JP7069621B2 - Heat seal inspection equipment, heat seal inspection method, and program for heat seal inspection equipment - Google Patents

Description

The present invention relates to a heat seal inspection device, a heat seal inspection method, and a program for the heat seal inspection device.

A container such as a standing pouch for storing a liquid content such as a liquid detergent or a drink is formed by heat-sealing the bottom and sides. The container is inspected for possible leaks. For example, Patent Document 1 describes a package or a package in which the heat-sealed portion is formed at a position where the heat-sealed portion should be stopped when the package or the material to be the package is stopped while moving intermittently. Flat light is projected onto the material that should be the body through the window hole of the dark box, and the reflected light is imaged on the screen as an image. Disclosed is a method for inspecting a heat-sealed portion for detecting an abnormality or misalignment in the width of the heat-sealed portion by comparing with a reference value.

Japanese Unexamined Patent Publication No. 2001-116517

The heat-sealed material unwound from the roll is transported in a relatively loose state without excessive tension so that the front and back patterns do not shift after the heat seal. However, the heat-sealed material transported in a relatively loose state has fluttering, and the comparison of reflectances in the prior art could not accurately inspect the sufficiently heat-sealed portion.

Therefore, the present invention has been made in view of the above-mentioned problems and the like, and an example of the problem is to provide a heat-sealing inspection device and the like capable of accurately inspecting a heat-sealed portion.

In order to solve the above problems, the invention according to claim 1 separates the heat-sealed object by each of the plurality of illuminators arranged on all sides of the photographing area of the object. An image acquisition means for acquiring a plurality of illuminated images, a visualization image generation means for generating a visualization image that visualizes a heat-sealed heat-sealed portion of the object from the plurality of illumination images, and a visualization image of the visualization image. Based on the form of the heat-sealed portion, the determination means for determining whether or not the object is properly heat-sealed is provided , and the determination means prints on the heat-sealed portion and the object in the visualized image. It is characterized in that it is determined whether or not the object is properly heat-sealed based on the positional relationship with the printed portion .

Further, the invention according to claim 2 further includes a feature point calculation means for calculating the feature points of the heat seal portion of the visualization image in the heat seal inspection apparatus according to claim 1, wherein the determination means is used. It is characterized in that it is determined whether or not the object is properly heat-sealed based on the positional relationship between the feature points of the heat-sealed portion and the printed portion. According to the third aspect of the present invention, in the heat seal inspection device according to the first or second aspect, the image acquisition means acquires a polygonal illuminated image simultaneously illuminated from a plurality of angles and prints the image on the object. The printed portion is the printed portion of the polygonal illumination image. In the invention according to claim 4 , in the heat seal inspection apparatus according to any one of claims 1 to 3, the image acquisition means acquires a polygonal illuminated image simultaneously illuminated from the surroundings, and the polygon is described. Further provided with an image correction means for correcting the visualized image by an illumination image, the determination means determines whether or not the object is properly heat-sealed based on the form of the heat-sealed portion of the corrected visualization image. It is characterized by making a judgment.

Further, in the invention according to claim 5 , in the heat seal inspection apparatus according to claim 4 , the corrected visualization image is a difference image between the contour image obtained by extracting the contour from the polygonal illumination image and the visualization image. It is characterized by being.

Further, in the invention according to claim 6 , in the heat seal inspection apparatus according to claim 5 , the difference image is subjected to expansion processing on the contour image and then difference processing with the visualization image. It is characterized in that it is calculated.

Further, in the invention according to claim 7 , the image acquisition means separately illuminates the heat-sealed object by each of the illuminators of a plurality of illuminators arranged on four sides of the photographing area of the object. An image acquisition step of acquiring a plurality of illumination images, and a visualization image generation step of generating a visualization image in which the visualization image generation means emphasizes a heat-sealed heat-sealed portion of the object from the plurality of illumination images. The determination means includes a determination step of determining whether or not the object is properly heat-sealed based on the form of the heat-sealed portion of the visualization image , and the determination means includes the determination means of the visualization image. It is characterized in that it is determined whether or not the object is properly heat-sealed based on the positional relationship between the heat-sealed portion and the printed portion printed on the object .

The invention according to claim 8 is a plurality of heat-sealed objects in which a heat-sealed object is separately illuminated by each of the plurality of illuminators arranged on four sides of the photographing area of the object. An image acquisition means for acquiring an illumination image, a visualization image generation means for generating a visualization image in which a heat-sealed heat-sealed portion of the object is emphasized from the plurality of illumination images, and the heat-seal portion of the visualization image. Based on the form of the above, the object is made to function as a determination means for determining whether or not the object is properly heat-sealed, and the determination means includes the heat-sealed portion of the visualized image and the printed portion printed on the object. It is characterized in that it is determined whether or not the object is properly heat-sealed based on the positional relationship of .

