The present application is a 35 U.S.C. §§371 national phase conversion of PCT/EP2009/008284, filed Nov. 20, 2009, which claims priority of European Application No. 08021168.3, filed Dec. 5, 2008, the contents of which are incorporated by reference herein. The PCT International Application was published in the French language.
The subject of the present invention is a calibration method in a machine for processing plate elements, and a machine for processing plate elements using said method.
Such machines are used in particular in the printing and packaging industry, for example for the manufacture of cardboard boxes from plate elements such as sheets of preprinted cardboard. In an introduction station, these sheets are taken from a stack situated upstream of the machine, and are then positioned by an introducer in gripper bars mounted at regular intervals on a subsequent line of endless chains. The latter makes it possible to convey the sheets into the various later processing stations of the machine. Typically, such stations are devoted to cutting the sheets, ejecting the cutting waste and receiving these sheets in a stack.
In a rhythmical motion, the line of chains moves and stops periodically so that, during each movement, all the gripper bars engaged with a sheet are passed from one station to the adjacent station downstream. If it is desired to obtain a print or a quality conversion, the positioning of the sheets within the various successive stations is a fundamental operation. For the cutting of a printed sheet, it will be understood that the positioning of the sheet in the cutting station must be precise. Specifically, it is appropriate to ensure that the tools used for cutting, for example the form to be cut of a platen press, are in perfect register with the print that has previously been made on the sheet.
Patent CH 690,470 describes a device for ensuring the quality of production of a press for making packages. To do this, this device comprises a camera designed to read on the one hand location marks associated with the printing, and on the other hand a mark intended for locating the cutting position. These location marks are placed on the front spoil of the sheet held by the gripper bar. The cutting mark is made by means of a perforator secured to the cutting tools. This perforator arranges a hole in the front spoil of the sheet at the same time as the latter is cut. Further downstream, another device makes it possible to mark the sheets identified as being faulty by the camera, namely those which have an out-of-tolerance offset between the printing and the cutting.
Patent EP 1,044,908 relates to a device and a method for positioning plate elements in an introduction station. From a bed situated in a rear starting position, this method consists in engaging means for fastening a plate element to the bed, then in commanding actuators to allow its movement forward depending on the position of the plate element on the bed. Accordingly, the front edge of the plate element is brought forward, stopped and then released in a predetermined position in the grippers of the gripper bar of the conveyor device before the bed has been finally returned to the start position. In order to be able to move the bed forward, if necessary sideways or obliquely, by an adequate amount, optoelectronic means read the coordinates of the position of the plate element and calculate the movement necessary to be able to position it as correctly as possible in the gripper bar.
The processing of a batch of identical plate elements, that is to say of the same dimensions, consisting of the same material and bearing the same prints is called a job. When the operator carries out a new job on the machine, he begins by calibrating the sensors which are used to detect the various location marks printed on the plate elements. This operation requires operator expertise, takes time and consumes plate elements in order to carry out the various tests until an acceptable result is obtained.
The object of the present invention is to remedy the aforementioned disadvantages so as to reduce the time for starting new jobs, the consumption of plate elements during start-up and to improve the quality obtained.
Accordingly, the subject of the present invention is a calibration method in a processing machine and a machine for processing plate elements using this method.
The invention will be better understood on studying embodiments taken in a manner that is in no way limiting and illustrated by the appended figures in which:
a, b, c and d each illustrate the illumination of a plate element and reflection of light from a plate element which is illuminated directly or indirectly and at greater or lesser intensity of illumination.
In order to prevent any confusion in the following description, the terms “upstream” and “downstream” will be defined with reference to the direction of movement of the plate elements, as illustrated by the arrow D in
In the introduction station 2, these plate elements are placed in a stack 11, which rests notably against a gauge 6 also serving as a front stop for these elements. Thanks to the gap left at the bottom of the gauge 6, these elements may be taken one by one from the bottom of a stack 11 by means of an introducer 20. This device will make it possible to introduce each of them into a gripping member 31 of a conveyor 30, as can be better seen in
The line of chains 32 moves and stops periodically so that, during a movement, each gripping member 31 is passed from one station to the adjacent downstream station. The position of the stops for the gripping members is dictated by a constant-distance movement of the line of chains. This distance corresponds to the theoretical pitch of these members on the line of chains. The processing stations 2, 3, 4 and 5 are fixed and set apart at this same pitch so that, at each stop, the gripping members 31 are stopped in register with the tools of these stations. Such a type of machine is most frequently used to process corrugated cardboard plate elements.
