JPH07333140A - Detection method and device for resin film crystal orientation of lamination plate - Google Patents

Abstract

PURPOSE:To provide a method as well as a device for inexpensively marking a lamination plate without any need of a substantial facility by projecting polarized light to the plate containing information recorded via the change of crystal orientation at the specified position of a resin film, and transmitting the polarized light through a polarizing filter for detecting the distribution of the crystal orientation. CONSTITUTION:When a lamination raw plate 5 such as a steel sheet is heated with a roll and a resin film 3 is' compression pasted thereon, a pattern roll is employed for forming a portion having temperature different from surrounding temperature and the crystal orientation of the film 3 is thereby changed to mark a bar code, a position mark or the like thereon. A. lamination plate 4 so marked is, then, exposed to monochromatic light projected from a light source 6. The light from the source 6 turns into light L1 having a transverse vibration plane after a polarizing plate 1. Then, the light is incident on the film 3 and reflected with the plate 5. As a result, light having a vertical component is incident on a polarizing filter 2a. In this case, a part of the light pass the filter 2a. The light through the filter 2a is converted to the variable density of light at an image processing device, and a mark is read on a monitor 9.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method / apparatus for detecting the degree of crystal orientation of a resin film in a laminated board and a method for recording information on the laminated board by applying them to information recording
The present invention relates to an apparatus, an information recording laminated board, and an information reading method / apparatus.

[0002]

2. Description of the Related Art Conventionally, information such as a mark for feeding amount feedback on a laminated plate obtained by laminating a synthetic resin film on a thin metal plate, or a symbol indicating the material or thickness of the metal or resin film of the laminated plate In the case of recording, a method is adopted in which a magnetic mark that magnetizes a specific portion of the metal plate is placed or a mark is placed by inkjet. However, when a magnetic mark is put in, a magnetic head for writing or reading and a device such as a peripheral device thereof become large in size and a large space is required. In addition, the magnetic mark may disappear during handling. In the case of inkjet marks,
Since ink is used, there is a problem in hygiene. In particular, can materials such as food cans and beverage cans require careful handling in terms of food hygiene, so hygienic marking is required. Furthermore, since a quick-drying chemical such as methyl ethyl ketone is used as a solvent for the ink, there are health and pollution problems. There is also a problem with running costs. In addition, in any of the above methods, the equipment cost is high. On the other hand, the applicant has previously set the crystal orientation degree (BO value) of the resin film in a region near the bottom of the can where the degree of processing is low in the laminated plate for can manufacturing, thereby making the resin film after can molding. Has been proposed (see Japanese Patent Application No. 5-213470). Along with this, in order to increase the crystal orientation of a specific region of the resin film in the laminated plate, a method of giving a partial temperature difference to the metal plate immediately before lamination is also proposed. However, the distribution state of the crystal orientation of the obtained laminated plate is measured by a film crystal orientation measuring instrument utilizing X-ray diffraction, so that the equipment cost becomes expensive and the crystal can be rapidly crystallized in the production line. It was not possible to detect the distribution pattern of the orientation degree.

[0003]

DISCLOSURE OF THE INVENTION The present invention solves the above-mentioned problems of the conventional marking method, and, firstly, does not require a large facility or space, is hygienic, and is inexpensive, and a method for marking a laminated plate. The challenge is to provide. Further, it is an object of the present invention to provide a method and an apparatus for detecting the distribution of the crystal orientation degree of the resin film in the laminate, to which the means for solving the above problems can be widely applied.

[0004]

A method for detecting the degree of crystal orientation of a resin film in a laminate according to the present invention comprises projecting light polarized at an angle onto the laminate and reflecting the reflected light at a predetermined angle. It is characterized in that the distribution of the degree of crystal orientation is detected by changing the brightness or color of light through a polarization filter having a polarization angle of. Such a detection method includes a projector that projects light onto a laminate plate at a constant angle, a first polarization filter that is provided in front of the projector, an optical element that detects reflected light, and an optical element of the optical element. A second polarization filter provided on the front surface, wherein the angle formed by the polarization angle by the first filter and the polarization angle by the second filter is in a relationship of approximately 0 degrees or 90 degrees. Is.