According to the present invention, a visualization image in which a heat-sealed heat-sealed portion of an object is emphasized is generated from a plurality of illumination images in which a heat-sealed object is separately illuminated from a plurality of angles, and the visualization image is generated. Since the object is determined based on the form of the heat-sealed portion, the heat-sealed portion can be accurately inspected.

It is a schematic diagram which shows the outline structure example of the heat seal inspection system which concerns on embodiment of this invention. It is a block diagram which shows an example of the outline structure of the inspection apparatus of FIG. It is a top view which shows the outline of the bottom sealing apparatus of FIG. It is a schematic diagram which shows an example of the structure of the bottom sealing apparatus of FIG. It is a schematic diagram which shows an example of the structure of the bottom sealing apparatus of FIG. It is a top view which shows the outline of the side seal apparatus of FIG. It is a schematic diagram which shows an example of the structure of the side seal apparatus of FIG. It is a schematic diagram which shows an example of the structure of the side seal apparatus of FIG. It is a side view schematically showing the arrangement of a photographing apparatus and a lighting apparatus. It is a top view schematically showing the arrangement of a photographing device and a lighting device. It is a schematic diagram which shows an example of the position of a seal with respect to a bag. It is a flowchart which shows the operation example of photography in an inspection apparatus. It is a schematic diagram which shows an example of the range to be photographed. It is a schematic diagram which shows an example of the image taken by a ring illuminator. It is a flowchart which shows the operation example of the inspection in the inspection apparatus. It is a schematic diagram which shows an example of a composite image. It is a schematic diagram which shows an example of the difference image. It is a schematic diagram which shows an example of the inspection value. It is a schematic diagram which shows an example of the inspection value.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The embodiment described below is an embodiment when the present invention is applied to a heat seal inspection system.

[1. Outline of configuration and function of heat seal inspection system 1]
(1.1 Configuration and function of heat seal inspection system 1)
First, the configuration and outline function of the heat seal inspection system according to the embodiment of the present invention will be described with reference to FIG.

FIG. 1 is a schematic diagram showing a schematic configuration example of a heat seal inspection system according to an embodiment of the present invention.

As shown in FIG. 1, the heat seal inspection system 1 includes a supply device 3 for unwinding the sheet S from a roll, and a cutting device 5 for cutting the sheet S into a portion to be a front surface and a portion to be a back surface of an object. An inspection device 10 for inspecting a heat-sealed object, a bottom-sealing device 20 for heat-sealing the bottom portion of the object, a side-sealing device 30 for heat-sealing both side portions of the object, and a heat seal. It includes a photographing device 40 for photographing the object, and a lighting device 50 for illuminating the heat-sealed object. Here, the sheet S is configured to include a heat-sealable thermoplastic resin film.

The heat seal inspection system 1 may include a heat seal control device (not shown) that controls a supply device 3, a cutting device 5, a bottom seal device 20, and a side seal device 30.

The sheet S may be laminated with a light-shielding film, a gas barrier film, a fragrance-retaining film, an impact-resistant film, a piercing-resistant film, or the like. A pattern or the like for a product is printed on the sheet S. The object is a container for packaging such as a retort pouch, a standing pouch, and a pouch with a spout. Further, the object may be a container such as PTP (Press Through Package) in which a solid substance such as a drug tablet is housed in a recess formed in a transparent resin sheet and sealed with a lid material such as aluminum foil.

The inspection device 10 acquires various data from the supply device 3, the bottom seal device 20, the side seal device 30, and the like.

The bottom sealing device 20 heat-seals to form the bottom portion of the object after the bottom material is supplied between the front surface portion and the back surface portion.

The side sealing device 30 heat-seals to form both side portions of the object after the bottom portion of the object is formed by the bottom sealing device 20. A plurality of side seal devices 30 are arranged in the transport direction of the sheet S. In order to increase the strength of the heat seal, each side seal device 30 may heat seal the same portion on the sheet S by controlling the transfer pitch.

The photographing device 40 photographs an object heat-sealed by the bottom sealing device 20 and the side sealing device 30. The photographing device 40 is connected to the inspection device 10 to control the timing of photographing, the transfer of captured image data, and the like.

The lighting device 50 illuminates the object for photographing the object. The lighting device 50 is connected to the inspection device 10 to control the timing of shooting the lighting and the like.

The supply device 3, the cutting device 5, the bottom sealing device 20, and the side sealing device 30 form a bag making system. The printed roll-shaped sheet S is set in the product loading section, the supply device 3 unwinds, and the cutting device 5 cuts in half in the width direction. One of the cut pieces is transported so as to be on the front side and the other side is on the back side. The bottom sealing device 20 heat-seals the bottom portion of the bag, and the side sealing device 30 then seals the left and right sides of the bag. After being inspected by the inspection device 10, the sheet S is punched out to manufacture a bag as an object.

(1.2 Configuration and function of inspection device 10)
Next, the configuration and function of the inspection device 10 will be described with reference to FIG.

FIG. 2 is a block diagram showing an example of a schematic configuration of the inspection device 10.

