• 专利附录
  • 专利说明
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    • 专利摘要:
    The invention relates to a method for measuring the dimensions of empty glass containers (2) consisting of: - choosing at least one region to be inspected from the container, - transporting the containers, - positioning, on both sides of the region to inspect, at least one focus of an X-ray tube and image sensors, - acquire, using image sensors, at least three radiographic images of the area for each container during its movement inspected, - analyze the at least three radiographic images to determine the three-dimensional coordinates of a set of points to derive at least one inside diameter of the neck and / or a thickness of the body.
    公开号:FR3073044A1
    申请号:FR1760173
    申请日:2017-10-27
    公开日:2019-05-03
    发明作者:Laurent Cosneau;Olivier Colle
    申请人:Tiama SA;
    IPC主号:
    专利说明:

    The present invention relates to the technical field of ['inspection of empty glass containers, such as for example bottles, jars, flasks for the purpose of detecting possible dimensional defects.
    The present invention relates more precisely to the measurement of dimensions on empty glass containers, scrolling in line after their manufacture in order to determine whether such containers meet the required dimensional criteria.
    After their manufacture, the empty glass containers are subject to various dimensional checks.
    Thus, it is known that there is a risk that the containers have one or more localized areas of poor distribution of glass affecting the aesthetics or more serious, the mechanical strength of the containers.
    To measure the thickness of the wall of a container, it is known for example from patent EP 0 320 139 or patent EP 0 584 673, a method known as by triangulation consisting in projecting a light beam on the wall of the container with a non-zero angle of incidence, and to collect the light beams reflected by the exterior surface and the interior surface of the wall. These light reflections on these two surfaces take place in the specular directions of the incident beams, that is to say symmetrically to the incident beam with respect to the normal to the surface at the point of impact of the incident beam. The rays reflected by the interior and exterior surfaces of the wall are collected by a lens in order to be sent to a linear light sensor. The thickness of the wall of the container is measured as a function of the separation, at the level of the light sensor, between the beams reflected by the interior and exterior surfaces of the wall. The container is rotated in one revolution to measure its thickness along one of its cross sections.
    An alternative to the previous technique of optical measurement by triangulation is the measurement by the process known as “confocal optical with chromatism” as described by the application DE 10 2007 044 530. This process consists in sending a light beam having a chromatic coding, to recover the beams reflected by the interior and exterior faces, on a sensor making it possible to analyze the wavelength of said reflected beams, and to determine the thickness as a function of the wavelengths of said reflected beams.
    Likewise, patent EP 2 676 127 describes a device making it possible to measure the thickness of the glass wall of the containers at several measurement points distributed over an inspection region superimposed according to a determined height of the container taken according to the 'central axis. The aim of the inspection process is to detect material distribution defects in transparent containers having a central axis and a wall delimited between an outer face and an inner face.
    The optical measurements described above are widely used because they are contactless and fairly rapid, but they all require the containers to be rotated to measure the thickness over a circumference. Indeed, these techniques have in common the projection of a beam of light and the recovery of the light reflected by the two interior and exterior surfaces of the wall. Only certain incidences and corresponding observation directions are then possible, in particular due to specular reflection. Since the containers are generally cylindrical, the measurement is only possible for a narrow region situated around the optical axis of the sensors. It is therefore not possible to use these principles for a measurement of containers scrolling online on a conveyor line during their manufacture.
    In addition, the rotation of the containers necessary for the optical thickness measurement is expensive. Indeed, the rotation requires the use of complex handling equipment. It is indeed necessary to stop the containers arriving in translation on the conveyor, to rotate them during the measurement and to put them back in translational movement on the conveyor. The containers are then brought into contact with guides, pebbles, stars. Adjustments are tedious and involve the use of equipment adapted to each size of container (variable equipment). Finally the rates are limited to 300-400 containers per minute while the current production of glass containers on the most efficient lines currently exceeds 700 containers per minute. In some cases, therefore, double measuring equipment is required.
    In a conventional manner, empty glass containers are also the subject, apart from the measurements of the thickness of their wall, of measurements at the level of the neck or of the ring of the container (internal / external diameters, seal, height) and of the neck. of the container (inside diameter, inside profile, pinout).
    In order to carry out such inspections, it is known to use one or more devices each comprising an inspection head intended to be lowered either over a precise distance depending on the nature of the container, or to come into contact with the container, either to rest on the container during the inspection. Conventionally, such an inspection is carried out using a machine having either a linear conveyor adapted to hold the containers in precise positions, or preferably a star conveyor, with an indexed circular movement for placing the containers in relationship with different checkpoints. Each inspection head is moved in an alternating vertical movement for a star conveyor while for a linear conveyor, the inspection head additionally has a horizontal movement.
    Patent FR 2 818 748 describes an inspection device comprising a head mounted on a horizontal slide which is fixed on a carriage moved in vertical reciprocating movements by a belt mounted between a mad pulley and a pulley driven by a servomotor. One of the drawbacks of such a device is the relatively large displaced mass, which limits the speed and acceleration of movement of the inspection head. As a result, the container inspection rate is limited, which is a major drawback in the on-line container production process. Another drawback of such a known device appears when the inspection head is intended to come into contact with the container. Indeed, the stroke of the inspection head is not defined because of the dispersion of the height of the containers and of the faults which influence this stroke such as those which do not allow the inspection head to descend during a pinout operation. Also, given the indeterminacy of this stroke and the on-board mass, there may occur a significant shock between the inspection head and the container, which is likely to cause deterioration of the container and / or the head inspection.
    Patent GB 1 432 120 describes a device for inspecting containers comprising several control stations, one of which aims at checking the dimensional conformity of the rings and the necks of the containers. This control station includes a mobile assembly driven by a motorization system in an alternating movement relative to the frame of the device, in a direction of movement parallel to the axis of symmetry of the containers. This mobile assembly is equipped with an external gauge for checking the outside of the ring of the containers and an internal gauge for checking the inside of the ring and the neck of the containers. The device described by this document GB 1 432 120 has the same drawbacks as the inspection device described by patent FR 2 818 748.
    The patent FR 2 965 344 by lightening the mobile part, by combining contact detection and dynamic control of the vertical movement, makes the solution much faster, but nevertheless the mechanical movements of handling the containers, the variable equipment and the contact of the calibers with containers remain major drawbacks.
    Analysis of previous technical solutions shows that there appears to be a need for a new technique allowing dimensional measurements to be made on containers without altering their integrity while retaining a high speed of conveying to these containers.
    The present invention aims to satisfy this need by proposing a new non-contact measurement technique making it possible to carry out dimensional measurements on containers traveling in line at high speed.
    To achieve this objective, the object of the invention relates to a method for measuring the dimensions of at least one region to be inspected of empty glass containers of a series each having a wall forming a neck and a body and delimited by a internal surface and an external surface, the method consists in:
    - choose at least one region to be inspected comprising at least part of the neck and / or part of the container body;
    transporting the containers placed on their bottom in a conveying plane along a flat trajectory with a direction materialized by a displacement vector, these receptacles generating a conveying volume during their displacement;
    - positioning, on both sides of the region to be inspected, at least one focal point of an X-ray tube and image sensors sensitive to X-rays and each exposed to X-rays from an associated focal point, these X-rays having passed through at least the region to be inspected producing on each image sensor a radiographic projection in the direction of projection;
    - acquire using image sensors for each container during its movement, at least three radiographic images of the region inspected, obtained from at least three radiographic projections of the region to be inspected whose projection directions are different ;
    - analyze the at least three radiographic images, using a computer system so as to determine a digital geometric model of the region to be inspected containing the three-dimensional coordinates of a set of points belonging to the region inspected, to deduce from the minus an internal diameter of the neck and / or a thickness of the wall of the body.
    In addition, the method according to the invention can also comprise, in combination, at least one and / or the other of the following additional characteristics:
    - the digital geometric model of the region to be inspected containing the three-dimensional coordinates of a set of points consists of:
    • at least two three-dimensional points of the space each belonging to an internal and / or external surface of the wall of the container and located in a plane not orthogonal to a direction of projection, and not parallel to the direction of movement;
    • and / or at least one surface representation of the internal and external surfaces of the wall of the container different from a plane orthogonal to a direction of projection, and different from a plane parallel to the direction of movement;
    • and / or at least one section of the region to be inspected, along a plane different from a plane orthogonal to a direction of projection and different from a plane parallel to the direction of movement;
    - to choose as region to be inspected, at least one defined area extending between two planes parallel to the conveying plane;
    - to choose as region to be inspected, an area comprising the neck and a body part of the container and to determine a digital geometric model of the region to be inspected containing the three-dimensional coordinates of a set of points belonging to the internal and external surfaces of the container wall in the region inspected, to deduce at least an internal diameter of the neck and a thickness of the glass wall of the container body;
    - to position on one side of the trajectory, a focal point from which a divergent X-ray beam from> 120 ° opening or at least two focal points from which diverging X-ray beams from which the sum of the openings is greater or equal to 120 °;
    - to have at least one hearth in the conveying plane;
    - to have on one side of a secant plane of the conveying volume, orthogonal to the conveying plane, a focus from which a divergent X-ray beam comes, so that its beam crosses the secant plane and the region to be inspected;
    - having on the opposite side with respect to the intersecting plane, at least one image sensor associated with said focus to receive the X-rays from said focus;
    - to have on one side of the conveying plane, a focal point from which a divergent X-ray beam originates, so that its beam crosses the conveying plane;
    - having on the opposite side with respect to the conveying plane, at least one image sensor associated with said focal point to receive the X-rays coming from said focal point;
    - to acquire using image sensors, for each container during its movement, at least two radiographic images of the region inspected corresponding to directions of projection defining a useful angle greater than or equal to 45 ° and less or equal to 90 ° and, advantageously greater than or equal to 60 ° and less than or equal to 90 °;
    - to acquire using image sensors, for each container during its movement, at least one radiographic image of the region inspected corresponding to a projection direction having an opening angle with the direction of movement between 10 ° and 60 °;
    - to carry out and acquire radiographic projections of the region inspected of a container so that the X-rays coming from the hearth (s) and reaching the image sensors do not pass through other containers;
    - to acquire, using image sensors, for each container during its movement, radiographic images from between three and forty, and preferably between four and fifteen radiographic projections of the region to be inspected different directions;
    the image sensors are of the linear type each comprising a linear network of elements sensitive to X-rays, distributed along a support line defining with the associated focal point, a projection plane containing the direction of projection, these image sensors being arranged so that:
    • at least m sensitive elements of each of these image sensors receive the radiographic projection of the region to be inspected by the X-ray beam from the associated focal point;
    • the projection planes for the various image sensors are distinct from each other and not parallel to the conveying plane;
    • using each of the at least three linear image sensors, at each incremental movement of each container along the trajectory, radiographic linear images of the region to be inspected according to a chosen number so that for each container, l the entire region to be inspected is completely represented in the set of linear radiographic images;
    • the at least three sets of linear radiographic images of the region to be inspected are analyzed for each container;
    - to make available to the computer system, an a priori geometric model of the region to be inspected from the series of containers, obtained by:
    • the digital model for computer design of the series containers;
    • or the geometric digital model obtained from the measurement of one or more containers of the same series by a measuring device;
    • or the geometric digital model generated by the computer system from entered values and / or from drawings and / or shapes selected by an operator on a man machine interface of the computer system;
    - make the value of the attenuation coefficient of the glass making up the containers available to the computer system.