The method of recording information on the laminate plate of the present invention is characterized by changing the crystal orientation degree of a specific portion of the resin film with the surrounding crystal orientation degree.

In such a method, when a metal plate is heated and a resin film is pressure-bonded on the metal plate for lamination, a region heated to a temperature different from the surroundings is provided on the metal plate and the region is pressure-bonded. It can be carried out by making the degree of crystal orientation of the resin film different from that of the surroundings.

The information recording laminate of the present invention comprises a metal plate and a synthetic resin film laminated on the metal plate and having crystal orientation. Characterized by being different. The information may be a position mark indicating a position, or may be a symbol such as a barcode or a character.

The laminated plate recording / reading method of the present invention projects a light polarized at an angle onto the information recording portion of the laminate, and reflects the reflected light with a polarizing filter having a predetermined polarization angle with respect to the angle. It is characterized in that the local change in the degree of crystal orientation is detected by lightness or darkness or a change in color by seeing through.

An apparatus for manufacturing an information recording laminated plate of the present invention has a heating roll for heating a metal plate and a pair of laminating rolls for press-bonding the heated metal plate and a resin film to each other. It is characterized in that unevenness having a shape representing information is formed.

Further, a second aspect of the manufacturing apparatus of the present invention is,
A heating roll that uniformly heats the metal plate, an information transfer roll that contacts the heated metal plate and raises or lowers the temperature of a portion of a predetermined shape, and a resin film on the partially heated or cooled metal plate. It is composed of a pair of laminating rolls to be pressure bonded.

[0011]

[Function] Generally, even if the synthetic resin film of the laminate has a local difference in crystal orientation, it is not visible to the naked eye.
It is difficult to detect even with a camera or the like. Therefore, conventionally, information writing and reading such as a marking method utilizing a difference in the degree of orientation due to heat have not been considered at all. The present invention detects a local change in the orientation degree based on the following principle, and proposes a new information recording method using the change.

As shown in FIG. 9, when one of the two deflecting plates is fixed and the other is rotated, the light of the light source 6 becomes invisible to the observer K at an angle. However, when the resin film 3 pulled in one direction is inserted between the deflecting plates 1 and 2, and the resin film 3 is rotated, a part of light is transmitted to the other polarizing plate 2 at an angle. become. The intensity of light periodically changes every time the resin film 3 is rotated 90 °. Such a phenomenon has a crystal orientation in which crystals are aligned in the direction pulled by the resin film 3, the refractive index is high in the direction in which the film is pulled, and the refractive index is low in the direction perpendicular thereto.
This is because it has a so-called birefringence property. That is, the light transmitted through the first polarizing plate 1 passes only the vibration wave in the vertical direction, but when it passes through the inside of the resin film 3, it is divided into a component Y1 in the pulled direction and a component Y2 in the direction perpendicular thereto, and advances.
This is because the two lights Y1 and Y2 have a phase difference due to different speeds, and the combined wave thereof passes through the resin film while changing the vibration direction.

The intensity I (θ) of the light when the film 3 set between the two polarizing plates 1 and 2 is rotated by an angle θ is I (θ) = IMAX · Sin ² θ · Sin It can be expressed as ² (δ / 2) ... (1). This equation (1) can be rewritten as follows. I (θ) = IMAX · Sin ² θ · Sin ² {πd (n ₂ −n ₁ ) / λ ₀ (2) where IMAX is the intensity of light when the polarization angles of the two deflecting plates are made parallel. Where δ is the phase difference between the two lights Y1 and Y2, n ₂ and n ₁ are the optical path lengths, and λ ₀ is the wavelength.
The phase difference δ is the extent to which the resin film is stretched (stretched), that is, the degree of crystal orientation (BO value).
Therefore, if the degree of crystal orientation is partially different in one resin film 3, the phase of the light transmitted to the second polarizing plate 2 differs depending on the distribution, and it can be observed as bright and dark. The method for detecting the degree of crystal orientation of a laminated steel sheet according to the present invention is an application of the above method. In this case, as shown in FIG.
The light reflected by the surface of the above and returned is passed through the second polarizing plate 2, and the light passing therethrough is detected. Then, by directly observing the light or performing an optical-electronic process, a local change (distribution) of the crystal orientation degree can be detected.