As shown in FIG. 2, the inspection device 10 which is a computer has a control unit 11 for controlling the inspection device 10, a storage unit 12 for storing data, a communication unit 13 for communicating with the bottom seal device 20 and the like, and information. It includes an output unit 14 for displaying on the screen and an operation unit 15 for receiving input.

The control unit 11 has, for example, a CPU (Central Processing Unit), a ROM (Read Only Memory), and a RAM (Random Access Memory). The control unit 11 reads and executes various control programs stored in the ROM and the RAM by the CPU. The control unit 11 controls each unit such as the storage unit 12 of the inspection device 10. The control unit 11 may read and execute the recording medium or the like in which these programs are stored.

The storage unit 12 is composed of, for example, a hard disk drive, a silicon disk, or the like. The storage unit 12 stores data such as an allowable range of distance between heat-sealed members, an allowable range of heat-sealed member temperature, and an allowable range of temperature of an object immediately after heat-sealing.

Further, various programs such as an operating system and a server program may be stored in the storage unit 12. The various programs may be acquired from another server or the like via a network, or may be recorded on a recording medium and read via a drive device.

The communication unit 13 controls communication with the bottom seal device 20, the side seal device 30, and the like. The communication unit 13 mainly acquires data from each sensor installed in the bottom seal device 20 and the side seal device 30. The communication unit 13 may be connected to the network. Further, the communication unit 13 may output information for controlling the temperature of the heaters of the bottom seal device 20 and the side seal device 30.

The output unit 14 is composed of, for example, a liquid crystal display element, an EL (Electro Luminescence) element, or the like.

The operation unit 15 is composed of, for example, a keyboard, a mouse, and the like.

(1.3 Configuration and function of bottom sealing device 20)
Next, the configuration and function of the bottom sealing device 20 will be described with reference to FIGS. 3 to 4B.

FIG. 3 is a plan view showing an outline of the bottom sealing device 20. 4A and 4B are schematic views showing an example of the structure of the bottom sealing device 20.

As shown in FIGS. 3, 4A and 4B, the bottom seal device 20 heat-seals the sheet S in which the front surface portion and the back surface portion overlap each other (an example of a heat seal member). It also has a heat seal support portion 22 that supports the bottom seal mold 21, a drive portion 23 that drives the heat seal support portion 22 so as to sandwich the sheet S, and a guide bar 24.

As shown in FIGS. 4A and 4B, the bottom seal mold 21 includes an upper bottom seal mold 21a (an example of a first or second heat seal member) and a lower bottom seal mold 21b (an example of a first or second heat seal member) so as to sandwich the sheet S. It has an example of a first or second heat seal member).

As shown in FIG. 3, each bottom seal die 21a, 21b has a semi-circular counterbore processing portion for forming the bottom portion of the object. The counterbore-processed portion of the upper bottom seal mold 21a and the counterbore-processed portion of the lower bottom seal mold 21b are arranged so as to engage with each other when the sheet S is sandwiched by the drive unit 23. Each bottom seal mold 21a, 21b has a heater.

As shown in FIG. 3, the bottom sealing device 20 has bottom sealing dies 21 on both sides of the conveyed sheet S in the width direction, and for example, three counterbore processing portions are arranged in the conveying direction. In order to increase the strength of the heat seal, each counterbore machined portion may heat seal the same portion on the sheet S by controlling the transfer pitch. The number of counterbored portions is not limited to three, and may be further reduced or increased. Further, the number of the bottom sealing devices 20 is not limited to one, and a plurality of bottom sealing devices 20 may be provided in the transport direction.

Teflon (registered trademark) tape having uneven eyes on the surface of the upper bottom seal mold 21a and the lower bottom seal mold 21b to heat seal the sheet S in order to prevent the bottom seal mold 21 and the sheet S from adhering to each other. Resin such as is pasted.

The heat seal support portion 22 has an upper heat seal support portion 22a and a lower heat seal support portion 22b. The upper heat seal support portion 22a supports the upper bottom seal mold 21a via a heat insulating material. The lower heat seal support portion 22b supports the lower bottom seal mold 21b via a heat insulating material.

The drive unit 23 is an air cylinder, an electric cylinder, or the like. As shown in FIGS. 4A and 4B, the drive unit 23 drives the upper heat seal support unit 22a downward in the drawing, sandwiches the sheet S, and applies a predetermined pressure. The upper heat seal support portion 22a moves along the guide bar 24 while the spring 24a is contracted by the drive portion 23. When the drive of the drive unit 23 is released, the restoring force of the spring 24a causes the upper heat seal support portion 22a to move along the guide bar 24 and return to its original position.

(1.4 Configuration and function of side seal device 30)
Next, the configuration and function of the side seal device 30 will be described with reference to FIGS. 5 to 6B. The configuration and function different from the bottom sealing device 20 will be mainly described.

FIG. 5 is a plan view showing an outline of the side seal device 30. 6A and 6B are schematic views showing an example of the structure of the side seal device 30.