    Another object of the invention is to provide an installation for automatic measurement of linear dimensions of at least one region to be inspected of empty glass containers each having a wall forming a neck and a body and delimited by an internal surface and a surface. external, the installation comprising:
    a device for transporting the containers in a direction materialized by a displacement vector, along a substantially rectilinear trajectory in a conveying plane, the containers traversing an extended conveying volume in the direction;
    - At least one focal point of an X-ray generator tube located outside the volume crossed, and creating a divergent beam of X-rays directed to pass through at least one region to be inspected comprising at least part of the neck and / or part of the container body;
    - at least three image sensors, located outside the conveying volume, so as to receive X-rays from an associated focal point, the focal point or focal points and the image sensors being arranged so that each images receives the radiographic projection of the region to be inspected by the rays coming from the hearth when the container crosses these rays, the directions of projection of these radiographic projections being different from each other;
    - an acquisition system connected to the image sensors, so as to acquire for each container during its movement, at least three radiographic images of the region to be inspected, obtained from at least three radiographic projections of the region to be inspected , with different projection directions;
    - And a computer system analyzing the at least three radiographic images, from at least the three different radiographic projections, so as to determine a digital geometric model of the region to be inspected containing the three-dimensional coordinates of a set of points belonging to the wall of the container in the region inspected, to deduce at least an internal diameter of the neck and / or a thickness of the wall of the body.
    In addition, the installation according to the invention can also comprise, in combination, at least one and / or the other of the following additional characteristics:
    - at least two x-ray production foci, positioned separately in two distinct positions and at least three image sensors, sensitive to x-rays and positioned so that:
    • each focus emits its beam through at least the region to be inspected to reach at least one associated image sensor;
    • each image sensor is associated with a focal point and receives the X-rays from said focal point after passing through the region to be inspected;
    - at least one focal point from which a divergent X-ray beam is obtained, with an opening greater than or equal to 120 ° or at least two focal points from which the divergent X-ray beams are obtained, the sum of which is greater than or equal to 120 °;
    - at least one hearth arranged in the conveying plane;
    - on one side of a plane intersecting the conveying volume and orthogonal to the plane of conveying, a focal point from which a beam of divergent X-rays comes, so that its beam crosses the intersecting plane and the region to be inspected;
    - on the opposite side with respect to the intersecting plane, at least one image sensor associated with said focal point for receiving the X-rays from said focal point;
    - On one side of the conveying plane, a focal point from which a diverging X-ray beam comes, so that its beam crosses the conveying plane;
    - on the opposite side with respect to the conveying plane, at least one image sensor associated with said focal point for receiving the X-rays from said focal point;
    at least one focal point and two image sensors are arranged so that the directions of projection of the inspected region which they receive have between them a useful angle greater than or equal to 45 ° and less than or equal to 90 ° and, advantageously greater than or equal to 60 ° and less than or equal to 90 °;
    - at least one focal point and one image sensor are arranged so that, when a container crosses the field of image sensors, the direction of projection of the region inspected on the image sensor makes an opening angle with the direction of movement between 10 ° and 60 °;
    - the image sensors and the focal points are arranged so that the X-rays coming from the focal point (s) and reaching the image sensors and passing through the region of a container do not pass through other containers at the same time;
    - between one and four foci, coming from one or more X-ray generating tubes;
    the number and the arrangement of the image sensors and of the associated focal points are such that for each container during its movement, the radiographic projections of the region to be inspected on the image sensors present between three and forty, and preferably between four and fifteen different directions of projection;
    - the image sensors are of the linear type and each comprise a linear network of elements sensitive to X-rays, distributed along a support line defining with the associated focal point, a projection plane containing the direction of projection, these image sensors images being arranged so that:
    • at least m sensitive elements of each of these image sensors receive the radiographic projection of the region to be inspected by the X-ray beam from the associated focal point;
    • the projection planes for the various image sensors are distinct from each other and not parallel to the conveying plane;
    at least three linear image sensors have their support lines parallel to each other;
    - at least three linear image sensors have their support lines orthogonal to the conveying plane;
    - A focal point is positioned on one side of the conveying plane, and according to the invention at least one associated linear image sensor, is positioned on the side opposite the focal point relative to the conveying plane and so that its straight support is parallel to the conveying plane;
    According to the invention, the installation comprises:
    - a device for making available to the computer system, the attenuation coefficient of the glass constituting the containers;
    - a device for making available to the computer system, an a priori geometric model of the region to be inspected, which is a mass memory, a wired or wireless computer network or a man-machine interface;
    - a device for providing the computer system with values and / or tolerances for the dimensions of the neck and / or minimum value for glass thickness for the wall of the body, and / or at least one model geometric reference of a container.
    Various other characteristics will emerge from the description given below with reference to the appended drawings which show, by way of nonlimiting examples, embodiments of the object of the invention.
    Figure 1 is a schematic top view showing an installation for measuring X-rays, dimensions on containers running in line.
    Figure 2 is a schematic side perspective view showing an installation for measuring X-rays, dimensions on a container.
    Figure 3 is a schematic sectional view showing part of an inspected container.
    Figure 4 is a schematic perspective view showing the volume traversed or generated by the containers during their linear movement.
    Figure 5 is a schematic top view showing an embodiment of an installation according to the invention comprising three x-ray generating foci.
    FIG. 6 is a schematic view in transverse elevation of the installation illustrated in FIG. 5.
    FIG. 7 is a schematic side elevation view of the installation illustrated in FIG. 5.
    Figures 8 and 9 are schematic views explaining the definition of the useful angle between two directions of projection.
    Figures 10 and 11 are schematic perspective views showing the positioning of image sensors with respect to the movement of the containers to be inspected.
    Figure 12 is a view of an exemplary embodiment of an installation according to the invention using raster image sensors.
    Figure 13 is a view of a matrix of X-ray sensitive elements in which two distinct zones appear corresponding to two raster image sensors.
    As a preliminary, some definitions of the terms used in the context of the invention are given below.
    A focal point Fj of an X-ray generating tube is a point source of X-rays, preferably a "micro focal point", for example between 0.01 mm and 1 mm in diameter, creating a divergent beam of X-rays. '' use any type of point or quasi-point x-ray source.
    A sensitive element is an X-ray sensitive element, in other words an elementary surface, of dimension for example 0.2 x 0.2 mm or 0.02 x 0.02 mm, converting the X-rays which it receives into a signal electric. Generally, a scintillator converts X-rays into visible light and then a photoelectric sensor converts visible light into an electrical signal. Techniques for direct conversion of X-rays to an electrical signal also exist. A pixel designates an elementary value of a point of a sampled image, characterized by its gray level between 0 and a maximum value. For example for a 12-bit digital image, a pixel takes digital values between 0 and 4095.
    A system for reading or acquiring radiographic images comprises one or more X-ray sensitive surfaces, that is to say surfaces comprising sensitive elements converting X-rays into an electrical signal to be transmitted to a system of X-rays. analysis conventionally implemented by a computer and designated by computer system in the following description. The signals from a set of sensitive elements belonging to the same sensitive surface area, acquired by the acquisition device and transmitted together to the computer system, constitute a radiographic image. To be analyzed by the computer system, the radiographic images are preferably converted into digital radiographic images either as close to the sensitive surface or remotely as close as possible to the computer system.
    The X-ray beams from a focal point Fj pass through at least one inspected region, and form on a sensitive surface, the radiographic projection of the inspected region, which is sometimes called the radiant image and which contains the information of attenuation of X-rays by the material passed through.
    An image sensor called Cji is an X-ray sensitive surface area which receives the radiographic projection of the region inspected. An image sensor Cji is exposed to X-rays from an associated focal point Fj. The image sensor converts this radiographic projection into a radiographic image of the region inspected. When the sensitive surface area contains a line of photosensitive elements, the transmitted radiographic image is linear, composed of a line of pixels forming a one-dimensional array of values. When the sensitive surface area contains a matrix of photosensitive elements, the radiographic image transmitted is matrix, composed of a matrix of pixels forming a table of two-dimensional values.
    The projection direction üji is the oriented direction or the vector leaving the focus Fj to pass through the center of the image sensor Cji, that is to say through the center of an X-ray sensitive area which receives the radiographic projection of the region inspected at the time of acquisition during the movement of the container between the focus and the image sensor. For an image sensor-associated household couple, the projection direction is the vector coming from the focal point reaching the middle of the image sensor. The positioning of the image sensors is such that the sensitive surface is not parallel to the projection direction. It may be advantageous in certain cases for the sensitive surface of the image sensor to be orthogonal to the direction of projection defined with the associated focal point. But this is not compulsory, for example if a sensitive surface contains several sensitive zones which cooperate for each image capture, with several different foci, therefore according to different directions of projection.
    The directions of projection Dji of radiographic projections are different if the directions of projection Dji taken two by two make between them a minimum angle at least equal to 5 °.
