FR2646904A1 - Device for measuring a transverse dimension of a substantially cylindrical object, for a plurality of cross-sections of this object - Google Patents

Abstract

A generator generates a beam of parallel light rays. The object 1 is held in the beam by a support 3. A detector measures the width, along Ox, of the shadow zone generated by the object 1. Means 38, 351 move the support 3 and therefore the object 1, in an oscillating movement of direction Oz parallel to the axis of the said object, to measure its transverse dimension in a plurality of cross-sections. The invention applies to the automatic measurement of the diameter of cigarettes.

Description

The subject of the present invention is a device for measuring at least one transverse dimension of a substantially cylindrical object comprising - means for generating a light beam with rays
parallel, - means for holding said object in said beam
light beam, so that it creates a shadow area
of thickness equal to the dimension to be measured, and - means for measuring said thickness.

Such a device is used in particular in the field of tobacco, to measure the diameter of cigarettes, for the purposes of manufacturing control, for example.

It will be noted here that the means for measuring the thickness of the shadow zone are arranged to measure this thickness in a given direction, perpendicular to the parallel rays and that, so that the measurement of the thickness of the number zone is representative of the dimension transverse, here the diameter, of the object, it must be arranged so that its axis is orthogonal both to the light rays, and to the direction of measurement.

An apparatus comprising the means for generating the light beam, and the means for measuring the thickness of the shadow area is described in patent FR-2 419 508. In this apparatus, the beam is generated by a lamp ' filament, associated with a collimating lens, and a network of photodiodes makes it possible to measure the thickness of the number zone.

In another device, marketed by the Japanese company KETENCE under the reference LS 3030, the beam comprises a single laser brush, or ray, which moves parallel to itself, at high and constant speed.

The thickness of the shadow area is measured by measuring the time during which the laser brush is interrupted. In this device, the beam is practically contained in a plane, which is the one in which the thickness is measured.

When measuring the diameter of cigarettes with a device of the type defined above, it is possible to make only one measurement of diameter per cigarette.

However, a cigarette only approaches substantially the shape of a perfect circular cylinder, and its section is never strictly a circle. Also, it is frequent, in order to properly characterize each type of cigarette, for example to detect imperfections in its manufacturing process, to measure the diameter of each cigarette in a plurality of directions, regularly distributed.

For this purpose, the cigarette is rotated around its axis, and lton performs a plurality of measurements of the thickness of the shadow area corresponding to different orientations, which thus makes it possible to determine a plurality of values of the variable diameter. of each cigarette.

However, in the case where only one diameter value is measured per cigarette as in the case where a plurality is measured relative to the same section, the causes which may affect the regularity of this diameter from one section to another of the cigarette.

This implicitly assumes that the axial variations in the dimensions of the cigarette are zero, which is not necessarily the case. This results in a risk of error in the appreciation of the diameter, if for example the measurement is carried out in a section deformed following a shock or an analogous reason, or in a section where a paper particle partially torn off is projecting from the body of the cigarette, thereby increasing the thickness of the shadow area, and therefore the measured diameter.

The present invention aims to overcome this drawback.

To this end, it relates to a device of the type defined above, characterized in that it comprises means for relative displacement of said object relative to said beam, according to an oscillatory movement of direction parallel to the axis of said object, in order measuring said transverse dimension for a plurality of sections of said object.

 In this case, the terror risk due to an irregularity in the apparent diameter of the cigarette along its axis is considerably reduced since there are a plurality of diameter values for different sections. It is sufficient to calculate the average of these values to significantly reduce the influence of an outlier and if one wishes to completely eliminate such a value, it is possible to do so by known methods of comparison and elimination of any value too far from the average value.

Advantageously, means are provided for driving said holding means in rotation, so that said object rotates about its axis.

In this case, it is possible to measure a plurality of values of the diameter of each cigarette, these values being obtained for different sections, and for different orientations of each section. The plurality of measured values thus contains relatively complete information.

Advantageously also, said displacement is a periodic oscillatory movement of half-period substantially equal to the duration of one revolution of said rotation or to a sub-multiple of it.