As shown in FIGS. 5, 6A and 6B, the side seal device 30 includes a side seal mold 31 (an example of a heat seal member) forming a heat seal portion on the side of the object and a side seal mold 31. It has a heat seal support portion 32 for supporting, a drive portion 33 for driving the heat seal support portion 32 so as to sandwich the sheet S, and a guide bar 34.

As shown in FIGS. 6A and 6B, the side seal mold 31 includes an upper side seal mold 31a (an example of a first or second heat seal member) and a lower side seal mold 31b (an example of a first or second heat seal member) so as to sandwich the sheet S. It has an example of a first or second heat seal member). Each side seal mold 31a, 31b has a heater.

On the surface of the upper side seal mold 31a and the lower side seal mold 31b where the sheet S is heat-sealed, a resin such as Teflon tape having uneven eyes is applied to prevent the side seal mold 31 and the sheet S from adhering to each other. , Is pasted.

The heat seal support portion 32 has an upper heat seal support portion 32a and a lower heat seal support portion 32b. The upper heat seal support portion 32a supports the upper side seal mold 31a via a heat insulating material. The lower heat seal support portion 32b supports the lower side seal mold 31b via a heat insulating material.

The drive unit 33 is an air cylinder, an electric cylinder, or the like, like the drive unit 23. As shown in FIGS. 6A and 6B, the drive unit 33 drives the upper heat seal support unit 32a downward in the drawing, sandwiches the sheet S, and applies a predetermined pressure. The upper heat seal support portion 32a moves along the guide bar 34 while the spring 34a is contracted by the drive portion 33. When the drive of the drive unit 33 is released, the restoring force of the spring 34a causes the upper heat seal support unit 32a to move along the guide bar 34 and return to its original position.

(1.5 Configuration of shooting device and lighting device)
Next, the configurations of the photographing device and the lighting device will be described with reference to FIGS. 7 and 8.

FIG. 7 is a side view schematically showing the arrangement of the photographing device and the lighting device. FIG. 8 is a top view schematically showing the arrangement of the photographing device and the lighting device.

The photographing device 40 is a digital camera having an image pickup element such as a CCD (Charge Coupled Device) image sensor or a CMOS (Complementary Metal Oxide Semiconductor) image sensor. The photographing device 40 captures an image of a predetermined area in 2D.

As shown in FIGS. 7 and 8, the illuminating device 50 includes a first bar illuminator 51, a second bar illuminator 52, a third bar illuminator 53, a fourth bar illuminator 54, and a ring illuminator. 55 and. Each illuminator of the illuminating device 50 is a light such as a fluorescent lamp, an incandescent lamp, and LED (Light Emitting Diode) illumination.

As shown in FIGS. 7 and 8, the lighting device 50 is installed between the heat-sealed sheet S and the photographing device 40. The first bar illuminator 51, the second bar illuminator 52, the third bar illuminator 53, and the fourth bar illuminator 54 are arranged so as to surround the photographing device 40 from all sides, and each has a different angle. Illuminate the heat-sealed object from. The first bar illuminator 51, the second bar illuminator 52, the third bar illuminator 53, and the fourth bar illuminator 54 are rod-shaped lights. Each bar illuminator illuminates an object from a specific direction (specific angle).

The ring illuminator 55 has a ring-shaped shape so as to surround the photographing device 40, and illuminates an object that is heat-sealed at the same time from a plurality of angles. Since it has a ring shape so as to surround the photographing device 40, the illumination directions of the ring illuminator 55 are the illumination direction of the first bar illuminator 51, the illumination direction of the second bar illuminator 52, and the third bar illuminator. The illumination direction of 53 and the illumination direction of the fourth bar illuminator 54 will be included. The ring illuminator 55 is used for diffuse illuminating. The photographing device 40 captures an image in which the unevenness of the sticker is inconspicuous and the pattern and characters are captured by the photographing using the ring illuminator 55 of the diffusion illumination.

(1.6 Composition of inspection object)
Next, the configuration of the object to be inspected will be described with reference to FIG.

FIG. 9 is a schematic view showing an example of the position of the seal with respect to the bag.

As shown in FIG. 9, the object c to be inspected includes a side seal portion ha (an example of a heat-sealed heat-sealed portion of the object) and a bottom seal portion hb (a heat-sealed heat-sealed portion of the object). One example) and.

When heat-sealed by the bottom-seal mold 21 and the side-seal mold 31, the eyes of the Teflon tape are transferred to the surface of the heat-seal portion of the object c, and unevenness is generated.

[2. Inspection system operation]
Next, the operation of the inspection system according to one embodiment of the present invention will be described with reference to FIGS. 2 to 8.

(2.1 Creation of object)
First, the creation of an object will be described.

A bottom material is supplied to the sheet S cut by the cutting device 5, and the bottom sealing device 20 heat-seals the bottom portion of the object.

Next, the side seal device 30 heat seals both side portions of the object.

Next, a cooling device (not shown) cools the heat-sealed object.