    A sensitive surface area containing a single line of sensitive elements constitutes a linear image sensor, which comprises a linear network of sensitive elements, distributed along a line segment of support. According to this definition, a column or a row belonging to a sensitive matrix surface, acquired and transmitted separately by the acquisition device is considered to be a linear image sensor. Several sensitive surface areas of the same surface and each containing a single line of different pixels therefore constitute several linear image sensors. The direction of projection associated with the linear radiographic image obtained is therefore the direction starting from the focal point and passing through the middle of the straight line of support at the time of acquisition of the image.
    A sensitive surface area which contains a matrix of sensitive elements constitutes a matrix image sensor, which comprises a matrix network of elements sensitive to X-rays, distributed in a matrix. As illustrated in Fig. 12, according to this definition, a matrix sensitive surface area C11, C12, which belongs to a larger sensitive surface Ss, and which is acquired and transmitted separately by the acquisition device is a matrix image sensor. Several zones of sensitive matrix surface C11, C12 of the same surface, acquired and transmitted separately by the acquisition device therefore constitute several sensors of matrix images providing different radiographic images respectively Mil, M12 (FIG. 13). The direction DU, of projection D12 associated with the matrix radiographic image respectively Mil, M12 is the direction starting from the focal point Fl and passing through the middle of the area Cil, C12 of matrix sensitive surface, at the time of acquisition of the image. It is therefore possible that the image sensors C11, C12 are non-disjoint regions activated successively over time.
    Of course, a person skilled in the art can use a matrix sensor technology based on an image intensifier or else a "screen capture camera" in which a scintillator plate receives the radiant image, converts it into visible light, the image visible at the rear of the scintillator being photographed by a visible camera equipped if necessary with a lens.
    As is apparent from the Figures, the object of the invention relates to an installation 1 allowing the implementation of a method for carrying out dimension measurements on empty glass containers 2. Conventionally, a container 2 is a hollow object comprising a bottom 3 connected to a heel or rim from which rises a body 4 extended by a shoulder connected to a neck or neck 5 terminated by a ring 6 delimiting the mouth allowing the container to be filled or emptied . Thus, as illustrated in FIG. 3, a container 2 has a glass wall 7 delimited internally by an internal surface 8 and externally by an external surface 9. The wall 7 has a thickness e between the internal surface 8 and the external surface 9. The neck 5 has an internal diameter D defined by the internal surface of the wall.
    According to an advantageous characteristic of embodiment, at least one region of the container is chosen to be inspected so as to be able to carry out dimension measurements in this region of the container, corresponding to a dimensional characteristic of the region to be inspected. Typically, the region to be inspected can comprise at least the neck 5 of the container and the measurement of a dimensional characteristic of this region to be inspected corresponds at least to the internal diameter D of the neck. Likewise, the region to be inspected can comprise at least a portion of the wall of the body 4 between the jable and the shoulder and delimited for example by two planes parallel to the plane of laying of the container, and the measurement of a dimensional characteristic. of this region to be inspected corresponds to the thickness e of the glass wall comprised between the internal 8 and external 9 surfaces delimiting this wall 7. The invention is therefore very particularly suitable for measuring dimensions in relation to the internal surface of the wall at the level of the neck and / or of the body of the container. Thus, the method according to the invention makes it possible to measure at least either an internal diameter of the neck or a thickness of the glass wall or an internal diameter of the neck and a thickness of the glass wall
    Likewise, the region to be inspected may correspond to a part of the wall 7 comprising the body, the rim or the bottom of the container. The region to be inspected can also correspond to the entire container 2. The dimensions measured are thicknesses of glass wall to the body, to the bottom, to the rim, heights, internal or external diameters, widths for example for nets on the bottleneck. These measurements also make it possible to deduce a dimensional characteristic of the region to be inspected, for example the ovalization of the container or a container with a tilted neck.
    The method according to the invention is implemented for glass containers 2, that is to say for series of manufactured objects composed of a single material, namely glass. It is considered that the attenuation coefficient μ of the glass is unique, that is to say having the same value at any point in a region to be inspected for containers and preferably constant over time and identical for the containers of series. These conditions are met because the composition of the glass is stable in ovens producing several hundred tonnes of glass per day. It should be noted that the attenuation coefficient μ of the glass is strictly a spectral property μ (λ) according to the wavelength λ or the energy of the X-rays. This characteristic is not necessarily taken into account in the method according to the invention insofar as the X-ray source having its own emitted spectral composition, it is possible to consider that the attenuation μ is a characteristic of the glass for the spectrum of the chosen source. Those skilled in the art will also know how to carry out the invention using any method of taking into account the spectral attenuation of the beams. It will also be able to adapt the spectrum emitted, for example by hardening it.
    Consequently, the attenuation of air can be considered negligible compared to that of glass. The attenuation of an X-ray beam passing through the container will depend only on the one hand, on said constant attenuation for the X-ray spectrum emitted, and on the other hand, on the cumulative thickness of glass passed through. Alternatively, it is considered that the thickness of the air passed through is large and uniform for all the beams, it can therefore be considered as known. The attenuation due to air can be subtracted from the total attenuation measured. Thus the gray level in each radiographic image, possibly corrected, depends only and directly on the total cumulative glass thickness crossed. It is then possible to precisely determine the boundary surfaces which are the transitions between air and glass.
    Thus, the computer system takes into account the attenuation coefficient of the glass of the containers being inspected for this calculation operation. Advantageously, the installation 1 comprises a device for making available to the computer system, the attenuation coefficient of the glass of the containers, for example known by analyzes of the glass in the oven. This provisioning device can be produced by a mass memory, a man-machine interface or by a wired or wireless computer network.
    The installation 1 also includes a device 11 for transporting the containers 2 in a conveying plane Pc, along a flat trajectory, with a direction materialized by a displacement vector T. Preferably, the trajectory is substantially straight. Conventionally, the transport device 11 is a conveyor belt or chain conveyor ensuring a linear translation of the containers in the upright position, that is to say with the bottom 3 of the containers bearing on the conveyor to establish themselves in the plane conveyor Pc.
    The installation according to the invention allows the implementation of a method for automatically carrying out measurements of linear dimensions on containers 2 moving in scrolling at high speed. The invention relates to a so-called "online" control of a series of containers, after a transformation or manufacturing step, in order to control the quality of the containers or of the transformation or manufacturing process.
    The method works for a rate of movement of a flow of containers 2. Ideally, the installation 1 is capable of processing production at the production rate, for example of 600 containers per minute.
    However, the calculation time may exceed the interval between two containers. Similarly, the exposure times of the image sensors and of reading can be too long. If the fastest flow cannot be treated by a single installation in accordance with the invention, then several installations can be implemented in parallel, each controlling part of the production. Thus it is possible to divide the production flow into two or three parallel flows inspected by two or three installations according to the invention. Obviously, the economic interest of the invention is reached if the number of flows and therefore of installations according to the invention remains low.
    The invention brings a considerable improvement thanks to the measurement of the internal surface and the thickness of the walls, without contact and in movement of the containers, the complex operations of rotating articles as implemented in carousels are eliminated. . This also allows thickness mapping over the entire periphery and over the entire height of the region inspected. For the control of the neck, the invention allows measurements in the neck, for all the containers of the production, while the prior art only performs a binary conformity test by template or measurements on a few samples taken. These measurements therefore allow observation of the drifts of the manufacturing process.
    As can be seen more clearly from FIGS. 1 and 2, the direction of movement of the containers 2 is established along a horizontal axis X of a reference X, Y, Z comprising a vertical axis Z perpendicular to the horizontal axis X and a transverse axis Y perpendicular to the vertical axis Z and to the horizontal axis X, and X and Y being in a plane parallel to the conveying plane Pc which is substantially horizontal.
    As shown more precisely in FIG. 4, during their translational movement, the containers 2 generate or pass through a so-called conveying volume Vt. The plane Ps is the secant plane of the conveying volume Vt, orthogonal to the conveying plane Pc and parallel to the direction of movement T. For example, a median plane separates the volume into two equal sub-volumes. The plane Ps is a vertical plane insofar as the conveying plane is generally horizontal.
    The installation 1 also includes, as illustrated in FIGS. 1 and 2, at least one focal point Fj (with j varying from 1 to k) of a tube 12 generating X-rays creating a divergent beam of X-rays directed to pass through the volume of conveying Vt and more precisely crossing at least the region to be inspected from the container 2. It should be noted that the container 2 is made of glass so that the region to be inspected from the container is made of a material whose absorption coefficient in transmission is homogeneous for a given X-ray.
    Installation 1 also includes at least three image sensors Cji (with i varying from 1 to N, N greater than or equal to 3) sensitive to X-rays and located so as to be exposed to X-rays from a focus Fj associated and having passed through the conveying volume Vt and more precisely, at least the region to be inspected from the container 2. Of course, the tube 12 and the image sensors Cji are located outside the conveying volume Vt to allow free movement containers in this volume. Conventionally, the X-ray generating tubes 12 and the Cji image sensors are placed in an X-ray tight enclosure.
    The X-ray beams coming from a focal point Fj associated with said image sensor Cji, pass through at least the inspected region, and form on the image sensor, the radiographic projection of the inspected region, in a projection direction Dji ( Fig. 1 and 2). The projection direction Dji is the oriented direction of the vector leaving the focus Fj to pass through the center Mji of the image sensor Cji. The focal point (s) Fj and the image sensors Cji are arranged so that each image sensor receives a radiographic projection of the region to be inspected in a projection direction of the region to be inspected.
    The installation 1 also includes an acquisition system connected to the image sensors Cjî, so as to acquire for each container 2 during its movement, at least three radiographic projections of the region to be inspected having different directions. It is recalled that the projection direction associated with the radiographic image obtained is the direction starting from the focal point and passing through the middle of the area of the sensitive surface of the image sensor, at the time of image acquisition. Thus, the at least three radiographic projections have projection directions which are two by two, an angle between them.
    The acquisition system is connected to a computer system not shown but of all types known per se. According to an advantageous characteristic of embodiment, the computer system records, using image sensors Cjî, for each container during its movement, radiographic images obtained from a determined number of radiographic projections of the region to be inspected according to different projection directions. Typically, the number of different projection directions Dji is between three and forty, and preferably between four and fifteen. According to the preferred alternative embodiment, the installation 1 comprises between three and forty image sensors Cjî and preferably between four and fifteen image sensors Cji.
