Classifications

• • G—PHYSICS
  • G06—COMPUTING; CALCULATING OR COUNTING
  • G06T—IMAGE DATA PROCESSING OR GENERATION, IN GENERAL
  • G06T7/00—Image analysis
  • G06T7/0002—Inspection of images, e.g. flaw detection
  • G06T7/0004—Industrial image inspection
• • D—TEXTILES; PAPER
  • D06—TREATMENT OF TEXTILES OR THE LIKE; LAUNDERING; FLEXIBLE MATERIALS NOT OTHERWISE PROVIDED FOR
  • D06H—MARKING, INSPECTING, SEAMING OR SEVERING TEXTILE MATERIALS
  • D06H3/00—Inspecting textile materials
  • D06H3/08—Inspecting textile materials by photo-electric or television means
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
  • G01N21/00—Investigating or analysing materials by the use of optical means, i.e. using sub-millimetre waves, infrared, visible or ultraviolet light
  • G01N21/84—Systems specially adapted for particular applications
  • G01N21/88—Investigating the presence of flaws or contamination
  • G01N21/89—Investigating the presence of flaws or contamination in moving material, e.g. running paper or textiles
  • G01N21/892—Investigating the presence of flaws or contamination in moving material, e.g. running paper or textiles characterised by the flaw, defect or object feature examined
  • G01N21/898—Irregularities in textured or patterned surfaces, e.g. textiles, wood
  • G01N21/8983—Irregularities in textured or patterned surfaces, e.g. textiles, wood for testing textile webs, i.e. woven material
• • G—PHYSICS
  • G06—COMPUTING; CALCULATING OR COUNTING
  • G06T—IMAGE DATA PROCESSING OR GENERATION, IN GENERAL
  • G06T2207/00—Indexing scheme for image analysis or image enhancement
  • G06T2207/30—Subject of image; Context of image processing
  • G06T2207/30108—Industrial image inspection
  • G06T2207/30124—Fabrics; Textile; Paper

Definitions

• the present invention relates to an optical inspection device for moving material. It applies to all materials that carry a network and in particular to textiles, fabrics, wallpapers, plastics, printed materials or dyed woven fabrics.
• the currently known inspection devices have an electronic camera or a network of photosensitive components, generally linear, the optical field of which is constant, in width and in temporal frequency of taking pictures.
• the time between the start of two successive shots is therefore independent of any changes in the speed of travel of the material or changes in pitch of the network carried by the materials successively inspected.
• the two networks, that of the individual inspection zones, linked to the opto-electronic system and that of the textile, interfere and prevent any fine inspection. Indeed, on the one hand when the textile network has a smaller mesh than that of the opto-electronic system, a defect on only one of the elements of the textile network cannot be perceived by the inspection system because it causes a variation signal too weak. On the other hand, when the textile network has a larger mesh than that of the opto-electronic system, the latter detects each space between the elements of the textile network and interprets it as a drilling in the network.
• the present invention intends to remedy these drawbacks by synchronizing the duration between two shots of the image sensor and the duration of passage of one or more steps of the network carried by the material.
• the present invention provides a material inspection device having a regular pitch network, comprising means for moving said material and at least one electronic camera comprising a photosensitive dot sensor and providing a signal representative of an image. formed on said sensor, camera in the optical field of which said material moves during inspection, characterized in that it comprises means for synchronizing the frequency of passage of the successive meshes of said network and the frequency of taking camera views.
• the signals representing images from each photosensitive point during successive shots correspond to zones of the similar material by their pattern. If the material has no difference between the two successive zones which are thus observed, and in particular, no defect, the image representative signal is identical.
• the processing of this signal is therefore simplified and makes it possible to detect defects of very small dimensional importance and / or of very low contrast with the normal pattern.
• the synchronization means substantially ensures equality between the duration of passage of one or more steps of said network and the duration separating the start of two successive shots.
• the area observed by each photosensitive point of the image sensor is, with each shot, made up precisely of one or more steps of the grating.
