Figure 2b).

A bond actually defines the connection between two contiguous supports or bands, which connection can be made by adhesive tape or other equivalent means, the width of which can be of the order of 50 mm. The two bands that can be connected can be of the same type (paper
RC / RC paper, estar / estar) or of a different type (paper
RC / estar, estar / RC paper). Thus the passage of a collage will result in two variations in density (support - support + adhesive tape | support), an essential condition being that the density of the collage must be different from that of the two supports. same type, the density at the exit of the collage will be of the same order of magnitude as the initial density; in the case where the supports will be of different nature, we will obtain markedly different densities. As for the passage of a wetting front, it will result in a single change in density corresponding to the passage from the non-emulsified part to the emulsified part.

 FIG. 1, to which reference is now made, represents in schematic form a particular device making it possible to implement the method according to the invention.

 This device consists of two infrared sources (1) and two receivers (2) placed opposite. The distance d between the detectors will preferably be less than the width of the edge so that the edge can be at the same time under the two sensors, particularly when there is an edge between two supports of different type so as to obtain two differentiable signals when each detector passes. Likewise, this distance d should not be too small in order to take account of the response time of the electronics - for example for a gap with a width of 50 mm, the distance d may be between 10 and 40 mm. Each transmitter / receiver group is placed so that the film passes successively in front of each of them. The light emitted by infrared sources supplied by a current source (5) is transmitted to the receiver. Preferably the diameter of the light spot on the film will be of the order of mm. This will be achieved using well-known techniques, such as using an optical system with several fixed lenses.

 The logarithmic amplifier (3) measures the differential density between the two receivers. If the densities are equal, the output signal will be zero. At the output of the electronics, a threshold comparator (4) for each polarity, formats the analog signal into a binary signal so as to eliminate the noise inherent in the film.

 This embodiment is of course not limiting.

Thus, in a preferred embodiment, additional electronics are provided, comprising in particular an optical encoder emitting a frequency proportional to the running speed of the strip to be inspected and thus making it possible to measure the length of the defect whatever the running speed of the band. We can thus get rid of the problem of small defects that do not correspond to collages.

 FIG. 2 to which reference is now made illustrates the response of the electronics to the passage of a bond in front of the device for implementing the method (FIG. 2a) and to the passage of a wetting front (FIG. 2b).

 For clarity of description, reference is made only to the case where the two supports on either side of the edge are identical, but it is obvious that when this is not the case, two groups of signals are also obtained. distinct corresponding to the passage of the collage in front of each transmitter / receiver group. Thus the passage of a collage in front of the first transmitter / receiver group will cause a pulse (6) whose amplitude will be proportional to the difference in density between the collage itself and the support.

When the gap arrives in front of the second transmitter / receiver group, the difference in density between the two portions of bands placed respectively under each transmitter / receiver group will be zero until the gap has completely passed in front of the first group. At this time, a new impulse (7) will appear, the amplitude of which will be the same as that of the first when the supports on either side of the edge will be identical. This second impulse will last until the pass has passed completely in front of the second transmitter / receiver group. Thus the passage of such a bond which is defined by a momentary variation of the density, will result in two pulses in the output signal.

 Similarly, the passage of a wetting front in front of the first transmitter / receiver group will cause a pulse (8) whose amplitude will be proportional to the difference in density between the non-emulsified zone and the emulsified zone. This pulse will last until the mooring front passes in front of the second transmitter / receiver group. From this moment, the density difference between the two transmitter / receiver groups will become zero again. Thus, when passing through a wetting front, which is defined by a single and final variation in density (of the rung type), a single pulse will be observed in the output signal.

Claims (4)

1 - Method for detecting seams between two bands  contiguous in which the edge has a density  different from that of the two bands and is brought to  pass successively in front of two detection units  each comprising a transmitter and a receiver placed  facing each other, said method being  characterized in that the seams are detected in  measuring the difference in density between the two  strip portions placed respectively under each  transmitter / receiver group.  2 - Method according to claim 1 wherein the two  bands on either side of the seam are the same  nature. 3 - Method according to claim 1 wherein the two  bands on either side of the bond are of a nature  different. 4 - Method according to claim 3 characterized in that  the distance between the two detection units is  less than the width of the seam.