In this case, we obtain a regular distribution, over the analyzed portion of each cigarette, of the diameters whose value is measured. The analyzed portion corresponds to that which is swept by the beam during the oscillatory movement of the object along its axis. After one or more rotations of the object on itself, a plurality of measurements are regularly distributed axially and radially. A simple calculation of the average of these values makes it possible to obtain, for the diameter of the cigarette, a value for which the contribution of each of the sections and of each of the directions is the same, and which is therefore very representative.

Advantageously also, said holding means comprise a support provided with a cylindrical hole traversed by said object, the height of said cylindrical hole being equal to a substantial part of the height of said object, and means for pushing said object against the wall of said hole cylindrical, so that at least one generator of said cylindrical hole coincides with a substantial portion of a generator of said object, and said thickness measuring means are arranged to measure the thickness of the area of shadow in a direction orthogonal to said generatrices and to said parallel rays.

With such a device, the object is immobilized against the wall of the cylindrical hole and the direction of its axis is strictly the same as the direction of the generator of the cylindrical hole, orthogonal to the direction of measurement of the thickness. The measurement carried out is therefore rigorous.

Indeed, the height of the cylindrical hole being equal to a substantial part of the height of the object, and by substantial part, it is necessary to understand here a part superior to appreciably a third, the two generatrices coincide over a length large enough so that we can consider their two directions as confused.

In addition, the friction between the object and the cylindrical hole, under the action of the pressure exerted by the thrust means, is sufficient to immobilize the object even when the cylindrical hole is arranged vertically and the object is subjected to the action. of its own weight.

This last characteristic is particularly appreciable when measuring the diameter of a cigarette, because it allows the insertion of the device of the invention in a chain of devices where the cigarette moves, from one device to another, by gravity, and always remaining vertical. In known manner, such a channel comprises a succession of measuring devices, for example a weighing device, a draft and ventilation measuring device, a diameter measuring device, and so on. These different devices are arranged one below the other, and each is arranged so that its measurement is carried out on the vertically disposed cigarette, the latter penetrating from above into the measuring station, and emerging from below. case, the path of the cigarette, from one end to the other of the catne is a vertical line. This avoids complex and costly cigarette delivery systems from one station to another, and also a waste of time between one station and the other.

Advantageously also, said pushing means comprise a plurality of orifices made in said cylindrical hole, and pneumatic means for sucking or blowing air through said orifices.

In this case, it is simple to control the pneumatic means for holding or not holding the object, which facilitates the automation of the device for the rapid treatment of a series of objects.

In a first and a second embodiment, said beam is stationary in said direction parallel to the axis of said object, and said displacement means move said holding means.

In a third embodiment, said holding means are stationary in said direction parallel to the axis of said object, and said displacement means move said beam.

In this case, and advantageously, said displacement means comprise a transparent blade with parallel faces, arranged in the path of said beam, and means for driving said blade in pivoting.

The present invention will be better understood from the following description of the preferred embodiments of the device of the invention, made with reference to the accompanying drawings, in which, - Figure 1 shows a schematic perspective view of a first embodiment of the device of the invention, - Figure 2 shows a schematic top view of the support of the device of Figure 1, - Figure 3 is an elevational view, in partial section, of a part of the device of Figure 1, during a phase of receiving an object to be measured, - Figure 4 is a view similar to that of Figure 3, during a phase of measuring the object received, - Figure 5 is a view similar to that of FIGS. 3 and 4, during a phase of evacuation of the measured object, - FIG. 6 is a partial perspective view of the device of FIG. 1, - FIG. 7 is a view in elevation, in partial section, of a second form of real sation of the device of the invention, and, - Figure 8 is a schematic view of a third embodiment of the device of the invention.

Referring to Figure 1, a device for measuring a transverse dimension, here the diameter, of a substantially cylindrical object, here a cigarette, is now described.

In known manner, this device comprises a generator 2 of a beam 20 of parallel rays 200, a receiver 5 of this beam 20, and a support 3 for holding a cigarette 1 in the light beam 20 so that the area d shadow 4 generated by it has a thickness E equal to the diameter to be measured of cigarette 1.