Next, the photographing device 40 photographs the heat-sealed object, and the inspection device 10 inspects the heat-sealed object based on the image.

Next, a punching device (not shown) punches an object from the sheet S.

Next, based on the inspection result of the inspection device 10, the defective object and the non-defective object are separated.

(2.2 Example of operation of lighting and shooting of inspection system)
Next, an operation example of lighting and photographing of the inspection system will be described with reference to FIGS. 10 to 12.

FIG. 10 is a flowchart showing an operation example of photographing in the inspection device. FIG. 11 is a schematic diagram showing an example of a range to be photographed. FIG. 12 is a schematic diagram showing an example of an image taken by a ring illuminator.

As shown in FIG. 10, the inspection device 10 turns on the first bar illuminator 51 (step S1). When the sheet S heat-sealed and cooled by the side seal device 30 is carried under the photographing device 40, specifically, the control unit 11 of the inspection device 10 lights the first bar illuminator 51. Then, the sheet S is illuminated from a certain angle.

Next, the inspection device 10 takes a first image (step S2). Specifically, the control unit 11 causes the photographing device 40 to photograph and acquires the image data of the first image (an example of the illumination image) of the inspection target illuminated from the direction of the first bar illuminator 51. Here, the photographing range of the heat-sealed sheet S is set to a portion necessary for determining the suitability of the heat-sealing, as shown by a dotted line in FIG. 11, for example.

As described above, the inspection device 10 functions as an example of an image acquisition means for acquiring a plurality of illuminated images in which a heat-sealed object is separately illuminated from a plurality of angles.

Next, the inspection device 10 turns off the first bar illuminator 51 (step S3). Specifically, the control unit 11 turns off the first bar illuminator 51.

Next, the inspection device 10 turns on the second bar illuminator 52 (step S4). Specifically, the control unit 11 lights the second bar illuminator 52 and illuminates the sheet S from an angle different from the illumination direction of the first bar illuminator 51 (for example, an angle different by 90 °).

Next, the inspection device 10 takes a second image (step S5). Specifically, the control unit 11 causes the photographing device 40 to photograph and acquires the image data of the second image (an example of the illumination image) of the inspection target illuminated from the direction of the second bar illuminator 52.

As described above, the inspection device 10 functions as an example of an image acquisition means for acquiring a plurality of illuminated images in which a heat-sealed object is separately illuminated from a plurality of angles.

Next, the inspection device 10 turns off the second bar illuminator 52 (step S6). Specifically, the control unit 11 turns off the second bar illuminator 52.

Next, the inspection device 10 turns on the third bar illuminator 53 (step S7). Specifically, the control unit 11 lights the first bar illuminator 53 and illuminates the sheet S from an angle different from the illumination direction of the first bar illuminator 51 and the second bar illuminator 52.

Next, the inspection device 10 takes a third image (step S8). Specifically, the control unit 11 causes the photographing device 40 to photograph and acquires the image data of the third image (an example of the illumination image) of the inspection target illuminated from the direction of the third bar illuminator 53.

As described above, the inspection device 10 functions as an example of an image acquisition means for acquiring a plurality of illuminated images in which a heat-sealed object is separately illuminated from a plurality of angles.

Next, the inspection device 10 turns off the third bar illuminator 53 (step S9). Specifically, the control unit 11 turns off the third bar illuminator 53.

Next, the inspection device 10 turns on the fourth bar illuminator 54 (step S10). Specifically, the control unit 11 lights the fourth bar illuminator 52, and the sheet S is lit from an angle different from the illumination direction of the first bar illuminator 51, the second bar illuminator 52, and the third bar illuminator 53. Illuminate.

Next, the inspection device 10 takes a fourth image (step S11). Specifically, the control unit 11 causes the photographing device 40 to photograph and acquires the image data of the fourth image (an example of the illumination image) of the inspection target illuminated from the direction of the fourth bar illuminator 54.

As described above, the inspection device 10 functions as an example of an image acquisition means for acquiring a plurality of illuminated images in which a heat-sealed object is separately illuminated from a plurality of angles.

Next, the inspection device 10 turns off the fourth bar illuminator 54 (step S12). Specifically, the control unit 11 turns off the fourth bar illuminator 54.

Next, the inspection device 10 turns on the ring illuminator 55 (step S13). Specifically, the control unit 11 lights the ring illuminator 55 and illuminates the sheet S from the surroundings. By illuminating from the surroundings, the unevenness of the surface caused by the heat seal is prevented from being reflected on the photographing apparatus 40 as much as possible. Instead of the ring illuminator 55, the inspection device 10 may simultaneously turn on the first bar illuminator 51, the second bar illuminator 52, the third bar illuminator 53, and the fourth bar illuminator 54. good.