    As will be explained in detail in the following description, the computer system is programmed to analyze the at least three radiographic images from the at least three radiographic projections of different directions so as to determine a digital geometric model of the region to be inspected containing the three-dimensional coordinates of a set of points belonging to the wall of the container in the region inspected. More specifically, the digital geometric model contains the three-dimensional coordinates of a set of points belonging at least to the internal surface of the wall of the container and preferably to the internal surface and to the external surface of the wall of the container. The determination of the three-dimensional coordinates of these points makes it possible to carry out dimensional measurements of the container for the region inspected, namely at least one internal diameter of the neck or at least one thickness of the glass wall of the body 4 of the container or at least one diameter internal neck and a thickness of the glass wall of the container body.
    The determination of the three-dimensional coordinates of these points and the carrying out of the dimensional measurements can be carried out in any suitable manner by the known techniques of analysis of three-dimensional geometric data.
    In general, the digital geometric model of the region to be inspected containing the three-dimensional coordinates of a set of points belonging to the internal and external surfaces of the wall of the container in the region inspected consists of:
    - At least two three-dimensional points of space each belonging to an internal and / or external surface of the wall of the container and located in a plane not orthogonal to a direction of projection Dji and not parallel to the direction T of displacement;
    - And / or at least one surface representation of the internal and external surfaces of the wall of the container different from a plane orthogonal to a direction of projection Dji, and different from a plane parallel to the direction T of displacement;
    - And / or at least one section of the region to be inspected, along a plane different from a plane orthogonal to a direction of projection Dji and different from a plane parallel to the direction T of displacement.
    The dimensional measurements are then carried out according to one of the methods described in the following description.
    A preferred embodiment consists in determining a digital geometric model representing the internal surface and the external surface of the container in the region to be inspected.
    According to this example, the digital analysis of the radiographic images makes it possible to construct a three-dimensional digital geometric model of the container. Optionally, this digital geometric model can simply be a stack of two-dimensional digital geometric models. The realization of a digital geometric model is the way - in mathematical, graphic and data structure terms of which three-dimensional containers are represented and manipulated in digital form in a memory of a computer system.
    The modeling can be voluminal. The mono-material container can therefore be represented by voxels whose value represents an amount of material. The voxel can be full, partially full or empty of material (in this case it is air). The volume geometric model can be analyzed to locate the boundaries of the container and then to measure linear dimensions such as lengths or thicknesses. It can also be transformed into a surface model, that is to say in which border surfaces of the container are modeled.
    It is possible to obtain a surface model directly from radiographic images, that is to say without going through the calculation of a volume model.
    In surface models, a container is defined by at least one three-dimensional surface. A three-dimensional surface corresponds to the border between the material of the container and the external environment (generally air), which makes it possible to grasp the concepts of interior and exterior of the container. Generally three-dimensional surfaces are modeled in several ways such as by polygonal modeling, by curves or parametric surfaces (cylinders, cones, spheres, splines, ...) or by subdivision of surfaces. Using a mesh of polyhedra, for example triangles, the three-dimensional surfaces of the containers are represented by sets of plane facets connected by their edges.
    A section of a three-dimensional container is its intersection with a plane. The section of three-dimensional surfaces are two-dimensional curves in the section plane. Knowledge of these two-dimensional curves in a succession of section planes allows the reconstruction of three-dimensional surfaces.
    In order to make length measurements, there are several approaches.
    In a first volume method, it is possible to run through a volume model along a straight line or a bundle of straight lines and determine the matter / air boundary voxels.
    In a second surface method, it is possible to calculate a segment whose ends are the intersections of a straight line with the matter / air boundary surface of a surface model. The algorithms solve the topological problems fairly well. The points of intersection are unique. Finally, a mixed method consists of transforming the volume model into a surface model, then applying the second method.
    A third method consists in determining in a section plane, the distance between two points of one or two two-dimensional curves, any curve being a border between matter and air.
    A three-dimensional point is a point whose coordinates are known in three-dimensional space, in any coordinate system.
    These three previous methods are examples of determining a distance between two three-dimensional points, to determine a measure of linear dimension.
    The objective of the invention is to carry out more complete measurements than those made possible by simple two-dimensional radiographic images. Indeed, it is easy using a matrix image sensor to obtain a two-dimensional radiographic image corresponding to a projection of the region inspected and to measure dimensions in a plane orthogonal to the direction of projection known as “plane projected ”. Similarly, it is easy to use a linear image sensor to obtain a two-dimensional radiographic image corresponding to a fan projection (parallel planes) of the inspected region obtained by juxtaposition of the successive image lines acquired during moving in the moving direction T, and measuring dimensions in a projected plane, which is parallel to the moving direction. On the other hand, according to the invention, linear dimensions can be measured in directions which are neither contained in the projected planes, nor parallel to the projected planes. The method according to the invention in fact consists in reconstructing and measuring dimensions in practically all directions when processing a combination of radiographic images in at least three different directions of projection. This is possible by any method allowing the determination of three-dimensional points in the space belonging to a boundary surface included in the region to be inspected from the container. The reconstruction of a three-dimensional model of the area to be inspected, of surface or volume type or based on sectional plans, is a possible method. In fact, according to the invention, it is possible either indirectly from a surface or volume model or from section planes, or directly, to determine at least two three-dimensional points, or even preferably three-dimensional point clouds, distributed in directions not measurable only in two-dimensional radiographic images.
    The glass container being made of a single material, therefore with a constant attenuation coefficient or considered as such, it is advantageous to determine its digital geometric model in the form of surfaces. It is possible to determine and represent in the digital geometric model for example, the internal surface of the neck of the container. According to this example, the inspected region contains the neck 3 and therefore extends between the ring surface plane 6 and a plane which is parallel to it. We can then measure the internal diameter of the neck. More precisely, several internal diameters of the neck can be measured. By choosing a given height for example by choosing a cutting plane parallel to the surface of the ring or to the bottom of the container, it is possible to measure several diameters from 0 to 360 ° in this plane. Thus, it is possible to determine the diameter at the opening Do (or mouthpiece), for example at 3 mm under the mouthpiece by positioning a cutting plane 3mm under the ring surface. It is also possible to determine a minimum diameter over the entire height h of the internal surface of the neck to replace the measurement by pinout.
    It is also possible to choose as region to be inspected, for example the body 4 of the container extending between the rim and the shoulder. Thus the region to be inspected can be delimited by two planes parallel to the bottom 3 or to the plane of laying of the container, one positioned above the rim the other under the shoulder. The digital geometric model of the internal and external surfaces of the region inspected is then determined, which makes it possible to measure the thickness of glass comprised between these surfaces at multiple points, thus providing a measure of the distribution of the glass.
    According to an alternative embodiment, the region to be inspected corresponds to at least part of the neck 5 of the container so that the radiographic images are analyzed to construct a digital geometric model of at least the internal surface of the neck so that the internal diameter neck D can be measured and correspond to the measurement of a dimensional characteristic of the region to be inspected.
    According to another alternative embodiment, the region to be inspected corresponds to at least part of the body 4 of the container so that the radiographic images are analyzed so as to construct a digital geometric model of the internal surface and of the external surface of the container in the wall part inspected, and from the internal and external surfaces of the digital geometric model, in obtaining the measurement of the thickness e of the glass wall of the body of the container included between said surfaces.
    According to a preferred embodiment, the region to be inspected comprises at least part of the neck and part of the wall of the body of the container so that the radiographic images are analyzed so as to construct a digital geometric model of the internal surface and of the external surface of the container, and from the internal and external surfaces of the digital geometric model, to obtain the measurements of an internal diameter of the neck and of the thickness of the glass wall of the body of the container.
    It emerges from the foregoing description that the invention makes it possible to construct a digital geometric model corresponding at least to the region to be inspected comprising at least part of the neck and / or part of the body of the container. As indicated above, the digital geometric model is constructed using the attenuation coefficient of the glass constituting the containers 2.
    According to an advantageous variant embodiment, the digital geometric model is also constructed by using an a priori geometric model of the region inspected making it possible to speed up and make reliable the reconstruction calculations of the digital geometric model of each container.
    Thus, the a priori geometric model is a digital geometric model of the series of containers, serving as initialization for reconstruction software in order to build the digital geometric model of each container inspected. Its role is mainly to provide the computer system with information on the shape, geometry and dimensions of the object to be modeled by calculation.
    Thanks to this a priori information, it becomes possible:
    - not to model, from radiographic images, the attenuation in regions of the image space empty of material a priori because the attenuation is considered as zero there;
    and or
    - to model from radiographic images only the surfaces on which the measurements of dimensions are to be made, possibly directly without going through the determination of voxels;
    and or
    - to determine only the differences between the surfaces modeled from radiographic images and theoretical ideal surfaces.
    Knowledge of the a priori geometric model of glass containers also makes it possible not to determine from radiographic images, attenuation values in regions of space containing material according to the a priori model because it is known as that glass used.
    Thus the a priori geometric model is a digital model of the series of containers, serving as initialization for the reconstruction software.
    The computer system therefore has an a priori geometric model of the region to be inspected to perform this calculation operation. Thus, the installation 1 comprises a device for making available to the computer system, an a priori geometric model of the region to be inspected for the containers or series of containers.
    The device for providing the computer system with an a priori geometric model of the region to be inspected is a mass memory, a wired or wireless computer network or a man-machine interface.
    According to a first variant of the invention, the a priori geometric model is obtained by the digital model of computer design of the containers, produced during their design (3D CAD). In this case, it is made available to the computer system by various possible means, such as a connection through a computer network, to a database containing several CAD models corresponding to the various models of containers capable of being measured in production. , a selection by the operator in a database internal to the installation, etc ...
    According to a second variant of the invention, the a priori geometric model is obtained from a geometric digital model constructed from the measurement of one or more containers of the same series (therefore of the same commercial model) by a measurement, for example by a probe measuring machine or an axial tomography device. The a priori geometric model can be constructed by merging the measurements of several containers made from the same series.
    According to a third variant of the invention, the a priori geometric model is a geometric digital model generated by the computer system from entered values and / or from drawings and / or shapes selected by an operator on the human interface. system machine.