• the optical pattern consists of parallel woven threads, the pitch of the network of the material being the repeating pitch of one or more threads carrying said pattern. Thanks to these provisions, the invention applies to woven materials, and in particular to woven textiles.
• the device according to the present invention comprises a means for tensioning the material which avoids folds in the direction perpendicular to the movement. Thanks to these provisions, the network of the material is substantially constant during the entire inspection period and / or throughout the optical field of the camera.
• the synchronization means comprises an encoding means mechanically connected to said material, and it emits at least one pulse each time the material has advanced in the field of the camera, a predetermined length.
• the speed of movement of the material is detected by the synchronization means and the duration between two successive shots taken by the camera is directly linked to said movement.
• the inspection can then be carried out with a variable speed of movement of the material, without disturbing the inspection.
• a visual inspection by an operator can be carried out in parallel with the inspection carried out by the camera, the operator directly controlling the instantaneous inspection speed. Even more particularly, the inspection carried out by the camera can assist the operator in his visual inspection.
• the synchronization means comprises a division means which receives the successive pulses leaving the encoding means and sends a pulse each time that the encoding means has emitted a predetermined number of successive pulses.
• the synchronization means comprises an optical sensor in the optical field of which the material being inspected passes, an optical sensor which emits a signal representative of the speed of movement of the material.
• an optical sensor can emit a substantially periodic signal, when the speed of movement of the material is substantially constant, the period of this signal being inversely proportional to the speed of movement of the material.
• the phase of the signal leaving the optical sensor is controlled by a control means. Thanks to these provisions, any local irregularities in the network in front of the optical sensor are eliminated by the use of this servo means.
• the device comprises a vertical differentiation means which receives the representative image signals leaving the electronic camera and emits a signal representative of the difference, for each photosensitive point of the camera, of the signals representative of images successively coming from said point.
• the pitch of the material is the pitch of a network of coating points.
• the invention therefore applies particularly to materials, in particular textiles, coated.
• the pitch of the material is the pitch of a pattern made in relief by embossing or embossing of said material or by weaving of threads constituting said material.
• the invention therefore particularly applies to materials embossed or seeded by a cylinder with repetitive patterns of small dimension in the direction of travel. It also applies to fabrics having a weaving relief.
• the pitch of the material is the pitch of a colored pattern originating from a weaving of said material or from an impression on said material.
• the invention therefore particularly applies to textiles, papers and other materials colored by printing or by weaving threads of different colors.
• the device comprises a means of slaving the duration of shooting of the electronic camera, to the light intensity received by the sensor of the electronic camera which receives the signal representative of image emerging from the electronic camera and providing said electronic camera with a shooting time control signal.
• the device according to the present invention comprises at least one means for adjusting the size of the optical field of the camera.
• the pitch of the network of zones each inspected by a photosensitive point of the camera, in the direction perpendicular to the direction of movement can also be a multiple of the pitch of the network of the material.
• the inspection of the material can then also be done by differentiation between signals coming from photosensitive points laterally joined.
• the device according to the present invention comprises a row of light sources controlled by a visit computer to illuminate individually or in groups facing the passage of detected faults.
• an operator can visualize the defects detected and assign them a treatment, for example, by validating or invalidating their detection, by recording their image or their position, by ordering a treatment of the material to eliminate each defect, .. .
• the inspection by camera can be supplemented by an inspection by a human operator with the aim of speeding up and making said inspection more reliable, while maintaining the subjective elements of appreciation, which depend, for example on the constraints of the user of the material or type of defect detected, for cleaning purposes, for example.
• FIG. 1a represents a block diagram of a first preferred embodiment of the device according to the present invention.
• FIG. 1 b represents a block diagram of a second preferred embodiment of the device according to the present invention.
• FIG. 2 shows the networks of a fabric and a camera.
• FIG. 3 represents a second embodiment of the device according to the present invention.
