JP2004294209A - Can inspection equipment - Google Patents

Abstract

An object of the present invention is to provide a can inspection apparatus capable of reliably determining the quality of a flange portion of a can irrespective of a defect form and of reliably removing a can with a defective flange portion from a production line.
A can inspection apparatus (6) for inspecting a can (1) having a bottomed cylindrical shape and having a flange portion at an opening, comprising: a turntable (211) for rotatably holding the can (1) around a can axis; A first detection unit 215 provided above the opening of the can 1, irradiating the irradiation light downward, detecting the presence or absence of light reflected from the flange, and detecting the outer diameter of the flange; A control unit 216 having a determination unit for determining the quality of the can 1 based on the detection result of the first detection unit 215.
[Selection diagram] Fig. 1

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a can inspection apparatus, and more particularly to a can inspection apparatus suitable for inspecting an outer diameter of a flange portion of a can.
[0002]
[Prior art]
For example, in the case of manufacturing a two-piece can (soft can), after manufacturing a bottomed cylindrical can having an open end, the opening is gradually reduced in diameter to form a neck portion. Is formed at the open end thereof with a flange portion extending radially outward. By forming the flange portion in this manner, in the operation of attaching the can lid to the opening of the can, the periphery of the can lid can be tightly wound together with the flange portion, and the can lid can be securely fixed to the can body. , The inside of the can can be sealed.
[0003]
By the way, in the process of forming the flange portion of the can described above, various factors such as the fact that the thickness of the can is very thin and easily deformed, or the failure such as breakage of the mold itself for forming the flange portion has occurred. As a result, a molding defect such as distortion of the flange portion or shortening or lengthening in the radial direction may occur. In this case, the work of winding the can lid around the can is not performed reliably, and the mounting strength of the can lid is insufficient, causing leakage of the contents, or in some cases, the canning itself cannot be performed. In some cases, it may not be attached, or the front end of the flange portion may come into contact with the lower top portion of the fastening portion of the can lid, and the fastening portion may be rubbed against the front end of the flange portion and cut off.
[0004]
For this reason, it is necessary to avoid the occurrence of defective molding of the flange portion. In particular, when a problem such as breakage occurs in the mold itself for molding the flange portion, all the cans molded by this mold are used. Since they have substantially the same defect form, it is desirable that the occurrence of this defect can be identified as early as possible.
[0005]
As means for solving such a problem, for example, there is an apparatus disclosed in Patent Document 1. With this device, inspection and selection can be performed only when the radial length of the flange portion, which is one of the above-described failure types of the flange portion, is short. There was a problem that can not be. For this reason, it was not possible to detect the occurrence of the above-mentioned other defective forms at an early stage, and a large number of defective cans were manufactured, and these cans were conveyed to the next step as non-defective products. As a result, a large number of defective cans are subjected to various processes and the like, resulting in waste of man-hours and man-hours for removing the defective cans, resulting in a significant increase in manufacturing man-hours. .
[0006]
[Patent Document 1]
Japanese Patent No. 2950066
[0007]
[Problems to be solved by the invention]
The present invention has been made in view of the above-described circumstances, and it is possible to reliably determine the quality of a flange portion of a can regardless of a defect form, and to reliably remove a can with a defective flange portion from a production line. It is an object of the present invention to provide an inspection apparatus.
[0008]
[Means for Solving the Problems]
In order to solve the above problems and achieve such an object, the present invention proposes the following means.
The invention according to claim 1 is a can inspection apparatus for inspecting a can that is formed in a cylindrical shape with a bottom and has a flange portion at an opening, and irradiates irradiation light substantially parallel to a can axis and the irradiation direction. And detecting means for detecting the presence or absence of the flange portion, and a control section having a judging section for judging the quality of the can based on the detection result of the detecting means.