    For example, to provide the a priori geometric model in the case of a check of the internal dimensions of the neck, the region inspected contains at least the neck, therefore the region of the container between the top of the ring and the shoulder of the container. . The a priori geometric model of the neck can be a simple hollow truncated cone of which the height, the two top and bottom diameters, and the wall thickness are known. It can also be a complete geometric model, for example of a wine type ring, with its external reliefs, against ring, and rounded included. According to another example, the computer system can by its interfaces receive technical descriptions of the a priori model, comprising for example a type of standardized screw ring described either by a saved 3D model, or by parameters of lengths, depths and no net etc ....
    Similarly to provide the a priori geometric model in the case of a control of the distribution of glass at the level of the body of the container, the region inspected extends at least over an inspection height situated between the rim (or heel) and the shoulder. The a priori geometric model of the body can be a simple portion of a perfect hollow cylinder, of which only the outside diameter, the height and the average thickness are given. The a priori means of making the digital model available can therefore be limited to entering or digitally transmitting the values of outside diameter, height and thickness. Of course these methods are easily generalized for containers of any shape, for example of polygonal section.
    It should be understood that the a priori geometric model must at least contain sufficient technical, geometric, topological and / or numerical information, to inform the computer system about the general three-dimensional structure of the series of containers, the degree of detail and precision this information can be very low without penalizing the precision sought for linear measurements.
    It is possible to configure the control by making virtual gauge positions available to the computer system. In this case, the device according to the invention obviously includes means for making the measurement tolerance intervals available.
    Another way to determine dimensions and their conformity is to compare the digital geometric model of the region inspected with a reference or theoretical geometric model.
    The geometric reference model is an ideal model from the series of containers inspected. To carry out a dimensional check, the digital geometric model of the region inspected can be compared with the reference geometric model, using an algorithm comprising the matching of the models, then the measurement of the differences between the models. The geometric reference model can be derived from CAD at least for the external surface of the containers.
    It is thus possible to carry out an operation of matching the digital geometric model of the region inspected with the reference geometric model, then to determine dimensional deviations by measuring distances between surface elements belonging to the reference model and surface elements belonging to the digital geometric model. For example, it is possible to measure according to the invention what the glassmakers call the "diameter at opening", which is specified by a tolerance of minimum and maximum diameter, for example a tolerance interval of 18 mm +/- 0.5, over a given depth from the ring surface, for example 3 mm. According to the invention, it is possible to position virtually, a first cylindrical surface of height 3mm, of maximum diameter inscribing in the internal modeled surface of the neck, and similarly a second cylindrical surface of height 3mm, of minimum diameter containing the modeled internal surface, and to consider as measurements of the diameter at the opening of the container the diameters of the cylindrical surfaces inscribed and exinscribed, which are respectively compared with the tolerances.
    According to a variant of the invention, the reference geometric model and the a priori geometric model are the same geometric model.
    According to another variant of the invention, the a priori geometric model is less precise, less complete and / or differ from the reference geometric model.
    It appears from the above description that the computer system determines for each container, at least an internal diameter of the neck and / or a thickness of the glass wall of the container body. In general, the invention makes it possible to carry out a series of dimension measurements on the containers 2. The dimensional control consists in measuring actual dimensions and in comparing them with the required dimensions. A priori, any container in a series is close to the ideal reference container having the required dimensions but deviates from it by dimensional variations. The aim is generally to compare the measurements obtained on the containers with the required values, for example defined by a quality department. These dimension measurements or the deviations of these measurements from the required values can be displayed, saved, etc. They can also be used to make conformity decisions on containers which can be sorted automatically. According to an advantageous characteristic of embodiment, the computer system is connected to a device for displaying the values of linear measurements of the region to be inspected and / or dimensional deviations from reference values. For example, the installation according to the invention may include a screen for viewing radiographic images of the region inspected and the dimensions measured.
    According to an advantageous characteristic of embodiment, the computer system is connected to a device for sorting the containers according to the linear measurement of the region to be inspected. Thus, this sorting device can eject from the transport device, the containers considered to be defective in consideration of the linear dimensions measured.
    Of course, the relative positions of the focal points Fj and of the image sensors Cji are diverse, it being recalled that the focal points Fj and the image sensors Cji are positioned outside the conveying volume Vt.
    According to an alternative embodiment, the installation 1 comprises a single focus (Fj = Fl) arranged along one side of the conveying volume Vt and a series of image sensors (Cji = Cli = Cil, C12, C13, ... ) arranged along the opposite side of the conveying volume Vt to receive the rays coming from the focal point Fl and having passed through the region to be inspected. In this example, the focal point has an opening Of which is measured in at least any plane, such as for example the plane X, Y in FIG. 1, which is greater than or equal to 120 °. This opening Of is considered at the outlet of the focus, in the case where the installation comprises between the focus and the volume Vt, or between the volume Vt and the image sensors, screens for limiting beams to only useful beams, in the goal of reducing broadcast.
    According to another alternative embodiment, at least two focal points Fj (F1 and F2) for producing X-rays, are positioned separately in two distinct positions and at least three image sensors Cji, sensitive to X-rays, are placed so that each focus is associated with at least one Cji image sensor, and each Cji image sensor is associated with a focus and receives X-rays from said focus and passing through the region to be inspected. In this example, each hearth has an opening greater than or equal to 60 ° so that the sum of the openings of the two hearths is greater than or equal to 120 °.
    In the exemplary embodiment illustrated in FIGS. 5 to 7, the installation 1 comprises three homes F1, F2, F3 each associated with a separate generator tube 12. Installation 1 also includes five image sensors C11, C12, C13, C14 and C15 each sensitive to X-rays from the first associated focal point F1, five image sensors C21, C22, C23, C24 and C25 each sensitive to rays X from the second associated focus F2 and three image sensors C31, C32, C33 each sensitive to X-rays from the third associated focus F3.
    According to this exemplary embodiment, the installation comprises at least one focal point (and in the example, two focal points F1 and F2) from each of which a divergent X-ray beam comes. At least one focal point (and in the example, two focal points F1 and F2) are positioned on one side of the intersecting plane Ps so that each of the beams crosses the intersecting plane Ps and the region to be inspected, while at least one image sensor Cji associated with said focal point Fj for receiving the X-rays coming from said focal point Fj is arranged on the opposite side with respect to the secant plane Ps. (In the example, these are the five image sensors Cil, C12, C13, C14 and C15 each sensitive to X-rays from the associated focus F1 and the five image sensors C21, C22, C23, C24 and C25 each sensitive to X-rays from the associated focus F2). Of course, it can be provided to have a focus on one side of the intersecting plane Ps and another focus on the other side of the intersecting plane Ps so that the associated image sensors are also arranged on either side of the secant plane Ps.
    According to an advantageous alternative embodiment which is illustrated in FIGS. 5 to 7, a focal point Fj from which a divergent X-ray beam comes from is disposed on one side of the conveying plane Pc so that its beam crosses the conveying plane Pc, while at least one image sensor Cji is associated with said focus Fj to receive the X-rays from said focus is positioned on the opposite side with respect to the conveying plane Pc. In the example illustrated, a focal point F3 is arranged above the conveying plane Pc while three image sensors C31, C32, C33 are positioned below the conveying plane Pc. Of course, the position between the focal point and the image sensors can be reversed with respect to the conveying plane.
    According to an advantageous alternative embodiment, at least one of the foci Fj is arranged in the conveying plane Pc. Preferably, these homes cooperate with associated image sensors situated at their opposite with respect to the intersecting plane Ps, and thus in the case of a transport of the containers arranged on a plane conveyor, this arrangement allows that in the radiographic images, the projections of the containers are not superimposed on the projection of the conveyor. Thus, in the digital geometric model of the containers, the part of the container in contact with the conveyor can be precisely determined.
    According to an advantageous characteristic of embodiment, the arrangement of the image sensors Cji and of the focal points is such that the X-rays coming from the focal point or focal points Fj and reaching the image sensors Cji pass through only one region to be inspected at a time. In other words, X-rays only pass through one container at a time. It should be noted that the installation may include a system for controlling the spacing between the successive scrolling containers, such as for example screws or belts in lateral contact with the containers.
    An object of the invention is to obtain a process which is not only rapid, but also inexpensive, capable of calculating with the precision necessary for dimensional control. The invention aims to reduce the number of images necessary for reconstruction to the minimum number making it possible to achieve the desired dimensional precision. For example, the invention makes it possible, with nine projections and a limited number of images of the region inspected, to measure the internal diameter of a cylinder at +/- 0.05 mm. Advantageously, the installation according to the invention comprises between one and four foci Fj and preferably one or two foci Fj and preferably between four and fifteen image sensors Cji.
    According to the invention, it is necessary to arrange the image sensors and the focal point or focal points so that the combination of at least three directions of projections optimizes the determination of the digital geometric model of the region inspected, by considering that the volume traversed Vt free for the circulation of the containers. The following rules are advantageously implemented in the context of the invention, these rules being valid for linear or matrix image sensors.
    In what follows, an angle is an absolute value. Figs. 8 and 9 illustrate two directions of projection Dji and D'ji which are also vectors. These Figures show the angle r between these two directions of projection either r - and s the angle complementary to the angle r, or s = 180 ° -r. By definition, the useful angle a between two different projection directions Dji and D'ji, is the smallest of the angles r and s, ie a = Min (r, s). Thus, the useful angle a is the smallest of the angles formed by the two lines carrying the directions of projection Dij, D'ji and brought back to any point of the region inspected.
    According to an advantageous variant of the invention, at least two images obtained from two radiographic projections in two different directions Dji and D'ji are acquired for each container making between them a useful angle a greater than or equal to 45 ° and less than or equal at 90 °. According to an advantageous alternative embodiment, at least two images are acquired for each container from two radiographic projections in two different directions making between them a useful angle a greater than or equal to 60 ° and less than or equal to 90 °.
    To do this, the installation 1 according to the invention comprises at least one focal point and two image sensors arranged so that the directions of projection of the inspected region which they receive have between them a useful angle a greater than or equal to 45 ° and less than or equal to 90 ° and, advantageously greater than or equal to 60 ° and less than or equal to 90 °.