Here, the beam 20 has the form of a flat sheet extending in the horizontal plane xOy of an orthonormal reference frame
Ox, Oy, Oz. The direction of the parallel rays 200 is the direction Oy, and the beam extends, according to the direction
Ox, over a width clearly greater than the diameter to be measured.

The receiver 5 is arranged to receive the beam 200 over its entire width and arranged, in a known manner, to measure the width E, in the direction Ox, of the shadow zone 4 generated by the cigarette 1.

The support 3 is here a circular cylinder of axis R parallel to the direction Oz, in which a cylindrical hole is made, here a bore 30 in the shape of a circular cylinder, also of axis R. The diameter of the bore 30 is greater than the maximum diameter of the cigarette 1, and the height of the cylinder 3, and therefore of the bore 30 is equal to a substantial part, here substantially half, of the height of the cigarette 1. This value of the height of l the bore, equal to half the height of the cigarette, is not critical, but as will be better understood in the following, it is desirable that the height of the bore remains greater than a substantial part of the order of a third, the height of the cigarette 1.

The cigarette 1 is arranged to pass through the bore 30 and, in a way which will be better understood below, and which is shown diagrammatically by the arrows F in FIG. 2, it is subjected to forces which push it against the wall. bore 30. I1 then results, obviously, that a generator P of cigarette 1 coincides, on its substantial portion which passes through bore 30, with a generator G of this bore.

FIG. 2 shows a top view of the cigarette 1 with the bore 30 of the support 3, as well as the points of passage of the axis R, of the generators G and P, and of the axis
C of the cigarette.

It is understood that, due to the coincidence between the generators G and P, the direction of the axis C of the cigarette 1 is strictly that of the generators G and P and of the axis R, that is to say the direction of the Oz axis.

Thus, thanks to lateral thrust forces, that is to say towards the wall of the bore 30, which, as will be better understood hereinafter, are relatively simple to implement, it not only manages to immobilize the cigarette I, but also to force it to orient itself rigorously in the direction Oz, so that the measurement of the thickness E, carried out by the receiver 5 in the direction Ox, effectively represents the diameter of the cigarette 1.

To carry out a plurality of measurements of the diameter of the cigarette 1 in different directions orthogonal to its axis C, and for different abscissa sections along this axis, the support 3 is here driven on the one hand in rotation around its axis R, as shown by arrow 37, and on the other hand in oscillatory translation of direction parallel to this axis, as shown by arrows 39. I1 results therefrom two oscillatory movements of the projection of the cigarette on the plane xOz, l 'one according to Ox, the other according to Oz. These movements do not however disturb the measurement of the diameter, provided that the cigarette 1 does not leave the beam 20, which is the case if the width of the latter is greater than the diameter of the bore 30, and if the amplitude of movement according to Oz remains moderate.

The rotational movement of the cigarette 1 on itself can be broken down into two elementary movements.

The first elementary movement causes the axis C of the cigarette to describe a circular cylinder centered on the axis of rotation R of the cylindrical hole. The second elementary movement is a revolution of the cigarette around its axis, which is synchronous with the revolution of the cylindrical hole around its own. In other words, when the cylindrical hole has made a turn, the cigarette also makes a turn. Since the first elementary movement results in a lateral oscillation of the shadow area in the beam, which remains without influence on the thickness of the shadow area, it appears that, from the point of view of the measurement of the diameter, everything happens as if only the second elementary movement took place.

This is indeed the aim sought to measure this diameter in a plurality of directions directly linked to the different positions of the cylindrical hole.

Referring to Figures 3 to 6, we now describe a first embodiment of the device of the invention. In this device, the oscillatory movement along the axis C is linked to the rotational movement of the support 3 around its axis. Furthermore, the thrust forces of the cigarette 1 include a plurality of orifices 300 formed in the bore 30, along the generator G, and a suction pump 6, for sucking air through said orifices.

To this end, the orifices 300 communicate with a conduit 33, formed in the thickness of the walls of the support 3, which itself commnnicates with an annular groove 34, formed in the external wall of the support 3.

The support 3 is slidably mounted, along the axis Oz, in a fixed sleeve 35, inside which it can also pivot, and in which a conduit 346 is formed, which permanently places the groove 34 and the suction pump 6.