[0014]

EXAMPLES Next, referring to the drawings, a detection method, a detection apparatus, an information recording method, an information recording laminated plate of the present invention,
An example of a reading method and a manufacturing apparatus will be described. Figure 1
2 is a schematic side view showing an embodiment of the detection device of the present invention, FIG.
Is an explanatory view showing the principle of the method of the present invention, FIGS. 3 and 4 are schematic side views showing one embodiment of the information recording apparatus of the present invention, and FIGS. 5a and 5b are used for the information recording apparatus of the present invention. FIG. 6 is a schematic perspective view showing another embodiment of the information recording apparatus of the present invention.
7a to 7c are plan views of the essential parts of the information recording laminated plate of the present invention, FIG. 8 is an explanatory view showing an embodiment of the reading method of the present invention, and FIG. 9 is a schematic perspective view showing the basic principle of the method of the present invention. It is a figure.

In FIG. 1, reference numeral 4 denotes a laminate plate, and the laminate plate 4 is composed of an original plate 5 such as a thin steel plate and a synthetic resin film 3 laminated on the original plate 5. Further, 6 in FIG. 1 is a light source of white light or monochromatic light, and 7 is a camera. An image processing device 8 such as a microcomputer and a monitor 9 are connected to the camera 7. The first polarizing plate 1 is provided in front of the light source 6. A polarizing filter 2a is provided in front of the camera 7. The camera 7 has an optical axis aligned so that the light L1 emitted from the light source 6 is reflected by the surface of the original plate 5 of the laminate plate 4 and the reflected light L2 can be detected through the polarization filter 2a. The original plate 5 of the laminate plate 4 may be a thin steel plate, particularly a metal plate such as ten-free steel, tin plate, nickel-plated steel plate, zinc-plated steel plate, or chrome-plated steel plate. However, the original plate is not necessarily limited to the above-mentioned one, and may be any one that can reflect light on its surface. For example, a metal plate vapor-deposited on a synthetic resin sheet or the like can be used as the original plate.

As the synthetic resin film 3, polyethylene, polypropylene, ethylene-propylene copolymer,
Ethylene-vinyl acetate copolymer, ethylene-acrylic ester copolymer, olefin resin film such as ionomer, polyester film such as polybutylene terephthalate, or polyamide film such as nylon 6, nylon 6.6, nylon 11, nylon 12, etc., Examples include stretched films such as uniaxially stretched or biaxially stretched films such as thermoplastic resin films such as polyvinyl chloride films and polyvinylidene chloride films. When an adhesive is used when laminating the original plate and the film, urethane adhesive, epoxy adhesive, acid-modified olefin resin adhesive, copolyamide adhesive, copolyester adhesive, etc. are preferably used. To be The thickness of the film is not particularly specified, but when used as a material for cans such as food cans and beverage cans, it is preferably about 1 μm to 100 μm. The resin film 3 is preferably transparent, but may be translucent as long as it has translucency.

The camera 7 is preferably a CCD line sensor camera, an area sensor camera or the like, which can convert an optically obtained image into analog or digital information. However, instead of the camera 7, it is also possible to directly observe visually.

The polarizing plate 1 is the same as a polarizer (polarizer) in a device for examining the birefringence of mineral crystals, and corresponds to the first polarizing plate described in the above section "Operation". For this, a commercially available polarizing film or the like can be adopted. The polarizing filter 2a in front of the camera 7 is the same as the analyzer and is the second polarizing plate. A commercially available polarizing filter for a camera or the like can be used for this. Polarizing plate 1
The polarization angles of the polarization filter 2a and the polarization filter 2a are made to be right angles as shown in FIG. That is, if the light is reflected directly by the original plate 5 without passing through the resin film 3, the light L2 is combined in such a direction that it does not come out through the polarization filter 2a. The polarization angles of the polarizing plate 1 and the polarization filter 2a may be parallel to each other.