    For example, as illustrated in FIG. 5, the useful angle a between the directions D15 and DU, and between the directions D13 and D25 are greater than 45 °. Obviously it should be understood that at least one useful angle is greater than or equal to 45 ° and less than or equal to 90 ° and advantageously that at least one useful angle is greater than or equal to 60 ° and less than or equal to 90 ° and the other useful angles between two directions Dji are arbitrary. A person skilled in the art will use this rule to find a provision which offers the most complete possible distribution of the directions of projections of the region inspected.
    According to another advantageous characteristic, for each container, the computer system acquires at least one radiographic image of the inspected region corresponding to a direction of projection making an opening angle β determined with the direction of movement T.
    As illustrated in Figs. 10 and 11, the angle p between a direction of projection (vector Dji) and the trajectory of the containers (vector T) is considered, ie the angle p = (Dji, T), that is to say p - (DU, T) and p = (D12, T) in the example illustrated in Fig. 10 and p = (D22, T) and p - (DU, T) in the example illustrated in FIG. 11. The angle q complementary to the angle p is such that q = 180 ° -p. By definition, the opening angle β between a direction of projection Dji and the trajectory T is the smallest of the angles p and q, namely β = Min (p, q). Thus, the opening angle β is the smallest of the angles formed by the two lines, one carrying the direction of projection Dji and the other the trajectory T, brought to any point in the region inspected.
    According to another advantageous characteristic, for each container, the computer system acquires at least one radiographic image of the region inspected corresponding to a projection direction Dji having, with the direction of movement T, an opening angle β of between 10 ° and 60 °. In other words, the installation according to the invention comprises at least one focal point and an image sensor Cji arranged so that, when a container crosses the field of image sensors, the projection direction Dji of the region inspected on the image sensor Cji makes an opening angle β with the direction of movement T between 10 ° and 60 °.
    For example, as illustrated in FIG. 10, an installation according to the invention comprises at least one focal point F1 and two image sensors C11, C12 whose projection directions DU, D12 define with the direction of movement T, an opening angle β of between 10 ° and 60 ° corresponding respectively to the angles p and q. In the example illustrated in FIG. 11, the installation comprises at least one image sensor C11, associated with a focal point F1 and an image sensor C22 associated with a focal point F2. The projection directions DU, D22 define the opening angle β between 10 ° and 60 ° and corresponding to the angles p. Likewise, the installation illustrated in FIG. 5, comprises an image sensor Cil associated with the focal point Fl and the projection direction DU of which makes an angle β of between 10 ° and 60 °, relative to the direction of movement T.
    Cji image sensors are of the matrix or linear type.
    According to a preferred variant embodiment, the installation 1 comprises linear image sensors. According to this preferred variant, each image sensor Cji comprises a linear network of elements sensitive to X-rays, distributed along a straight line of support Lji defining with the associated focal point Fj, a projection plane Pji containing the projection direction Dji (Fig. 2). These image sensors Cji are arranged so that at least m sensitive elements of each of these image sensors receive the radiographic projection of the region to be inspected by the X-ray beam from the associated focal point Fj, with the planes of projection Pji for the various image sensors which are distinct from each other and not parallel to the conveying plane Pc. The number m of sensitive elements of each linear image sensor is greater than 128, preferably greater than 512. The distance between neighboring sensitive elements (called "pitch" or "pitch" in English) and / or the dimension of the sensitive elements is preferably less than 800 µm. The reading frequency of the image lines is preferably greater than 100 Hz, advantageously greater than 1 kHz. Of course, these parameters are adapted as a function of the size of the containers, the precision sought and the speed of travel.
    According to an advantageous characteristic of embodiment, at least three linear image sensors Cji have their support lines Lji parallel to each other.
    According to another advantageous characteristic of embodiment, at least three linear image sensors Cji have their support lines Lji orthogonal to the conveying plane Pc.
    According to a variant, a focus Fj is positioned so that its beam crosses the region inspected and then the conveying plane Pc. In addition, at least one associated linear image sensor Cji is positioned opposite the focal point Fj with respect to the conveying plane Pc and in such a way that its straight support Lji is parallel to the conveying plane Pc.
    According to these alternative embodiments with linear image sensors, the acquisition system acquires using each of the at least three image sensors Cji, at each incremental movement of each container on the trajectory, radiographic linear images. of the region to be inspected according to a chosen number so that for each container, the entire region to be inspected is represented completely in the set of linear radiographic images. Thus, during the movement of a container, each image sensor is able to acquire linear radiographic images so that the entire region to be inspected of the container is completely represented in the set of linear radiographic images obtained at from said image sensor. Thus, for each container, at least three sets of linear radiographic images of the region to be inspected are obtained, which are then analyzed. Raster radiographic images of the region inspected can be created by juxtaposing sets of linear radiographic images. But the reconstruction of the geometric model and the measurement do not necessarily impose it
    The incremental displacement is the translation carried out by the container between two successive acquisitions of images. For a given scrolling speed of the containers, the incremental movement is limited lower by the reading speed of the image sensors. This parameter, combined with the vertical resolution of the linear image sensors, (or the horizontal and vertical resolutions of the matrix image sensors), conditions the density of measured points of the digital geometric model, therefore ultimately the spatial resolution and the precision the measurement of the dimensional characteristic of the region to be inspected. For example, the incremental movement may be less than 0.5 mm, preferably less than 0.2 mm, which means that the image sensors are read 5 times during a movement of 1 mm from the containers.
    Of course, the number of focal points, the number of image sensors associated with each focal point, and their relative arrangements are chosen in any suitable manner according to the degree of measurement accuracy desired, the shape of the containers and their spacing over the conveyor.
    The invention allows the measurement of dimensions (for dimensional control) on scrolling glass containers at high speed and without contact, by at least three X-ray projections of different directions, and by means of an optimal, rapid and sufficiently accurate calculation, thanks to to the mono-material property and by a priori knowledge of the general shape of the containers.
    It should be noted that in glassware, it is possible that several series of different containers are present at the same time on the same control line. The installation according to the invention can be used to inspect a flow of containers made up of several different series, for example a first series and a second series. In this case, the installation comprises an indication system to the computer system of the series to which each of the containers belongs in order to implement the method of the invention for all the containers of the same series. In other words, the installation is provided with a means for making available to the computer system, an a priori geometric model of each series of container, and the computer system is adapted in order to associate the radiographic images of each container with the series. to which it belongs.
    The invention is not limited to the examples described and shown since various modifications can be made without departing from its scope.
    权利要求:
    Claims (33)
    [1" id="c-fr-0001]
    1 - Method for measuring dimensions of at least one region to be inspected of empty glass containers of a series (2) each having a wall forming a neck and a body and delimited by an internal surface and an external surface, the method consists in :
    - choose at least one region to be inspected comprising at least part of the neck and / or part of the container body;
    transporting the containers placed on their bottom in a conveying plane (Pc) along a flat trajectory with a direction materialized by a displacement vector (T), these receptacles generating a conveying volume (Vt) during their displacement;
    - position, on each side of the region to be inspected, at least one focal point (Fj) of an X-ray tube and image sensors (Cji) sensitive to X-rays and each exposed to X-rays from an associated focal point (Fj), these X-rays having passed through at least the region to be inspected producing on each image sensor a radiographic projection in the projection direction (Dji);
    - acquire using image sensors (Cji) for each container during its movement, at least three radiographic images of the region inspected, obtained from at least three radiographic projections of the region to be inspected, including the directions of projection are different;
    - analyze the at least three radiographic images, using a computer system so as to determine a digital geometric model of the region to be inspected containing the three-dimensional coordinates of a set of points belonging to the region inspected, to deduce from the minus an internal diameter of the neck and / or a thickness of the wall of the body.
    [2" id="c-fr-0002]
    2 - Method according to claim 1, characterized in that the digital geometric model of the region to be inspected containing the three-dimensional coordinates of a set of points consists of:
    - at least two three-dimensional points of the space each belonging to an internal and / or external surface of the wall of the container and located in a plane not orthogonal to a direction of projection (Dji), and not parallel to the direction (T) of displacement ;
    - And / or at least one surface representation of the internal and external surfaces of the wall of the container different from a plane orthogonal to a direction of projection (Dji), and different from a plane parallel to the direction (T) of movement;
    - And / or at least one section of the region to be inspected, according to a plane different from a plane orthogonal to a direction of projection (Dji) and different from a plane parallel to the direction (T) of movement.
    [3" id="c-fr-0003]
    3 - Method according to one of the preceding claims, characterized in that it consists in choosing as region to be inspected, at least one defined area extending between two planes parallel to the conveying plane (Pc).
    [4" id="c-fr-0004]
    4 - Method according to one of the preceding claims, characterized in that it consists in choosing as region to be inspected, an area comprising the neck and a body part of the container and in determining a digital geometric model of the region to be inspected containing the three-dimensional coordinates of a set of points belonging to the internal and external surfaces of the wall of the container in the region inspected, to deduce at least an internal diameter of the neck and a thickness of the glass wall of the body of the container.
    [5" id="c-fr-0005]
    5 - Method according to one of the preceding claims, characterized in that on one side of the trajectory, a focal point from which a beam of diverging X-rays from> 120 ° or from at least two focal points is derived. from divergent X-ray beams whose sum of openings is greater than or equal to 120 °.
    [6" id="c-fr-0006]
    6 - Method according to one of the preceding claims, characterized in that it consists in having at least one hearth in the conveying plane (Pc).
    [7" id="c-fr-0007]
    7 - Method according to one of the preceding claims, characterized in that it consists in:
    - have on one side of a secant plane (Ps) of the conveying volume (Vt), orthogonal to the conveying plane (Pc), a focal point (Fj) from which a beam of divergent X-rays comes, so that its beam crosses the intersecting plane (Ps) and the region to be inspected;
    - have on the opposite side with respect to the secant plane (Ps), at least one image sensor (Cji) associated with said focal point (Fj) to receive the X-rays coming from said focal point (Fj).