A vacuum gauge 7 is provided for measuring the residual pressure in the conduit 346, that is to say the pressure downstream of the orifices 300. I1 is connected to an alarm 8, so as to trigger it if the pressure measured in the conduit 346 is greater than a threshold.

As shown more particularly in FIG. 6, the support 3 is provided, in its upper part disposed outside of the sleeve 35, with a finger 38 which extends radially, and which cooperates with a ring 351, here of the same diameter as the inner diameter of the sleeve 35, and disposed around its upper orifice. The upper face of the ring 351 is here of sinusoidal profile.

An assembly 32, comprising a motor and a reduction gear, is provided for driving, by means of a belt 323, the support 3 in rotation about its axis R. The belt 323 is flexible enough to allow the support to slide 3 in the sleeve 35 of amplitude equal to that of the variations in the profile of the ring 351.

A device 31 is provided for closing the lower opening of the bore 30. The device 31 comprises, in known manner, a controllable flap which closes, or opens, the lower opening of the bore 30.

A device 100, similar for example to device 31, is provided for closing the lower opening of a bore 10, of axis R, disposed above the bore 30, and which represents the lower part of a station supply of cigarettes, or a weight measurement station or another parameter, in which each cigarette is arranged vertically in the bore 10.

An electronic control circuit 9, for example with a microprocessor, receives, from the receiver 5, a signal E representative of the thickness of the measured shadow area, and, coming from assembly 32 a signal M representative of the rotational displacement of its output shaft, therefore of the support 3.

The circuit 9 delivers control signals VI and V2 from the shutter devices 100 and 31 respectively, a control signal A from the vacuum gauge 7, and a control signal P from the suction pump 6.

The device which has just been described operates as follows.

The assembly 32 for driving the support 3 is arranged to ltentraSner permanently, and at constant speed, around its axis R, as shown by the arrows 37. As the weight of the support 3 means that the finger 38 remains permanently in contact with the ring 351 of sinusoidal profile, this results in an oscillatory movement of the support 3, in the direction Oz. Thus the cigarette 1 is entangled, relative to the beam 20, moving in direction parallel to its axis, which allows the measurement of its diameter for a plurality of its sections. This movement is shown schematically in the figures by the arrows 39. I1 is here periodic oscillatory, of half-period equal to a sub-multiple of the duration of a revolution of the rotation of the cigarette 1 on itself, that is to say say of the rotation 37 of the support 3, because several periods of variation of the profile of the ring 351 are included in its circumference.

With reference now to FIG. 3, the phase of reception of the object is described. During this phase, the circuit 9 controls the stopping of the pump 6, inhibits the vacuum gauge 7, closes the shutter device 31 and opens the device 100, so as to drop the cigarette 1, according to arrow 12, in a vertical position, from the wise axis 10 towards the bore 30 rotated 37. As the cigarette 1 falls along Itaxe R, and the diameter of the bore 30 is greater than that of the cigarette 1, that -this is positioned to pass through the bore, and it is stopped by the flap of the device 31. To facilitate this operation, the upper opening of the bore 30 is flared. As the diameter of the bore 30 is greater than that of cigarette 1, the latter is not arranged, a priori, so that its axis C is parallel to the axis R.

However, during the measurement phase, represented in FIG. 4, the circuit 9 controls the suction pump 6, and the pressure difference thus created between the orifices 300 and the rest of the volume of the bore 30 has the effect of pushing the cigarette 1 against the generator G. The orifices 300 are normally blocked by the cigarette 1, which means that the pressure in the duct 346 is quite low.

The alarm 8 is thus not triggered by the vacuum gauge 7, which is put into service by the circuit 9 during the measurement phase. If, on the other hand, the cigarette 1 is badly positioned, at least one orifice 300 will be free, and the pressure in the duct 346 cannot fall sufficiently, which will have the effect of triggering the alarm 8.

During the measurement phase, the circuit 9 controls the pump 6 so that it operates so as to maintain the cigarette 1 for an interval of time equal to the duration of a half-turn, or even a turn complete, and it stores the series of values of the signal E measured for a series of instants regularly distributed along this time interval, in order to obtain a series of values of the diameter in directions regularly distributed around the axis C of cigarette 1 and for sections of this cigarette regularly distributed along this axis C, in its portion swept by the beam 20.