• FIG. 1a an inspection table 1 comprising lower light sources 2a, a grazing upper light source 2b and a front light source 2c provided with a filter 36, a textile passage 3, an unwinder 4, a reel 5, a doorbell 6, a motor 7, a memory computer 8, a motor control 9, a brake 10 and a cutter 11.
• a camera 12 carrying a filter 35 is arranged Connected to the camera 12 is a digitizer 13 which is connected, via a bus 41 to the storage computer 8, to a vertical differentiation means 14, a horizontal addition means 25, a threshold circuit 15, a fringe extractor 16, a means of horizontal differentiation 26, a means of vertical addition 27, a threshold circuit 28, a visit computer 17, a row of light sources 18, a sound transmitter 23, a printer 24 and a means of validation 29.
• an encoder 19 a frequency detection means 20 comprising an optical sensor and a phase control means and a picture-taking control means 21 are represented.
• the inspection table 1 is of known type. It allows the fabric to pass before the eyes of a user, said fabric being lit by at least one light source.
• the light sources 2a, 2b and 2c are continuous or high frequency light sources, that is to say whose light emission periods succeed each other with a frequency much higher than that of the camera 12. As for example, a frequency of 30 kilohertz allows the camera 12 to take a thousand images per second, each image corresponding to around thirty flashes emitted by the light source operating at this frequency. It should be noted that this light source is modified compared to that which is traditionally found on inspection tables, for which the operating frequencies are of the order of a few tens or a few hundred hertz, frequencies adapted to the period. retinal persistence.
• the visit computer jointly controls the levels of the light intensities permanently emitted simultaneously by the lower light sources 2a, which are located below of the inspection table and which illuminate the fabric by transparency, by the grazing upper light source 2b, which illuminates the fabric with an oblique incidence and preferably close to the right angle, and by the upper frontal light source 2c which illuminates the fabric at an angle of incidence close to the angle of view used by the camera 12.
• the upper front light source is provided with a polarizing filter 36.
• the camera 12 is provided with a polarizing filter 35, the axis of polarization of which is, depending on the types of material and the types of defects sought, either parallel (for example to detect lack of coating points on coated fabrics), either perpendicular (to detect traces on a reflective material, for example metallic) to the axis of the polarizing filter 36.
• the textile passage 3 is a zone for the movement of textiles between the light source 2 and the camera 12, on the one hand and the eyes of a user on the other.
• the means for tensioning the fabric consists of assemblies of cones between which the fabric is pinched and which are entrained in rotation by the fabric itself, around an axis oblique to the direction of movement of the fabric. This means of tensioning is well known to those skilled in the art of equipment for the textile industry.
• the unwinder 4 consists of an axis of rotation around which rotates a roller on which the textile is unwound and of a brake 10 which brakes the rotation of this roller.
• the reel 5 consists of an axis of rotation around which a roller turns on which the textile is wound and a motor 7.
• the doorbell 6 is of known type. It places on one of the edges of the fabric marks consisting either of a sticker, or of a staple, or of a thread passing through the fabric, opposite the defects detected by the device and confirmed by the user, such as presented below. These marks, also called doorbells in the textile industry, can present differences, for example of color, to indicate different types of defects, different repetitions of defects or even different origins of defects.
• the motor 7 is of known type. It activates the reel 5 to wind the textile. It is controlled by the motor control 9.
• the storage computer 8 is a computer of known type which stores the positions on the one hand and the types of faults encountered on the textile on the other hand.
• the positions are given by the encoder 19 and by the visit computer 17 according to techniques known in the field of textile inspection.
• the types of faults are given by the visit computer 17, as described below.
• the motor control 9 and the brake 10 are placed to be easily operated either by foot, or by hand, or by a production management system.
• the cutter 11 is placed on the textile passage 3 between the light source 2 and the reel 5. It allows the textile to be cut across its entire width to produce pieces of fabric, at the request of the user of this fabric . All of these first elements are of known type but are possibly electrically connected to the elements of FIG. 1 presented below for exchanging data with them.