    [8" id="c-fr-0008]
    8 - Method according to one of the preceding claims, characterized in that it consists in:
    - have one side of the conveying plane (Pc), a focal point (Fj) from which a beam of divergent X-rays comes, so that its beam crosses the conveying plane (Pc);
    - have on the opposite side with respect to the conveying plane (Pc), at least one image sensor (Cji) associated with said focus (Fj) to receive the X-rays from said focus (Fj).
    [9" id="c-fr-0009]
    9 - Method according to one of the preceding claims, characterized in that it consists in acquiring using image sensors (Cjï), for each container during its movement, at least two radiographic images of the region inspected corresponding to projection directions (Dji) defining a useful angle (a) greater than or equal to 45 ° and less than or equal to 90 ° and, advantageously greater than or equal to 60 ° and less than or equal to 90 °.
    [10" id="c-fr-0010]
    10 - Method according to one of the preceding claims, characterized in that it consists in acquiring, using image sensors (Cji), for each container during its movement, at least one radiographic image of the region inspected corresponding to a projection direction (Dji) having an opening angle (β) with the direction of movement (T) between 10 ° and 60 °.
    [11" id="c-fr-0011]
    11 - Method according to one of the preceding claims, characterized in that it consists in making and acquiring radiographic projections of the inspected region of a container so that the X-rays from the hearth (s) and reaching the image sensors (Cji) do not pass through other containers.
    [12" id="c-fr-0012]
    12 - Method according to one of the preceding claims, characterized in that it consists in acquiring, using image sensors (Cji), for each container during its movement, radiographic images from between three and forty, and preferably between four and fifteen radiographic projections of the region to be inspected from different directions.
    [13" id="c-fr-0013]
    13 - Method according to one of the preceding claims, characterized in that:
    - the image sensors (Cji) are of the linear type each comprising a linear network of elements sensitive to X-rays, distributed along a straight line of support (Lji) defining with the associated focal point (Fj), a projection plane (Pji ) containing the direction of projection (Dji), these image sensors being arranged so that:
    • at least m sensitive elements of each of these image sensors receive the radiographic projection of the region to be inspected by the X-ray beam from the associated focus (Fj);
    • the projection planes (Pji) for the different image sensors are distinct from each other and not parallel to the conveying plane (Pc);
    - using each of the at least three linear image sensors (Cji), on each incremental movement of each container along the path (T), radiographic linear images of the region to be inspected according to a number chosen so as to that for each container, the entire region to be inspected is completely represented in the set of linear radiographic images;
    - We analyze for each container, the at least three sets of linear radiographic images of the region to be inspected.
    [14" id="c-fr-0014]
    14 - Method according to one of the preceding claims, characterized in that it consists in making available to the computer system, an a priori geometric model of the region to be inspected from the series of containers, obtained by:
    - the digital model for computer design of the series containers;
    - or the geometric digital model obtained from the measurement of one or more receptacles of the same series by a measuring device;
    - or the geometric digital model generated by the computer system from entered values and / or from drawings and / or shapes selected by an operator on a man machine interface of the computer system.
    [15" id="c-fr-0015]
    15 - Method according to one of the preceding claims, characterized in that it consists in making available to the computer system the value of the attenuation coefficient of the glass constituting the containers.
    [16" id="c-fr-0016]
    16 - Installation for automatic measurement of linear dimensions of at least one region to be inspected of empty glass containers (2) each having a wall forming a neck and a body and delimited by an internal surface and an external surface, the installation comprising :
    a device (11) for transporting the containers in a direction materialized by a displacement vector (T), along a substantially rectilinear trajectory in a conveying plane (Pc), the containers traversing a conveying volume (Vt) extended in the direction (T);
    - at least one focal point (Fj) of an X-ray generator tube (12) located outside the volume traversed (Vt), and creating a divergent beam of X-rays directed to pass through at least one region to be inspected comprising at least one part of the neck and / or part of the container body;
    - at least three image sensors (Cji), located outside the conveying volume (Vt), so as to receive X-rays from an associated focal point (Fj), the focal point or focal points (Fj) and the sensors of images (Cji) being arranged so that each image sensor receives the radiographic projection of the region to be inspected by rays from the focus (Fj) when the container passes through these rays, the directions of projection of these radiographic projections being different from each other;
    - an acquisition system connected to the image sensors (Cji), so as to acquire for each container during its movement, at least three radiographic images of the region to be inspected, obtained from at least three radiographic projections of the region to be inspected, with different projection directions;
    - And a computer system analyzing the at least three radiographic images, from at least the three different radiographic projections, so as to determine a digital geometric model of the region to be inspected containing the three-dimensional coordinates of a set of points belonging to the wall of the container in the region inspected, to deduce at least an internal diameter of the neck and / or a thickness of the wall of the body.
    [17" id="c-fr-0017]
    17 - Installation according to claim 16, characterized in that it comprises at least two foci (F1, F2) for producing X-rays, positioned separately in two distinct positions and at least three image sensors (Cji), sensitive to X-rays and positioned so that:
    - Each focus emits its beam through at least the region to be inspected to reach at least one associated image sensor (Cji);
    - Each image sensor (Cji) is associated with a focal point and receives the X-rays from said focal point after having crossed the region to be inspected.
    [18" id="c-fr-0018]
    18 - Installation according to one of claims 16 to 17, characterized in that it comprises, at least one focal point from which a beam of divergent X-rays comes from an opening greater than or equal to 120 ° or at least two focal points from which are from divergent X-ray beams whose sum of openings is greater than or equal to 120 °.
    [19" id="c-fr-0019]
    19 - Installation according to one of claims 16 to 18, characterized in that it comprises at least one hearth disposed in the conveying plane (Pc).
    [20" id="c-fr-0020]
    20 - Installation according to one of claims 16 to 19, characterized in that it comprises:
    - on one side of a secant plane (Ps) at the conveying volume and orthogonal to the conveying plane (Pc), a focal point (Fj) from which a beam of divergent X-rays comes, so that its beam crosses the plane secant (Ps) and the region to be inspected;
    - on the opposite side with respect to the secant plane (Ps), at least one image sensor (Cji) associated with said focal point (Fj) to receive the X-rays coming from said focal point (Fj).
    [21" id="c-fr-0021]
    21 - Installation according to one of claims 16 to 20, characterized in that it comprises:
    - on one side of the conveying plane (Pc), a focal point (Fj) from which a divergent X-ray beam comes, so that its beam crosses the conveying plane (Pc);
    - on the opposite side with respect to the conveying plane (Pc), at least one image sensor (Cji) associated with said focal point (Fj) to receive the X-rays coming from said focal point (Fj).
    [22" id="c-fr-0022]
    22 - Installation according to one of claims 16 to 21, characterized in that at least one focal point and two image sensors (Cji) are arranged so that the directions of projection (Dji) of the region inspected that they receive have between them a useful angle (a) greater than or equal to 45 ° and less than or equal to 90 ° and, advantageously greater than or equal to 60 ° and less than or equal to 90 °.
    [23" id="c-fr-0023]
    23 - Installation according to one of claims 16 to 22, characterized in that at least one focus (Fj) and an image sensor (Cji) are arranged so that when a container (2) crosses the field image sensors, the projection direction (Dji) of the region inspected on the image sensor (Cji) makes an opening angle (β) with the direction of movement (T) between 10 ° and 60 ° .
    [24" id="c-fr-0024]
    24 - Installation according to one of claims 16 to 23, characterized in that the image sensors (Cji) and the homes (Fj) are arranged so that the X-rays from the home or homes and reaching the sensors images (Cji) and crossing the region of one container do not cross other containers at the same time.
    [25" id="c-fr-0025]
    25 - Installation according to one of claims 16 to 24, characterized in that it comprises between one and four foci (Fj), coming from one or more X-ray generating tubes.
    [26" id="c-fr-0026]
    26 - Installation according to one of claims 16 to 25, characterized in that the number and arrangement of image sensors (Cji) and associated homes, are such that for each container (2) during its movement, the radiographic projections of the region to be inspected on the image sensors have between three and forty, and preferably between four and fifteen different projection directions.
    [27" id="c-fr-0027]
    27 - Installation according to one of claims 16 to 26, characterized in that:
    - the image sensors (Cji) are of the linear type and each comprise a linear network of elements sensitive to X-rays, distributed along a support line (Lji) defining with the associated focal point (Fj), a projection plane ( Pji) containing the direction of projection (Dji), these image sensors being arranged so that:
    • at least m sensitive elements of each of these image sensors receive the radiographic projection of the region to be inspected by the X-ray beam from the associated focus (Fj);
    • the projection planes (Pji) for the various image sensors are distinct from each other and not parallel to the conveying plane (Pc).
    [28" id="c-fr-0028]
    28 - Installation according to claim 27, characterized in that at least three linear image sensors (Cji) have their support lines (Lji) parallel to each other.
    [29" id="c-fr-0029]
    29 - Installation according to one of claims 27 and 28, characterized in that at least three linear image sensors (Cji) have their support lines (Lji) orthogonal to the conveying plane (Pc).
    [30" id="c-fr-0030]
    30 - Installation according to one of claims 27 to 29, characterized in that a focus (Fj) is positioned on one side of the conveying plane (Pc), and in that at least one image sensor (Cji) associated linear, is positioned on the side opposite the focus (Fj) relative to the conveying plane (Pc) and so that its straight support (Ljï) is parallel to the conveying plane (Pc).
    [31" id="c-fr-0031]
    31 - Installation according to one of claims 16 to 30, characterized in that it comprises a provision device for the system
    5 computer, the attenuation coefficient of the glass constituting the containers.
    [32" id="c-fr-0032]
    32 - Installation according to one of claims 16 to 31, characterized in that it comprises a device for making available to the computer system, an a priori geometric model of the region to be inspected which is a mass memory, a wired or wireless computer network or a
    10 man-machine interface.
    [33" id="c-fr-0033]
    33 - Installation according to one of claims 16 to 32, characterized in that it comprises a device for making available for the computer system, values and / or tolerances for the dimensions of the neck and / or minimum value d glass thickness for the body wall, and / or
    15 of at least one geometric reference model of a container.