Without this being compulsory, the circuit 9 can control the shutter of the device 31 so that it releases the lower opening during the measurement phase, so as to avoid friction of the lower end of the cigarette 1.

During the evacuation phase of the cigarette 1, shown in FIG. 5, the flap of the device 31 being open, the circuit 9 controls the stopping of the pump, which has the effect of the cigarette falling, according to arrow 13, to the next work station, or to a receiving basket.

A new measurement can then be made, and so on.

It will be noted that with such a device, the support 3 remains continuously driven in rotation, and does not have to be stopped between the departure of one cigarette and the arrival of the next. This is an important advantage, in particular insofar as its speed thus remains rigorously constant without loss of time for setting it in speed and stopping it between each cigarette.

For example, the diameter of the bore 30 is here 10 mm, which allows, with three orifices 300 of substantially 1 mm in diameter, subjected to a vacuum of 500 mbar, to maintain cigarettes whose diameter is between substantially 4 mm and substantially 9 mm.

With reference to FIG. 7, a second embodiment of the device of the invention is now described. This embodiment includes the same support 3 as above, inside which the cigarette 1 is held by suction. However, the support 3 is not here provided with a follower finger like the finger 38, and there is not provided, on the sleeve 35, a ring with a sinusoidal profile like the ring 351. It is a simple annular flange of the support 3 which cooperates with the upper face of the sleeve 35 which ensures the vertical positioning of support 3. I1 follows that if the latter can pivot in the sleeve 35, its vertical position relative to the latter remains the same. To produce the displacement relative of the cigarette 1 with respect to the beam 20, in the direction Oz, it is the sleeve 35 and its drive assembly 32 which are moved.

To this end, the sleeve 35 and its drive assembly 32 are fixed on a plate 73 movably mounted relative to a fixed casing 74, thanks to a vertical guide assembly by rods and bearings, assembly not shown for the sake of simplicity. . The generator 2 of the beam 20 is mounted fixed on the chassis 74. The plate 73 is animated, relative to the chassis 74, dtun alternately up and down movement, thanks to a motor 71 whose axis is provided with an eccentric 72 which cooperates with a light 731 from the plate 73.

With this device, the vertical back and forth movement, shown schematically by the arrows 39, and the rotational movement, shown schematically by the arrow 37, can be controlled independently of one another. In practice, if it is desired to obtain a regular distribution of the measurements, it is preferable to provide for the vertical oscillatory movement to be of half-period substantially equal to the duration of one turn of the rotation, or to a sub-multiple of that -this. In the case where the half-period of the vertical oscillatory movement is substantially equal to one revolution of rotation, the series of diameters measured is distributed helically over the portion of cigarette scanned by the laser beam.

With this device, it is also possible to obtain a vertical stepping movement of the cigarette 1, if the motor 71 is a stepping motor. The diameter measurements are then carried out in sections distant by a motor pitch. The vertical movement and the rotation are advantageously synchronized in order to scan each section over a whole number of turns of the cigarette 1.

A limiting case is that where the number of steps is equal to two, and where the cigarette 1 is then animated with a vertical movement whose temporal variations are square signals, only two sections of the cigarette thus being scanned.

In the two previous embodiments, the beam 20 is stationary along the axis Oz and this is the support 3 which is moved along this axis.

In the third embodiment of the device, shown in FIG. 8, the position of the support 3 relative to the axis Oz is fixed, and it is the beam 20 which is displaced by a transparent blade 77 with parallel faces, here glass, arranged on its path, upstream of the cigarette 1. The blade 77 is pivotally mounted about an axis parallel to the axis Ox, and pivotally driven by a connecting rod and a crank connected to a motor 76. When the blade 77 is perpendicular to the beam 20, the latter is not deflected, but when the blade 76 is inclined relative to the beam 20, the latter undergoes a vertical translation, due to the refractions occurring on the parallel faces of the blade 77. In FIG. 8, the amplitude h of the displacement thus obtained has been represented. Here, the receiver 5 is provided with a zone sensitive to the beam of height greater than h and it is not necessary to deviate to new beam 20 after scrutati one of cigarette 1, to bring it back to this sensitive area.