The method of detecting the crystal orientation degree of the resin film 3 of the laminate plate 4 by the detecting device A constructed as described above is as follows. When monochromatic light is emitted from the light source 6, the light passes through the polarizing plate 1, and as shown in FIG.
For example, the light L1 has a horizontal vibration surface. The light L1 enters the resin film 3 at an incident angle θ and is reflected by the surface of the metal original plate 5. Further, the reflected light exits from the resin film 3 and enters the polarization filter 2 at the reflection angle θ. At this time, the vibrating surface rotates in the resin film 3, and light having a vertical component enters the polarizing filter 2. Therefore, a part of the light passes through the polarization filter 2, is detected by the camera 7, undergoes amplification processing by the image processing device 8, and can be observed by the monitor 9. In that case, if the crystal orientation is uniformly distributed in the range of observation, the screen of the monitor 9 is of uniform brightness. Therefore, in that case, it is found that the crystal orientation degree is uniformly distributed. If the crystal orientation degree of the resin film 3 is partially different, light and shade occur. This light and shade is a relative one having periodicity, and a portion having a high degree of crystal orientation is bright and a portion having a low degree of crystal orientation is not dark. By detecting this relative light and shade through the monitor 9, the distribution of crystal orientation can be easily grasped. It should be noted that the detection range of the camera 7 is, for example, running the laminate plate 4 and reciprocating the camera 7 at right angles to perform appropriate scanning or increase the number of cameras to increase the degree of crystal orientation in a wide range. The distribution can be detected and analog or digital data can be obtained. Further, by further processing the data, for example, edge enhancement processing and coloring processing, it is possible to make the distribution of the crystal orientation degree easier to understand.

The crystal orientation degree can be detected, for example, by detecting the distribution of the crystal orientation degree that naturally occurs in the manufacturing process of the laminated plate to detect a lamination defect or the like. Further, in the case of a laminated plate for can manufacturing, a ring-shaped region corresponding to a side wall of a can that is highly processed may be treated in advance so that the degree of crystal orientation becomes low. Flat 5-2134
(See No. 70) The method of the present invention can also be used to check whether or not the processing in that case is performed correctly.

Further, by forming a region having a crystal orientation different from the surroundings in a specific shape on a part of the laminated plate, information such as a position mark and a bar code is recorded on the laminated plate, and the detection method is used. The information can be read. Hereinafter, a method of recording information including a region having a specific degree of crystal orientation change will be described with reference to FIGS. In FIG. 3, reference numeral 10 is a heating roll for heating the original plate 5 made of metal up to around the temperature required for lamination, and reference numeral 12 is for forming a high temperature portion or a low temperature portion on the original plate 5 in a specific pattern representing information. It is a pattern roll. Further, the pair of rolls 13 and 14 are laminating rolls for press-bonding the resin film 3 having crystal orientation to the heat-treated and patterned original plate 5.

Like the pattern roll 15 shown in FIG. 5a, each of the pattern rolls 11 and 12 has an elongated concave portion 16 formed near the end of the surface of the roll so that the concave portion does not contact the original plate 5. It is a thing. Reference numeral 17 is a concave portion for forming the above-mentioned portion having a low degree of orientation. Such a pattern roll 15 can be used, for example, to heat the original plate 5 preheated to a certain temperature, which is the heating roll 10, to a higher temperature, and in that case, the temperature of the specific pattern is low. Then, the original plate 5 is heated in a so-called halved pattern in the other high temperature region. Then, as a result of being heated to a high temperature, the portion of the resin film 3 that is pressure-bonded to the high temperature region has a reduced degree of crystal orientation, and the regions of low temperature heating corresponding to the recesses 16 and 17 do not have a reduced degree of crystal orientation. Therefore, by passing the laminating rolls 13 and 14 as shown in FIG. 3, it is possible to obtain the laminating plate 4 having a certain pattern and a portion having a high degree of crystal orientation. Conversely, it is also possible to keep the pattern roll 15 with the constant pattern of recesses 16 of FIG. 5a at a somewhat lower temperature so as to partially remove the heat of the preheated master plate 5. In that case, a region having a low crystal orientation of a specific pattern can be formed on the laminate plate 4. On the other hand, the pattern roll 18 shown in FIG. 5b has a convex portion 19 of a specific pattern that is strongly pressed against the resin film 3 formed on the surface, and whether this is also maintained at a high temperature or a low temperature. Thereby, a region having a low crystal orientation degree or a region having a high crystal orientation degree of a specific pattern can be formed.