    1/5
    FIG.2
    2/5
    FIG.3
    FIG.4
    3/5
    FIG.6
    FIG.7
    4/5
    FIG.8
    FIG.9
    C22
    5/5 / / C31 i i
    FIG.12
    FIG.13
    National registration number
    FA 845609
    FR 1760173
    FRENCH REPUBLIC irpi - I NATIONAL INSTITUTE
    PROPERTY
    INDUSTRIAL
    PRELIMINARY SEARCH REPORT based on the latest claims filed before the start of the search
    DOCUMENTS CONSIDERED AS RELEVANT Relevant claim (s) Classification attributed to the invention by ΙΊΝΡΙ Category Citation of the document with indication, if necessary, of the relevant parts X W0 2010/025539 Al (OPTOSECURITY INC [CA]; 16,21, G01B15 / 02 BOUCHARD MICHEL [CA]; GUDMUNDSON DAN [CA]; 25.31 to 33 G01N23 / 04 BOUR) March 11, 2010 (2010-03-11)Y * abbreviated * 1-15,* page 4, line 23 - page 5, line 4 * 17-20* page 8, lines 11-18 * 22-24* page 13, lines 22-27 * 26-30* page 17, line 12 - page 30, line 9 * * figures 1,2,4a, 4b, 5a, 5b, 9a, 16a, 16b *X JP S60 260807 A (KAWASAKI STEEL C0; FUJI 16,17ELECTRIC C0 LTD) 21December 24, 1985 (1985-12-24) 24-26 31-33 Y * abbreviated * 1,4,8,* figures 3,5-7 * 11,15,* paragraphs [0001], [0003] * 16,21,25* page 1 *X US 5,864,600 A (GRAY GLENN [US] ET AL) 16,25,January 26, 1999 (1999-01-26) 31-33 TECHNICAL AREAS Y * abbreviated * 1-29 RESEARCHED (IPC) * figures 1,6,9 *G01B * column 1, lines 10-15 *B07C * column 1, line 36 - column 6, lineG01N 24 *G01V * column 8, line 5 - column 10, line 58 * - / -
    Research completion date
    Examiner
    April 19, 2018
    CATEGORY OF DOCUMENTS CITED
    Poizat, Christophe
    EPO FORM 1503 12.99 (P04C14)
    X: particularly relevant on its own
    Y: particularly relevant in combination with another document in the same category
    A: technological background
    O: unwritten disclosure
    P: intermediate document
    T: theory or principle underlying the invention
    E: patent document with a date prior to the filing date and which was only published on that filing date or on a later date.
    D: cited in the request
    L: cited for other reasons &: member of the same family, corresponding document page 1 of 3
    FRENCH REPUBLIC
    National registration number
    FA 845609
    FR 1760173 irai - I NATIONAL INSTITUTE
    PROPERTY
    INDUSTRIAL
    PRELIMINARY SEARCH REPORT based on the latest claims filed before the start of the search
    EPO FORM 1503 12.99 (P04C14)
    DOCUMENTS CONSIDERED AS RELEVANT Relevant claim (s) Classification attributed to the invention by ΙΊΝΡΙ Category Citation of the document with indication, if necessary, of the relevant parts YYY US 2009/262891 Al (ZHANG LI [CN] AND AL)October 22, 2009 (2009-10-22)* abbreviated ** figures 1-4,7 ** paragraphs [0002], [0007] - [0014],- [0030], [0035] - [0045] ** claims 1,14,16,17,18,29 *W0 2010/092368 A2 (DURHAM SCIENT CRYSTALS LTD [GB]; ROBINSON MAX [GB])August 19, 2010 (2010-08-19)* abbreviated ** page 1, lines 3-30 ** page 3, lines 20-25 ** page 4, line 1 - page 9, line 18 ** page 22, line 14 - page 23, line 10 ** page 28, line 19 - page 29, line 6 ** figures 1,8 ** figures la, lb *DE 197 56 697 Al (PFEILER MANFRED DR ING [DE]; MARHOFF PAUL DI PL ING [DE])July 1, 1999 (1999-07-01)* abbreviated ** page 1, line 3 - page 8, line 31 ** figures 1-8 *- / - 2.5-7,9-13,15-2022-2426-30I, 2.5,II, 16,17,24,26-302,3,5,7,9,10,12,13,15,16,18,20.22,23.26 to 30 TECHNICAL AREAS SOUGHT (IPC) Research Completion Date ExaminerApril 19, 2018 Poizat, Christophe CATEGORY OF DOCUMENTS CITED T: theory or principle underlying the inventionE: patent document with an earlier date X: particularly relevant on its own at the filing date and which was not published until that dateY: particularly relevant in combination with a deposit or at a later date.other document of the same category D; cited in requestA: technological background L: cited for other reasonsO: unwritten disclosureP: interlayer document &: member of the same family, corresponding document
    page 2 of 3
    FRENCH REPUBLIC
    National registration number
    FA 845609
    FR 1760173 irai - I NATIONAL INSTITUTE
    PROPERTY
    INDUSTRIAL
    PRELIMINARY SEARCH REPORT based on the latest claims filed before the start of the search
    DOCUMENTS CONSIDERED AS RELEVANT
    Relevant claim (s)
    Classification attributed to the invention by ΙΊΝΡΙ
    Category
    Citation of the document with indication, if necessary, of the relevant parts
    US 2006/058974 Al (LASIUK BRIAN W [US] ET AL) March 16, 2006 (2006-03-16) * abridged * * Figures 1,1b, 9 * * paragraphs [0002], [0013], [0033] - , [0043], [0060], [0078] [0082], [0100] *
    1,4,14,
    TECHNICAL AREAS SOUGHT (IPC)
    EPO FORM 1503 12.99 (P04C14)
    Research completion date
    April 19, 2018
    Examiner
    Poizat, Christophe
    CATEGORY OF DOCUMENTS CITED
    X: particularly relevant on its own
    Y: particularly relevant in combination with another document in the same category
    A: technological background
    O: unwritten disclosure
    P: intermediate document
    T: theory or principle underlying the invention
    E: patent document with a date prior to the filing date and which was only published on that filing date or on a later date.
    D: cited in the request
    L: cited for other reasons &: member of the same family, corresponding document page 3 of 3
    ANNEX TO THE PRELIMINARY RESEARCH REPORT
    RELATING TO THE FRENCH PATENT APPLICATION NO. FR 1760173 FA 845609
    EPO FORM P0465
    This appendix indicates the members of the patent family relating to the patent documents cited in the preliminary search report referred to above.
    The said members are contained in the computer file of the European Patent Office on 19 “04-2018
    The information provided is given for information only and does not engage the responsibility of the European Patent Office or the French Administration
    Patent document cited in the research report Publication date Patent family member (s) Publication date wo 2010025539 al 11-03-2010 EP 2331944 al 15-06 2011 US 2010208972 al 19-08 2010 US 2014211980 al 31-07 2014 WO 2010025539 al 11-03 2010 JP S60260807 AT 24-12-1985 JP ΗΘ311646 B2 18-02 1991 JP 560260807 AT 24-12 1985 us 5864600 AT 26-01-1999 AT 274694 T 15-09 2004 BR 9610662 AT 21-12 1999 IT 2233074 al 03-04 1997 OF 69633243 DI 30-09 2004 OF 69633243 T2 22-09 2005 DK 0852718 T3 03-01 2005 EP 0852718 al 15-07 1998 ES 2225890 T3 16-03 2005 JP 3667348 B2 06-07 2005 JP H11514435 AT 07-12 1999 PT 852718 E 31-01 2005 US 5602890 AT 11-02 1997 US 5864600 AT 26-01 1999 WO 9712233 al 03-04 1997 us 2009262891 al 22-10-2009 CN 101561405 AT 21-10 2009 OF 102009018137 al 29-10 2009 OF 102009061763 al 18-02 2016 EP 2273257 al 12-01 2011 US 2009262891 al 22-10 2009 WO 2009127118 al 22-10 2009 wo 2010092368 A2 19-08-2010 EP 2396672 A2 21-12 2011 ES 2546467 T3 23-09 2015 JP 5763551 B2 12-08 2015 JP 2012517587 AT 02-08 2012 JP 2015038504 AT 26-02 2015 US 2012004513 al 05-01 2012 WO 2010092368 A2 19-08 2010 OF 19756697 al 01-07-1999 NO US 2006058974 al 16-03-2006 US 2006058974 al 16-03 2006 WO 2006033868 A2 30-03 2006
    For any information concerning this annex: see Official Journal of the European Patent Office, No.12 / 82
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    法律状态:
    2019-05-03| PLSC| Publication of the preliminary search report|Effective date: 20190503 |
    2019-10-23| PLFP| Fee payment|Year of fee payment: 3 |
    2020-10-22| PLFP| Fee payment|Year of fee payment: 4 |
    2021-10-22| PLFP| Fee payment|Year of fee payment: 5 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1760173|2017-10-27|
    FR1760173A|FR3073044B1|2017-10-27|2017-10-27|METHOD AND DEVICE FOR MEASURING DIMENSIONS BY X-RAYS, ON EMPTY GLASS CONTAINERS RUNNING IN LINE|FR1760173A| FR3073044B1|2017-10-27|2017-10-27|METHOD AND DEVICE FOR MEASURING DIMENSIONS BY X-RAYS, ON EMPTY GLASS CONTAINERS RUNNING IN LINE|
    US16/758,180| US20200333133A1|2017-10-27|2018-10-29|Method and device for measuring dimensions by x-rays, on empty glass containers running in a line|
    RU2020116515A| RU2020116515A3|2017-10-27|2018-10-29|
    CN201880070267.4A| CN111279149A|2017-10-27|2018-10-29|Method and device for measuring the dimensions of empty glass containers travelling in a flow line by means of X-rays|
    EP18803753.5A| EP3701222A1|2017-10-27|2018-10-29|Method and device for measuring dimensions by x-rays, on empty glass containers running in a line|
    BR112020007832-8A| BR112020007832A2|2017-10-27|2018-10-29|method for measuring dimensions, and, installation for automatically measuring linear dimensions|
    JP2020523449A| JP2021500577A|2017-10-27|2018-10-29|Methods and equipment for measuring the dimensions of multiple empty glass containers running in-line with X-rays|
    PCT/FR2018/052683| WO2019081876A1|2017-10-27|2018-10-29|Method and device for measuring dimensions by x-rays, on empty glass containers running in a line|
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