• the camera 12 is of known type. It comprises either a matrix image sensor, which simultaneously captures illuminations on several lines of photosensitive points of the image sensor and provides a signal representative of illuminations received by said photosensitive points, or a linear image sensor which simultaneously captures the illuminations on a single line of photosensitive points of the sensor, points which follow one another on a straight line.
• the camera 12 provides an electrical signal representative of the illuminations which each reach the photosensitive points of its electronic sensor.
• the digitizer 13 receives the representative signal of illumination leaving the camera 12 and provides a digital signal representative of said illuminations.
• the vertical differentiation means 14 compares by subtraction the digital values of the signals representing illumination coming from the same photosensitive point of the image sensor, between two successive shots.
• the vertical differentiation means 14 thus receives the signals representing the image leaving the electronic camera and emits a signal representative of the difference, for each photosensitive point of the camera, of the signals representing the images successively from said point.
• the vertical differentiation means 14 provides a signal representative of this difference. It is of known type, being constituted for example either of a correspondence table, or of a comparator. Preferably, it adds a constant value to said difference so that all the values obtained remain positive.
• the horizontal addition means 25 add up the successive differences leaving the vertical differentiation means 14.
• the number of added differences is one, two, or a few units and is provided by the visit computer 17.
• the threshold circuit 15 transmits threshold crossing signals for the values leaving the horizontal addition means 25 which exceed in more or less the values supplied by the visit computer 17. It is of known type, being constituted either by 'a correspondence table, or a set of comparators.
• the fringe extractor 16 separates the threshold crossing signals for the points close to the edges of the fabric, at a distance less than a value given by the visit computer 17.
• the fringe extractor applies to the signals leaving the photosensitive points of the image sensor of the camera which receives an image of these fringes, a specific treatment for detecting specific defects of the edges of fabric, for example the lack of total width of the fabric, the excessive width of the fringes, detected by crossing thresholds and counting photosensitive points corresponding respectively to the fabric and to the fringes, the representative signals of which are at predetermined numerical values, according to techniques known to those skilled in the art of camera inspection.
• the horizontal differentiation means 26 compares by subtraction the numerical values of the successive points of each line of illumination values on the line of the image sensor, values supplied by the digitizer 13. It provides a signal representative of this difference. It is of known type, being constituted for example either of a correspondence table, or of a comparator.
• the vertical addition means 27 adds the successive differences leaving the horizontal differentiation means 26, for each point of the image sensor.
• the added differences therefore always correspond to the same pair of photosensitive points of the image sensor.
• the number of added differences is one, two, or a few units and is provided by the visit computer 17.
• the threshold circuit 28 emits threshold crossing signals for the values leaving the vertical addition means 27 which exceed values supplied by the visit computer 17. It is of known type, consisting either of a correspondence table, or of a comparator assembly.
• the visit computer 17 receives the information leaving the threshold circuits 15 and 28, the encoder 19, the width measurement means 22 and the validation means 29, processes them to provide at least a list of faults in each part of textile, list comprising the positions identified on the one hand in the direction of movement, also called “length", and on the other hand in the direction perpendicular to this movement, also called “width” and the types of defects. It also provides a measure of the width of the textile, the average width measured over a length of a few centimeters of textiles. It can provide a textile rating based on these values.
• the visit computer 17 transmits:
• the visit computer 17 analyzes on the one hand the values of the illuminations as they come out of the digitizer 13 in order to memorize the appearances of the defects, on the other hand the geometries of the sets of points of the textile for which threshold crossings have been detected by the threshold circuits 15 and 28, to classify the faults as a function of these geometries, of these digital illumination values, of the values leaving the encoder 19, of the lateral position of said sets of points and of data stored in the visit computer 17.
• the visit computer 17 uses in particular different signal processing and image processing techniques already known.
• the visit computer 17 therefore allows:
• the row of light sources 18 is placed above the textile passage 3 and includes light sources whose operation is individually controlled by the visit computer 17. At each fault detected by crossing a threshold, the visit computer 17 controls the light source or sources placed directly near the passage of the fault to illuminate it individually or in groups opposite the passage of the detected faults.