FIG. 4 shows a structure in which the pattern roll 11 is pressed against the surface of one of the laminating rolls 14, and a high temperature or low temperature region of a specific pattern is formed on the surface of the laminating roll 14 to thereby form a resin film. It is possible to give the distribution of the crystal orientation degree of the pattern representing the specific information to 3. The imaginary lines 20 and 21 in FIG. 4 are the same as those of the pattern rolls 11 and 12, and are for heating or cooling the laminated plate 5 immediately after pressure bonding, which has come out from the laminating rolls 13 and 14. By doing so, information can be recorded after the fact. In some cases, the laminating rolls 13 and 14 themselves may be provided with irregularities as shown in FIGS. 5a and 5b to record information. Furthermore, regardless of the unevenness, by coating or embedding a material with high or low thermal conductivity in a specific part or by embedding a heater with a specific shape, the resin sheet or metal plate in contact with that part respectively Information may be recorded by controlling the temperature to generate area patterns having different crystal orientation degrees.

In FIG. 6, a pattern heating device 22 using a laser is provided on the resin film 3 side of the laminate plate 5 formed by the laminate rolls 13 and 14. This can be irradiated while scanning a laser beam in a predetermined pattern. Then, by this, it is possible to write information having a pattern of a specific shape and a low degree of crystal orientation on the resin film. This is suitable for writing information such as characters by a dot pattern or bar codes.

FIG. 7a shows the pattern roll 15 of FIG. 5a.
3 shows an information recording laminated plate 31 manufactured by using a position mark 32 along the side edge of the laminated plate 31.
Are formed. The position mark 32 is a region where the degree of crystal orientation is higher (or lower) than the surroundings, and in this embodiment, the position mark 32 is elongated with a certain width w provided at right angles to the traveling direction (longitudinal direction) of the laminate plate 31. It has a morphology. The tip side 32a corresponds to the center of the ring-shaped region 32c having a low degree of crystal orientation. FIG. 7b shows the information of the bar code 33 in which the thick line 33a and the thin line 33b are combined and arranged on the laminate plate 31. By using the bar code 33 in this way, various information such as the thickness of each of the original plate 5 and the resin film 3 and the lot number can be written in addition to the simple positional information. In FIG. 7c, the character 34 is written as information instead of the barcode. For example, it is possible to record information about an original plate or a film. By using such characters or symbols, the operator observing on the monitor can immediately recognize the information. The position information and the bar code can also be read by the image processing device (reference numeral 8 in FIG. 1) into numerical data or character information and displayed on the monitor 9.

FIG. 8 shows the operation of the image processing apparatus for accurately obtaining the center position of the position mark 32. That is, the laminate plate 31 moving in the direction of the arrow
The camera 7 is installed on the side of the camera, and the camera 7 detects the image of the fixed area G including the position mark 32. Then, as shown by P1, a portion 36 having high brightness is detected according to the width w of the position mark 32. Further, by differentiating the graph showing the relationship between the position in the longitudinal direction and the brightness of the laminate plate 31 obtained in this way,
The edge portions 37 and 38 are emphasized (P2), and then the intermediate position 39 of the edge portions 37 and 38 is determined (P3). As a result, the position mark 32 having a wide width w is used for reading,
Writing can be done smoothly, and highly accurate information can be read and written. When the laminating plate 31 is traveling fast, the light source may be a strobe light, or an image may be input by the camera 7 having a high-speed shutter.

[0027]

According to the detection method and the detection apparatus of the present invention, it is possible to easily observe or measure a change in the film crystal orientation, which is usually invisible. According to the information recording / reading method of the present invention, hygienic marking or bar code information can be recorded and read on a material laminate plate of a food can.

[Brief description of drawings]

FIG. 1 is a schematic side view showing an embodiment of a detection device of the present invention.

FIG. 2 is an explanatory diagram showing the principle of the method of the present invention.

FIG. 3 is a schematic side view showing an embodiment of the information recording apparatus of the present invention.

FIG. 4 is a schematic side view showing another embodiment of the information recording apparatus of the present invention.