[0009]
According to the inspection apparatus for a can according to the present invention, since the detection means for detecting the presence or absence of the flange of the can in the irradiation direction is provided, it is necessary to inspect whether or not the outer diameter of the flange is within the reference range. This can be performed reliably, and an increase in the load required for this processing can be suppressed to a minimum. Therefore, even when this inspection apparatus is provided on a high-speed production line, the outer diameter of the flange portion can be reliably inspected. Furthermore, in this inspection apparatus, in a configuration in which a switching mechanism for switching the transport destination of the can based on the determination result is provided, if the can is a good product, the process proceeds to the next step. The transfer destination can be switched so as to discharge, and appropriate pass / fail sorting can be automatically performed with high efficiency.
[0010]
The invention according to claim 2 is a can inspection apparatus for inspecting an outer diameter of a flange portion of a can having a flange portion at an opening while being formed in a cylindrical shape with a bottom during the can transport, wherein the transport direction of the can A first detection unit and a second detection unit that are disposed apart from each other in a direction intersecting with the can, and the distance between the first detection unit and the second detection unit is determined by a flange portion of the can. When the outer diameter is larger than the reference upper limit value, it is set so as to come into contact with the flange portion.
[0011]
According to the inspection apparatus for a can according to the present invention, when the outer diameter of the flange portion of the transferred can is larger than the reference upper limit, the flange portion comes into contact with the first and second detection portions. Therefore, the transfer of the can having such a flange portion to the next step is avoided. Therefore, when the flange portion and the can lid are subsequently tightened, the tip of the flange portion is prevented from contacting the lower top portion of the tightened portion of the can lid. When the can is transported after passing through all the steps such as lid wrapping and the like, the problem that the lower top portion of the can lid is rubbed against the tip of the flange portion and cut off is reliably avoided.
[0012]
In a can having a flange outer diameter larger than the reference upper limit, the transfer of the can can be stopped because the flange comes into contact with the detection unit. Therefore, for example, in a configuration in which the inspection device is provided on a production line on which a molded can is continuously transferred, when the can comes into contact with the detection unit and the transfer is stopped, the can is Will be stopped. Here, if a defect such as breakage occurs in the mold device itself for molding the flange portion in the opening of the can, the flange portion molded by this mold device has the same defective form for all cans. Will be. Therefore, when the outer diameter of the flange portion of a certain can is larger than the reference upper limit value, there is a high possibility that the same defective form occurs in all cans formed after this can. It is desirable to stop the transfer of the mold and inspect and repair the components on the production line including the mold apparatus. By the way, in the can inspection device according to the present invention, since the transport of the can itself is stopped by the detection unit, such a defective can can be found early and reliably, and high quality control can be performed. The system can be reliably realized, and the occurrence of such defective cans can be minimized.
[0013]
According to a third aspect of the present invention, in the can inspection apparatus according to the first or second aspect, the third detection unit and the third detection unit are disposed on one plane facing the base unit and extend substantially parallel to each other. And a separation distance between the third detection unit and the fourth detection unit is smaller than the outer diameter of the flange of the can and larger than the outer diameter of the opening of the can. And a discharge port for blowing compressed air toward the can to be transferred is formed at a position of the base portion between the third detection portion and the fourth detection portion. It is characterized by having.
[0014]
According to the inspection apparatus for a can according to the present invention, the following operation is achieved. That is, in the case where the outer diameter of the flange portion is equal to or larger than the reference lower limit value, since the flange portion is engaged with the third detection portion and the fourth detection portion, the flange portion resists the force of the compressed air from the outlet. The can is held, and the can can be moved along the extension direction of the detection unit. On the other hand, in the can having an outer diameter of the flange smaller than the reference lower limit, the third and fourth cans are provided. Is not engaged with the detecting portion, the flange portion is disengaged from the third and fourth detecting portions without being able to resist the force of the compressed air from the outlet, and the can is removed from the inspection device. Become. Therefore, in a configuration in which this inspection device is arranged on a production line, cans with an outer diameter of the flange portion smaller than the reference lower limit value can be easily and reliably removed from this line.
[0015]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. 1 to 5 show a first embodiment of the present invention.
[0016]
First, a schematic configuration of a can provided for the present inspection apparatus will be described with reference to FIG.