• the encoder 19 continuously provides data on the length of fabric already passed under the camera 12. It can be reset either by the user or by the inspection computer 17.
• the frequency detection means 20 is here consisting of a phase locked resonant circuit which receives the signal from an optical sensor which observes an area of the moving material smaller than the pitch of the network on which the camera is synchronized.
• the optical sensor is a photodiode, in the optical field of which the threads of the inspected fabric pass one by one or the points of a network of coating points.
• the optical filters possibly placed in front of the optical sensor may vary. The optical sensor thus emits a signal representative of the speed of movement of the material, by its frequency.
• the phase-locked resonant circuit constitutes an example of a means of phase control of the signal leaving the optical sensor.
• the picture-taking control means 21 emits an approximately periodic signal coming from the signal leaving the frequency detection means 20. This signal can have the same frequency as the signal leaving the frequency detection means 20 or even a frequency half or double of it.
• the signals coming out of the shooting control means 21 control the triggering of shooting by the camera 12.
• a means of synchronizing the frequency of passage of the successive meshes of said network and the frequency of shooting of the camera is constituted by the frequency detection means 20 cooperating with the shooting control means 21 .
• said synchronization means substantially ensures equality between the duration of passage of one or more steps of said network and the duration separating the start of two successive shots.
• the optical pattern whose pitch is used for said synchronization consists of parallel woven threads, the pitch of the network of the material being the repeating pitch of one or more threads carrying said pattern.
• the value of the pitch of the zones observed on the textile by the photosensitive points of the image sensor of the camera 12 preferably varies between ninety-five percent and one hundred and five percent of a multiple of the pitch of the textile network, and this in at least one direction of this network. This tolerance makes it possible to tolerate deformations of the textile network due to the flexibility of this textile.
• the use of a multiple of the pitch of the textile network to constitute the pitch of the observation zones of the points of the image sensor is preferable for textiles whose network is very tight, that is to say has a pitch very small, on the order of a few hundredths or tenths of a millimeter.
• the sound emitter 23 is of known type and is controlled by the visit computer 17 each time the latter sends a fault detection signal and a signal for controlling the illumination of a light source in row 18.
• the printer 24 is of known type and is connected either to the visit calculator 17, or to the storage calculator 8. It allows the emission of labels, possibly with bar codes, and visit reports, as well as data textile production statistics.
• the validation means 29 is placed within reach of the user and serves to validate or possibly eliminate the faults detected by the device which is the subject of the present invention. It should be noted that the storage computer 8 can be confused with the visit computer 17.
• a first operating mode only the faults validated by the user are counted and memorized. Each validated fault, whether or not it has been detected by the device, gives rise to the installation of a bell, to storage in the memories of the storage computer 8 and to various editions of documents.
• Figure 1b is shown a second embodiment of the device which differs from the first embodiment of the device only by the synchronization means which here consists no longer of an optical sensor followed by a phase control means but of the encoder 19 followed by a division means 39.
• a means of servo-shooting duration 38 receives the signal representative of the image leaving the camera and controls on the one hand the duration of shooting of the camera and on the other hand the maximum speed of movement of the material, such that the average level of the image representative signal is approximately constant and the blur, which is measured as the distance traveled by the material during shooting, is limited to a predetermined value.
• it uses an average value of the amplitude of the signal representing the image leaving the electronic camera, an amplitude which is representative of the average light intensity received by the sensor of the electronic camera.
• This control means uses electronic circuits and diagrams known in the field of automatic control of illumination of photographic films which jointly control two parameters, the diaphragm of the lens and the speed of shooting.
• the lens diaphragm is replaced by the speed of movement of the moving material.
• FIG. 2 are represented the networks of a fabric and a camera.
• horizontal 30 and vertical wires 31 constituting the fabric 32, rectangular areas 33 representing the areas for taking pictures of the camera 12.
• the horizontal 30 and vertical wires 31 are woven and have a rectangular mesh given by weaving.