5A and 5B are perspective views of essential parts showing an embodiment of a pattern roll used in the information recording apparatus of the present invention.

FIG. 6 is a schematic side view showing still another embodiment of the information recording apparatus of the present invention.

7A and 7B are plan views of essential parts of the information recording laminated plate of the present invention.

FIG. 8 is an explanatory diagram showing an embodiment of a reading method of the present invention.

FIG. 9 is a schematic perspective view showing the basic principle of the method of the present invention.

[Explanation of symbols]

 1 polarizing plate 2 polarizing plate 2a polarizing filter 3 synthetic resin film 4 laminating plate 5 original plate 6 light source 7 camera

Claims (15)

[Claims] 1. A method of detecting the distribution state of the crystal orientation degree of a resin film in a laminate plate obtained by laminating a synthetic resin film having crystal orientation on a metal plate, which comprises projecting polarized light on the laminate plate. Then, the reflected light is transmitted through a polarizing filter having a predetermined polarization angle with respect to the angle, and the distribution of the degree of crystal orientation is detected by the change in light or darkness or color of the light. Detection method. 2. The method according to claim 1, wherein the projected light is light transmitted through a polarization filter. 3. The method according to claim 1, wherein the light is monochromatic light or white light. 4. A light projector for projecting light at a constant angle with respect to a laminate plate, a first polarizing filter provided on the front surface of the light projector, an optical element for detecting reflected light, and a front surface of the optical element. It consists of the second polarizing filter provided,
An apparatus for detecting the degree of crystal orientation of a laminate plate, wherein the angle formed by the polarization angle of the first filter and the polarization angle of the second filter is in a relationship of approximately 0 degrees or 90 degrees. 5. A method for recording information on a laminated plate, which is obtained by laminating a synthetic resin film having crystal orientation on a metal plate, wherein the degree of crystal orientation of a specific portion of the resin film is changed from the degree of crystal orientation of the surroundings. A method of recording information on a laminated board, which is characterized in that 6. When a metal plate is heated and a resin film is pressure-bonded onto the metal plate to be laminated, a portion heated to a temperature different from the surroundings is provided on the metal plate, and the resin film crystal to be pressure-bonded to the portion is provided. The method of claim 5, wherein the degree of orientation is different from the surroundings. 7. A resin film is pressure-bonded and laminated on a metal plate, and then the resin film is locally heated or cooled so that the degree of crystal orientation of the site is different from that of the surroundings.
The method described. 8. The method according to claim 5, wherein the resin film of the laminate plate in which the resin film is pressure-bonded to the metal plate is irradiated with a laser in a specific locus and heated to form a portion having a low crystal orientation of a specific shape. . 9. When heating a metal plate to be laminated with a resin film with a heating roll, unevenness of a specific shape is formed on the surface of the heating roll, and the heating temperature of the metal plate is locally changed depending on the pressing force. The method according to claim 6, wherein the method is changed. 10. An information recording laminate comprising a metal plate and a synthetic resin film laminated on the metal plate and having crystal orientation, wherein the resin film has a degree of crystal orientation different from the surroundings at a portion representing predetermined information. . 11. The laminate according to claim 10, wherein the information is a position mark indicating a position. 12. The laminate according to claim 10, wherein the information is a bar code symbol or a symbol such as a character. 13. A method for reading information on a laminated plate according to claim 10, 11 or 12, wherein light polarized at a certain angle is projected on an information recording portion of the laminated plate, and the reflected light is reflected with respect to the angle. A recording / reading method for a laminate plate, wherein a local change in the crystal orientation degree is detected by a change in brightness or color by passing through a polarizing filter having a predetermined polarization angle. 14. A heating roll for heating a metal plate, and a pair of laminating rolls for press-bonding the heated metal plate and a resin film, wherein the heating roll is provided with irregularities having a shape representing predetermined information. Information recording laminated board manufacturing equipment. 15. A heating roll that uniformly heats a metal plate, an information transfer roll that contacts the heated metal plate and raises or lowers the temperature of a portion having a predetermined shape, and a metal that is partially heated or cooled. An information recording laminated plate manufacturing apparatus comprising a pair of laminating rolls for pressing a resin film onto the plate.