As soon as the measurements have been taken by said first sensors 7, these measurements are immediately transmitted to a control unit 40 to calculate the position of the location marks and the trajectory of the introducer 20. Knowing the theoretical stopping position of the gripping member 31 in the introduction station, the control unit is capable of calculating the values of the movement parameters (lateral, longitudinal or slantwise) of the introducer 20, so that the latter correctly brings the plate element that it conveys into the gripping member, depending on its initial starting position. These calculations are made by the control unit 40 which also drives the introducer 20.
The plate element 10 will then be conveyed by the gripping member 31 into the cutting station 3, where it will be cut according to a matrix corresponding to the developed shape that it is desired to obtain, for example for the purpose of obtaining a plurality of boxes of a given shape. In this station, or in one or more subsequent stations, other operations may also be carried out such as the scoring of fold lines, the stamping of certain surfaces and/or the placement of patterns from metalized strips for example.
The devices for creating the overlapping stream of sheets and for conveying the overlapping stream are shown in greater detail in
The sheets of the overlapping stream are precisely positioned longitudinally and laterally by a positioning device 60 which has an operation that is similar to that of the introducer 20 of the processing machine shown in
Many types of plate materials, having very different characteristics, are used in the packaging industry. For example, the surface of certain materials may be very reflective, while other materials will be transparent. The shades of the materials may vary from white to matt black, and the increasingly elaborate prints are placed on their surfaces. Whatever the type of material of the plate element 10 and the print that it bears, the detection of the location marks 12 must be perfect, so that the processes carried out by the machine are in register with the prints present on the plate element 10.
The object of the present invention is therefore to ensure optimal detection of the location marks 12 printed on the plate materials, while reducing the time for starting a new job and the quantity of spoil produced during this startup, by proposing a calibration method within a machine for processing plate elements which will be used when the machine is started up for a new job and a machine for processing plate elements capable of applying this calibration method. In the detailed description that follows of exemplary embodiments of the invention, the term “introducer” will be used to designate a device the function of which is to introduce the downstream edge of a plate element 10 into the gripping member 31. Such a device corresponds to the introducer 20 shown in
For the rest of the description, the terminology and numbering of the elements will be those of
During a first step of the method that is the subject of the invention, the fastening device 21 takes hold of a plate element 10 in order to secure it to the introducer 20. The way in which this plate element 10 is selected from the batch which has to be processed is of no importance: the selection may be automatic from a stack of plate elements, or else manual.
In a second step of the method, the control unit 40 impresses on the introducer 20 a back-and-forth movement, while the plate element 10 selected during the previous step is secured to the introducer 20 by the fastening device 21.
Simultaneously, the control unit 40 drives the illumination device and the sensor 7 so that the region of the plate element bearing the location mark 12 is illuminated by the illumination device, with a different illumination for each back-and-forth movement made by the introducer 20; and in order that the reflected light intensity is measured by the sensor 7. The measurements taken by the sensor 7 are transmitted to the control unit 40 of the machine, and thereby form a succession of measurements which corresponds to the succession of back-and-forth movements made by the introducer 20.
In a final step, the control unit 40 determines, on the basis of the succession of measurements obtained during the previous step, the illumination parameters which will be used for the whole batch of plate elements, that is to say for the job in question. This determination applies conventional techniques of processing the signal, which make it possible to analyze the quality of detection for each measurement made by the sensor 7, and therefore for each corresponding illumination.
According to a preferred embodiment of the invention, one of the illumination parameters relates to the selection between a direct illumination and an indirect illumination. An illumination is considered to be direct when it is substantially perpendicular to the surface of the plate element, and to be indirect when it has an angle of incidence with the surface.
A plurality of measurements may optionally be taken for each type of illumination, direct or indirect, with various levels of light intensity.
Advantageously, for one and the same type of illumination, distinct reflected colors are measured during various back-and-forth movements, so as to adapt the illumination not only to the characteristics of the material of the plate element but also to those of the prints carried by its surface. This embodiment may, for example, consist in using a plurality of sensors 7, each measuring the reflected light intensity in a different spectrum, typically red, green and blue. The illumination parameters then comprise one light intensity parameter for each of the sources.
In a preferred embodiment, several light sources of different colors are used for each type of illumination, direct or indirect. In order to limit the number of back-and-forth movements made by the introducer 20, the type of material of which the plate element 10 is composed may be optionally indicated by the operator of the machine, so as to directly determine the type of illumination used by the illumination device 7 and an order of magnitude of the light intensity, as, for example, shown in
Once this calibration process has been carried out, the illumination parameters determined will be used throughout the job in question. The method according to the invention makes it possible to obtain in an extremely rapid manner an excellent quality of detection of the location marks, irrespective of the type of material forming the plate elements and the prints that they bear, reducing to the minimum the consumption of plate material.