Next, the inspection device 10 takes a fifth image (step S14). Specifically, the control unit 11 causes the photographing device 40 to photograph and acquires the image data of the fifth image (an example of a polygonal illumination image) to be inspected simultaneously illuminated from a plurality of angles by the ring illuminator 55. .. As shown in FIG. 12, only the pattern including the registration mark is photographed as the fifth image. The fifth image is an image taken by a ring illuminator 55, which is an example of diffuse lighting. The ring illuminator 55 makes it easier to capture the printed portion printed on the object in the fifth image.

As described above, the inspection device 10 functions as an example of the image acquisition means for acquiring the polygonal illumination image illuminated at the same time from a plurality of angles.

Next, the inspection device 10 turns off the ring illuminator 55 (step S15). Specifically, the control unit 11 turns off the ring illuminator 55.

(2.3 Example of inspection operation of inspection system)
Next, an operation example of the inspection of the inspection system will be described with reference to FIGS. 13 to 17.

FIG. 13 is a flowchart showing an operation example of inspection in the inspection device. FIG. 14 is a schematic diagram showing an example of a composite image. FIG. 15 is a schematic diagram showing an example of a difference image. 16 and 17 are schematic views showing an example of inspection values.

As shown in FIG. 13, the inspection device 10 generates a composite image (step S20). Specifically, the control unit 11 uses the photometric stereo method (illumination difference stereo method) from the first image to the fourth image taken by illumination from different angles, and the bottom seal mold 21 and the side seal metal. By heat sealing with the mold 31, a composite image (an example of a visualized image) is generated, which visualizes the unevenness of the surface of the object generated by transferring the eyes of the Teflon tape of the mold. The control unit 11 calculates information in the normal direction of the surface from the illumination direction of each bar illuminator and the intensity of light obtained from the photographing device 40, and generates a composite image. As shown in FIG. 14, a composite image showing clear surface irregularities is generated together with the printed pattern. In the composite image, the unevenness on the surface of the object is emphasized and conspicuous, and the heat-sealed portion is clearly visualized.

As described above, the inspection device 10 functions as an example of the visualization image generation means for generating a visualization image that visualizes the heat-sealed heat-sealed portion of the object from the plurality of illumination images.

Next, the inspection device 10 performs shading correction on the fifth image (step S21). Specifically, the control unit 11 sets the average gradation to be the same as that of the composite image so as to eliminate uneven illumination or uneven brightness with respect to the fifth image taken under the illumination of the ring illuminator 55. Performs image processing for shading correction. Even if the sheet S is distorted due to the heat of the heat seal or the like, the shading correction reduces the unevenness of the illumination and makes it easier to clarify the printed portion of the fifth image (an example of the printed portion of the polygonal illuminated image).

Next, the inspection device 10 performs a contour extraction process (step S22). Specifically, the control unit 11 performs differential processing on the image-processed fifth image of shading correction to extract the outline of the pattern printed on the sheet S. Note that the control unit 11 may remove noise before extracting the contour.

Next, the inspection device 10 performs an expansion process (step S23). Specifically, in step S22, the control unit 11 performs expansion processing on the contour-extracted image, and the control unit 11 performs expansion processing on the pixels having a predetermined brightness or higher. For example, the control unit 11 sets the value of the pixel in the vicinity of 4 or the vicinity of 6 of the pixel specified by scanning to the brightness of a predetermined value or more. Further, the control unit 11 may perform the expansion process a plurality of times. It should be noted that this expansion process may be omitted, and this expansion process is an image process for more reliably removing the pattern portion in the next difference process.

Next, the inspection device 10 performs the difference processing (step S24). Specifically, the control unit 11 generates a difference image between the composite image generated in step S20 and the image expanded in step S23. By subtracting the image obtained by shading, contouring, and expanding the fifth image shown in FIG. 12 from the composite image shown in FIG. 14, a difference image as shown in FIG. 15 is generated. The composite image is corrected by removing the printed portion from the composite image. The difference image between the contour image obtained by extracting the contour from the polygonal illumination image and the visualization image is an example of the corrected visualization image. This difference image is an example of an image calculated by performing expansion processing on a contour image and then performing difference processing with a visualized image. The control unit 11 may perform the difference processing without performing the expansion processing.

As described above, the inspection device 10 functions as an example of the image correction means for correcting the visualized image by the polygonal illumination image.

Next, the inspection device 10 determines the object (step S25). Specifically, the control unit 11 extracts a feature amount from the difference image generated in step S24, determines whether or not a predetermined condition is satisfied, and inspects whether or not the heat seal is properly performed. do.

For example, the control unit 11 determines whether or not the heat-sealed portion is heat-sealed at a predetermined position from the positional relationship between the heat-sealed portion and the pattern portion photographed by diffuse lighting (an example of the form of the heat-sealed portion). do.

As shown in FIG. 16, as an example of the heat-sealed portion, there is an intersection point (x1, y1) between the side-sealed portion and the bottom-sealed portion (an example of the form of the heat-sealed portion). Be done. As an example of the heat-sealed portion, a boundary line between the side-sealed portion and the bottom-sealed portion (an example of the form of the heat-sealed portion) may be used. The boundary line extends from the intersecting points (x1, y1) to the bottom of the bottom-sealed portion along the straight line L1. The intersection of the side-sealed portion and the bottom-sealed portion and the boundary line between the side-sealed portion and the bottom-sealed portion are examples of the characteristic points of the heat-sealed portion.