• the rectangular areas of shots 33 overlap but have the same vertical pitch as that of the fabric, the vertical here representing the direction of movement of the fabric.
• the rectangular areas also have the same horizontal pitch as that of the fabric 32, direction perpendicular to the movement of the fabric.
• the width of the shooting areas 33 is given by the ratio of the width of the optical field of the camera 12 divided by the number of photosensitive points per line of the image sensor of the camera 12.
• the height of the shooting areas of views 33 is given by the length covered by the textile during the duration of a shooting added to the product of the ratio of height to width of each photosensitive zone of the image sensor of the camera 12 by the width of the shooting zone of views 33.
• FIG. 3 represents a second embodiment of the device according to the present invention.
• the camera 12 a zoom lens 34, a motor 35 and the visit computer 17.
• the zoom lens controls the width of the optical field of the camera 12.
• the motor 35 moves the camera 12 up and down bottom and far away or closer to the passage of fabric 3.
• the visit computer 17 calculates, as a function of the signals leaving the digitizer 13, the width of the optical field of the camera which is substantially equal to the width of the network of the textile visited. This measurement is, for example, performed with the use of Fourrier transformation functions.
• the computer 17 controls the position and operation of the motor 35 and the focal length of the zoom lens 34.
• the areas for taking pictures have, either automatically or by manual adjustment assisted by the device, a network whose steps in the direction of the length and in the direction of the width of the textile are as close as possible to a multiple of the textile steps.
• the device observes the finest irregularities.
• the detections of horizontal or vertical faults are amplified.
• the defects are classified.
• the pitch of the network of the inspected material which is used for synchronization with the duration between the beginnings of shooting by the camera, may as well be that of a relief, a woven pattern, a pattern printed, with a machined motif.
• any material undergoing treatment by a cylinder, impression or deformation for example, has a pitch equal to the circumference of the cylinder and can be inspected by a device according to the present invention.
• the use of other optical filters on light sources to enhance particular types of defects, on particular materials is an improvement of the present invention within the reach of the skilled person, by using known techniques in optics.
• a polarizing filter can, of course, be positioned on the light source 2c as well as on one of the other light sources.
• inspection table 1 light source 2 textile passage 3 unwinder 4 reel 5 doorbell 6 motor 7 memory computer 8 motor control 9 brake 10 cutter 11 camera 12 digitizer 13 differentiation means 14 threshold circuit 15 fringing extractor 16 visit computer 17 row of light sources 18 encoder 19 frequency detection means 20 shooting control means 21 sound transmitter 23 printer 24 horizontal addition means 25 horizontal differentiation means 26 vertical addition means 27 threshold circuit 28 validation means 29 horizontal wires 30 vertical wires 31 fabric 32 rectangular areas 33 motor 34

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• Engineering & Computer Science (AREA)
• Textile Engineering (AREA)
• Physics & Mathematics (AREA)
• Life Sciences & Earth Sciences (AREA)
• Chemical & Material Sciences (AREA)
• General Physics & Mathematics (AREA)
• Theoretical Computer Science (AREA)
• Computer Vision & Pattern Recognition (AREA)
• Quality & Reliability (AREA)
• Materials Engineering (AREA)
• Wood Science & Technology (AREA)
• Health & Medical Sciences (AREA)
• Analytical Chemistry (AREA)
• Biochemistry (AREA)
• General Health & Medical Sciences (AREA)
• Immunology (AREA)
• Pathology (AREA)
• Treatment Of Fiber Materials (AREA)
• Investigating Materials By The Use Of Optical Means Adapted For Particular Applications (AREA)

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• 1994
  • 1994-11-02 FR FR9413419A patent/FR2726299A1/fr active Granted
• 1995
  • 1995-11-02 EP EP95939316A patent/EP0789795A1/de not_active Withdrawn
  • 1995-11-02 US US08/836,280 patent/US5990468A/en not_active Expired - Fee Related
  • 1995-11-02 WO PCT/FR1995/001444 patent/WO1996014460A1/fr not_active Application Discontinuation

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