Naturally, it is possible, with the device of FIG. 8, to obtain relative displacements of the cigarette 1 and of the beam 20 continuous, step by step or synchronized with the rotation of the support 3, as with the previous devices, and with a relatively simple mechanical device. It would obviously be possible to replace the oscillating blade 77 by any suitable optical deflection device, allowing the vertical displacement of the plane of the beam 20.

In the above description, it has always been considered that the object to be measured was driven at the same time in vertical translation and in rotation on itself. If the rotational movement is convenient and well adapted when the object is a cigarette which is an imperfect circular cylinder, it is not however compulsory.

Similarly, the present invention is not limited to the device for holding the object to be measured by suction orifices which has been described, this holding device also being able to be purely mechanical, or pneumatic but of another type than that described. Thus, it would be possible to replace the suction pump with a blowing device connected to a source of compressed air. In this case, the cigarette 1 will always be pushed by a pressure difference, but against the generator of the bore opposite to that which includes the orifices.

In this case, it may be desirable to provide orifices along several generators. Similarly, one can provide, inside the bore 3, a series of small inflatable balloons for pushing the cigarette against the wall, or a series of tabs controllable by mechanical means, it being understood that in all cases , the arrangement of these elements is such that the cigarette occupies an off-center position in the bore, so that one of its generators is in contact with a bore generator
In the above description, we have taken the example of a cigarette and a cylindrical hole, or bore, both in the form of circular cylinders. The invention obviously also applies to the case of filters for cigarettes and other rod-shaped objects, and even to the measurement of the transverse dimension of any cylindrical object, whether its base is circular or not.

Thus, depending on the shape of the object to be measured, the cylindrical hole can be in the form of a non-circular cylinder, for example with an elliptical, hexagonal, or other base. In this case, several generators of the object can coincide with several generators of the cyaindric hole.

Claims (8)

Claims 1. Device for measuring at least one transverse dimension of a substantially cylindrical object (1) comprising - means (2) for generating a light beam (20) with parallel rays (200), - means (3 ) to hold said object (1) in said light beam (20), so that it generates a shadow area (4) of thickness (E) equal to the dimension to be measured, and, - means (5) for measuring said thickness, device characterized in that it comprises means (38, 351; 71 -73; 76, 77) for relative displacement of said object (1) relative to said beam (20), in an oscillatory movement direction parallel to the axis of said object, in order to measure said transverse dimension for a plurality of sections of said object (1). 2. Device according to claim 1, in which means (32) are provided for driving said holding means (3) in rotation, so that said object (1) rotates about its axis. 3. Device according to claim 2, wherein said displacement is a periodic oscillatory movement of half-period substantially equal to the duration of one revolution of said rotation or to a sub-multiple thereof. 4. Device according to one of claims 1 to 3, in which: - said holding means comprise a support (3! Provided with a cylindrical hole (30) traversed by said object (î), the height of said cylindrical hole ( 30) being equal to a substantial part of the height of said object (1), and means (6 ,, 300) for pushing said object (1) against the wall of said cylindrical hole (30), so that it results from the coincidence of at least one generator (G) of said cylindrical hole (30) with a substantial portion of a generator (P) of said object (1), and, - said thickness measuring means (5) are arranged to measure the thickness (E) of the shadow zone (4) in a direction orthogonal to said generatrices (G, P) and said parallel rays (200). 5. Device according to claim 4 wherein said pushing means comprise a plurality of orifices (300) formed in said cylindrical hole (30), and pneumatic means (6) for sucking or blowing air through said orifices ( 300). 6. Device according to one of claims 1 to 5, wherein said beam (20) is stationary in said direction parallel to the axis of said object (1), and said displacement means (38, 351i 71 - 73) move said holding means (3). 7. Device according to one of claims 1 to 5, wherein said holding means (3) are stationary in said direction parallel to the axis of said object (and said moving means (76, 77) move said beam (20 ). 8. Device according to claim 7, wherein said displacement means comprise a transparent blade (77) with parallel faces, arranged in the path of said beam (20), and means (76) for driving said blade (77) in pivoting. .