As shown in FIG. 16, as the pattern portion, the position (x2, y2) (center of gravity, corner point, etc.) of the register mark (position measurement mark) can be mentioned.

The control unit 11 calculates the intersection of the side seal and the bottom seal by image processing. For example, the control unit 11 calculates the straight line L1 from the side seal portion of the difference image. The control unit 11 calculates the straight line L2 from the bottom seal portion. The control unit 11 calculates an intersection (x1, y1) from the straight line L1 and the straight line L2. The intersections (x1, y1) calculated from the straight lines L1 and L2 and the straight lines L1 and L2 are examples of the form of the heat-sealed portion and the characteristic points of the heat-sealed portion.

The control unit 11 calculates the position (x2, y2) of the registration mark from the registration mark in the pattern such as the fifth image and the image obtained by shading-correcting the fifth image. The control unit 11 has a predetermined range of intersections (x1, y1) with the position of the registration mark (x2, y2) as a base point (a circle having a predetermined radius centered on the end point of a vector having a predetermined length in a predetermined direction). Determine if it is inside. If the positional relationship between the intersection (x1, y1) and the registration mark (an example of the form of the heat-sealed portion) is within a predetermined range, it is considered as a non-defective product. As shown in FIG. 17, instead of the cash register mark, a printed dragonfly may be used, as long as it is a feature point of the printed pattern.

In the method of calculating the seal position, CAD data of the seal mold is registered in advance, matching is performed with the seal mold of the CAD data from the captured image, and the intersection of the side seal and the bottom seal is calculated by image processing. For example, the mold shape is extracted from the CAD data in advance and stored as a shape model. The control unit 11 calculates the intersection of the side seal and the bottom seal by performing matching etc. by image processing on the image actually taken of the heat seal part of the product and fitting the shape model on the taken image. You may. As a fitting, the part closest to the shape model is specified from the actual image, and the shape model is overlaid on the image.

Further, as shown in FIG. 16, the control unit 11 may calculate the width w1 of the side seal (an example of the form of the heat seal portion) and determine whether or not the width is within a predetermined width.

Further, as shown in FIG. 17, the control unit 11 calculates the thickness d1 (an example of the form of the heat-sealed portion) of the bottom heat-sealed portion at the bottom of the bottom-sealed portion, and has a predetermined thickness. It may be determined whether or not it is inside. The point for measuring the thickness d1 of the bottom heat-sealed portion such as the bottom of the bottom-sealed portion is an example of the characteristic points of the heat-sealed portion.

Further, as shown in FIG. 17, the control unit 11 may calculate the distance w2 between the side heat seals (an example of the form of the heat seal portion) and determine whether or not the distance is within a predetermined distance. The point for measuring the distance w2 between the side heat seals is an example of the characteristic points of the heat seal portion.

Further, as shown in FIG. 17, the control unit 11 has a vector (in the form of a heat seal portion) of a specific position of the bottom seal (for example, the position p1 of the bottom) and a feature point of the pattern (position p2 of the print dragonfly). An example) may be calculated to determine whether or not the distance is within a predetermined distance. The specific position of the bottom seal is an example of the characteristic points of the heat seal portion.

Further, is the control unit 11 properly heat-sealed by the darkness of the heat-sealed portion (an example of the form of the heat-sealed portion) due to the depth of the unevenness of the surface caused by the heat-sealing. It may be determined whether or not.

As described above, the inspection device 10 functions as an example of a determination means for determining whether or not the object is properly heat-sealed based on the form of the heat-sealed portion of the visualized image. The inspection device 10 functions as an example of a determination means for determining whether or not the object is properly heat-sealed based on the form of the heat-sealed portion of the corrected visualization image. The inspection device 10 functions as an example of a determination means for determining whether or not the object is properly heat-sealed based on the positional relationship between the heat-sealed portion of the visualized image and the printed portion printed on the object. do. The inspection device 10 functions as an example of a determination means for determining whether or not the object is properly heat-sealed based on the positional relationship between the feature points of the heat-sealed portion and the printed portion.

As described above, according to the present embodiment, a visualization image in which the heat-sealed heat-sealed portion of the object is emphasized is generated from a plurality of illumination images in which the heat-sealed object is separately illuminated from a plurality of angles. Since the object is determined based on the form of the heat-sealed portion of the visualized image, the heat-sealed portion can be accurately inspected.

In addition, whether or not the object is properly heat-sealed based on the form of the heat-sealed portion of the corrected visualization image by acquiring the polygonal illumination image illuminated at the same time from multiple angles and correcting the visualization image by the polygonal illumination image. In the case of determining whether or not, even if the pattern of the object is applied to the heat-sealed portion, it can be detected more accurately and the accuracy of the inspection is further improved.