A plate processing machine according to the invention will therefore comprise in a conventional manner an introducer 20 furnished with a fastening device 21. The introducer 20 makes it possible to position these plate elements 10 in a plurality of gripping members 31 of a conveyor 30, which conveys them in a rhythmical motion into successive stations. Also in a conventional manner, a processing machine according to the invention will comprise at least one LED illumination device placed so as to illuminate a location mark 12 printed on a plate element 10 when the latter is secured to the introducer 20 by the fastening device 21; and at least one sensor 7 which measures the light intensity reflected by the surface of the plate element when it is illuminated by the illumination device. The processing machine according to the invention also comprises a control unit 40, of the microprocessor or microcontroller type, which drives the introducer 20, the illumination device and the sensor 7 and which receives the measurements taken by the sensor 7.
According to the invention, the illumination device is of the type that is capable of generating various illuminations, that is to say that it is capable of generating one illumination selected from a set of possible illuminations, depending upon the illumination parameters that are transmitted to it. The introducer 20 is capable of carrying out a back-and-forth movement when a plate element is held by the fastening device. During calibration for a new job, the control unit 40 drives the introducer 20, the illumination device and the sensor 7 so that the introducer 20 makes a succession of back-and-forth movements, while a plate element 10 is held by the fastening device 21. Therefore, the location mark 12 printed on the surface of the plate element 10 is subjected to an illumination during each back-and-forth movement, and the sensor 7 measures, for each back-and-forth movement, the reflected light intensity. The control unit 40 receives the measurements taken by the sensor 7, which form a succession of measurements corresponding to the succession of back-and-forth movements made by the introducer 20.
According to the invention, the control unit 40 drives the illumination device so that a different illumination is applied to the surface of the plate element 10 during each back-and-forth movement made by the introducer 20 during calibration. Then the control unit 40, based on the succession of measurements made by the sensor 7, determines the illumination parameters which will be used for the job, that is to say for the processing of all the plate elements 10 forming the batch.
Advantageously, the illumination device makes it possible to carry out a direct illumination, that is to say in a direction substantially perpendicular to the surface of the plate element 10 conveyed by the introducer 20, and an indirect illumination, that is to say in a direction having an angle of incidence with the surface of the plate material, and the control unit 40 drives the illumination device while checking which type of illumination is used: direct or indirect. The illumination device may optionally comprise a distinct light source for each type of illumination, direct or indirect.
Preferably, the illumination device makes it possible to illuminate in various colors; for example, by comprising a plurality of light sources of different colors. The control unit 40 may advantageously drive the illumination device while determining the light intensity of each source of color.
The surface of the plate elements 10 most frequently bears a plurality of location marks 12. The processing machine then has illumination devices and the sensors 7 for each location mark. These illumination devices and these sensors 7 may be identical for all the marks. However, in order to propose a greater capability for correcting the error in lateral positioning of the plate elements 10, it is possible optionally to use different illumination devices and sensors 7 for the location mark or marks 12 designed to achieve the lateral alignment of the plate element 10 than for the location mark or marks 12 present on the downstream edge of the plate element 10. For example, for the detection and measurement of the position of the location marks printed on the downstream edge of the plate element 10, it is possible advantageously to use an illumination device comprising one or more light sources for a direct illumination and one or more light sources for an indirect illumination with a sensor 7; and for the detection and measurement of the position of the lateral location marks of the plate element 10, it is possible advantageously to use a multiple-color illumination device, for example, red, green and blue, with a sensor 7 in the form of a bar, consisting, for example of 32 to 512 monochrome cells, making it possible to measure the reflected light intensity over a straight line segment.
Preferably, the illumination device is incorporated into the casing of the corresponding sensor 7, which procures many advantages in terms of space requirement, ease of installation and mechanical adjustment, but also in terms of maintenance.
Although the present invention has been described in relation to particular embodiments thereof, many other variations and modifications and other uses will become apparent to those skilled in the art. It is preferred, therefore, that the present invention be limited not by the specific disclosure herein, but only by the appended claims.
Number | Date | Country | Kind |
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08021168 | Dec 2008 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2009/008284 | 11/20/2009 | WO | 00 | 6/6/2011 |
Publishing Document | Publishing Date | Country | Kind |
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WO2010/063380 | 6/10/2010 | WO | A |
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5705020 | Chiari | Jan 1998 | A |
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7202492 | Inhelder et al. | Apr 2007 | B2 |
7391525 | Chapman et al. | Jun 2008 | B2 |
Number | Date | Country |
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690470 | Sep 2000 | CH |
1044908 | Oct 2000 | EP |
1623943 | Feb 2006 | EP |
Entry |
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International Search Report dated Mar. 9, 2010, issued in corresponding international application No. PCT/EP2009/008284. |
Number | Date | Country | |
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20110239432 A1 | Oct 2011 | US |