Further, when the corrected visualization image is a difference image between the contour image obtained by extracting the contour from the polygonal illumination image and the visualization image, even if the pattern of the object is applied to the heat seal portion, it can be detected more accurately. The accuracy of inspection is improved.

When the difference image is calculated by performing the expansion processing on the contour image and then performing the difference processing with the visualized image, the printed part is subtracted a lot, so that the printed part such as the pattern is surely removed. It can be detected more accurately and the accuracy of inspection is improved.

When determining whether or not the object is properly heat-sealed based on the positional relationship between the heat-sealed portion of the visualized image and the printed portion printed on the object, the position of the heat-seal due to a transfer error or the like. When a deviation occurs, it can be detected more accurately and the inspection accuracy is further improved.

When calculating the feature points of the heat-sealed portion of the visualized image and determining whether or not the object is properly heat-sealed based on the positional relationship between the feature points of the heat-sealed portion and the printed portion, the positional relationship with the feature points. Therefore, the determination can be made more accurately, and the accuracy of the inspection is further improved.

When a polygonal illumination image illuminated simultaneously from multiple angles is acquired and the printed portion printed on the object is the print portion of the polygonal illumination image, the position of the printed portion can be detected more accurately, and the inspection accuracy is improved. Improve more.

1: Heat seal inspection system 10: Inspection device (heat seal inspection device)
40: Photographing device 50: Lighting device 51: 1st bar illuminating device 52: 2nd bar illuminating device 53: 3rd bar illuminating device 54: 4th bar illuminating device 55: Ring illuminating device

Claims (8)

An image acquisition means for acquiring a plurality of illumination images in which a heat-sealed object is separately illuminated by each of the plurality of illuminators arranged on four sides of the photographing area of the object.
A visualization image generation means for generating a visualization image that visualizes a heat-sealed portion of the object from the plurality of illumination images.
A determination means for determining whether or not the object is properly heat-sealed based on the form of the heat-sealed portion of the visualized image.
Equipped with
The heat is characterized in that the determination means determines whether or not the object is properly heat-sealed based on the positional relationship between the heat-sealed portion of the visualized image and the printed portion printed on the object. Seal inspection device. In the heat seal inspection apparatus according to claim 1 ,
Further provided with a feature point calculation means for calculating the feature points of the heat-sealed portion of the visualization image is provided.
The determination means is based on the positional relationship between the feature points of the heat seal portion and the print portion.
A heat-sealing inspection device for determining whether or not the object is properly heat-sealed. In the heat seal inspection apparatus according to claim 1 or 2 .
The image acquisition means acquires a polygonal illumination image illuminated at the same time from a plurality of angles.
A heat seal inspection device, characterized in that the printed portion printed on the object is the printed portion of the polygonal illumination image. The heat seal inspection device according to any one of claims 1 to 3 .
The image acquisition means acquires a polygonal illumination image illuminated at the same time from the surroundings, and obtains the polygonal illumination image.
Further provided with an image correction means for correcting the visualized image by the polygonal illumination image,
A heat seal inspection device, wherein the determination means determines whether or not the object is properly heat-sealed based on the form of the heat-seal portion of the corrected visualization image. In the heat seal inspection apparatus according to claim 4 ,
A heat seal inspection device, wherein the corrected visualized image is a difference image between a contour image extracted from the polygonal illumination image and the visualized image. In the heat seal inspection apparatus according to claim 5 ,
A heat seal inspection device, characterized in that the difference image is calculated by performing expansion processing on the contour image and then performing difference processing with the visualization image. An image acquisition step in which the image acquisition means acquires a plurality of illumination images in which the heat-sealed object is separately illuminated by each of the plurality of illuminators arranged on the four sides of the photographing area of the object. ,
A visualization image generation step in which the visualization image generation means generates a visualization image in which the heat-sealed heat-sealed portion of the object is emphasized from the plurality of illumination images.
A determination step in which the determination means determines whether or not the object is properly heat-sealed based on the form of the heat-sealed portion of the visualization image.
Including
The heat is characterized in that the determination means determines whether or not the object is properly heat-sealed based on the positional relationship between the heat-sealed portion of the visualized image and the printed portion printed on the object. Seal inspection method. Computer,
An image acquisition means for acquiring a plurality of illumination images in which a heat-sealed object is separately illuminated by each of the plurality of illuminators arranged on four sides of the photographing area of the object.
A visualization image generation means for generating a visualization image in which a heat-sealed heat-sealed portion of the object is emphasized from the plurality of illumination images, and a visualization image generation means.
Based on the form of the heat-sealed portion of the visualized image, the object is made to function as a determination means for determining whether or not the object is properly heat-sealed .
The determination means is characterized in that it determines whether or not the object is properly heat-sealed based on the positional relationship between the heat-sealed portion of the visualized image and the printed portion printed on the object. A program for heat seal inspection equipment.

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