The can 1 has a large-diameter body portion 2, a tapered portion 3 whose diameter gradually decreases from the upper end of the body portion 2, and a flange portion 4 extending radially outward from the upper end of the tapered portion 3. On the other hand, a lower portion of the large-diameter body portion 2 is provided with a counter sink portion 5 whose diameter gradually decreases downward from the lower end of the body portion 2 and whose bottom portion is recessed upward. . In this configuration, the can 1 is hermetically sealed by winding a can lid (not shown) around the flange portion 4.
[0017]
Next, a schematic configuration of an inspection apparatus that inspects the can 1 configured as described above will be described.
In FIG. 1, the inspection device 6 includes a first detection unit 100 that detects whether the outer diameter of the flange portion 4 of the can 1 is smaller than a reference lower limit, and a flaw or the like on the surface of the can 1 by image processing or the like. An image processing apparatus (not shown) for inspection, and a second detection unit 200 including first detection means 215 for detecting whether the outer diameter of the flange portion 4 of the can 1 is larger than a reference upper limit value. . These first and second detection units 100 and 200 are arranged so that the can 1 reaches the second detection unit 200 after passing through the first detection unit 100. Note that the image processing device of the second detection unit 200 captures an image of the outer surface and inner surface of the can 1 with an imaging unit, performs image processing based on the obtained image data, and processes the outer surface and inner surface of the can 1. Since it is a well-known technique for inspecting the presence or absence of a scratch on the surface, detailed description and illustration thereof are omitted.
[0018]
First, the first detection unit 100 will be described with reference to FIGS.
As shown in FIG. 2, the first detection unit 100 has a starting end connected to an outlet side of a discharge path of a not-shown necker flanger that forms a tapered part 3 and a flange part 4 in an opening of a cylindrical can with a bottom. The rear end of the can 1 is connected to a conveyor (not shown) heading toward the second detection unit 200, and is arranged to extend in the transport direction A of the can 1.
[0019]
The detection unit 100 includes a long base plate 10 facing the opening of the can 1 to be transferred, a first detection plate 20 provided on the surface of the base plate 10 so as to extend in the transfer direction A, and a base plate. A second detection plate 30 disposed on the front surface of the base plate 10 so as to face the first detection plate 20; a box 40 provided on the back surface of the base plate 10 so as to extend in the transfer direction A; Side support mechanism 50 which is provided extending in the transfer direction A to support the body 2 of the can 1, and two lifting cylinders which respectively support the vicinity of both ends of the base plate 10 in the transfer direction A and raise and lower the base plate 10. 60, 61, and the can 1 provided to the detection unit 100 from the discharge path of the necker flanger, which are provided on the starting end side of the transfer direction A of the base plate 10. A supply unit 80 to the inner, provided at the end side of the conveying direction A of the base plate 10, and is configured with a discharge portion 90 for guiding the can 1 to the conveyor (not shown) mainly.
[0020]
The base plate 10 is formed in the shape of a long plate, and is disposed so as to be inclined from the start end on the supply section 80 side disposed on the upper side to the end on the discharge section 90 side disposed on the lower side. The upper end and the lower end of 10 are supported by lifting cylinders 60 and 61, respectively.
An outlet 11 penetrating in the thickness direction over substantially the entire length of the base plate 10 is formed substantially in the center of the base plate 10 in the width direction. Two heat plates 12 and 13 in the form of a scale plate are provided extending parallel to each other. The heat plates 12 and 13 have resistance heating means embedded therein, and can heat the base plate 10 and the detection plates 20 and 30 to about 50 ° C. to keep the temperature.
[0021]
The first detection plate 20 is provided on the surface of the base plate 10 so as to extend substantially in parallel with the direction in which the outlet 11 extends, that is, to extend along the transfer direction A. As shown in FIG. 3 and FIG. 4, the tip of the detection plate 20 on the side of the outlet 11 (hereinafter, referred to as “tip”) has a surface opposite to the surface in contact with the surface of the base plate 10 (hereinafter, “back surface”). ) To a surface (hereinafter, referred to as a “surface”) that abuts the surface of the base plate 10, and is inclined so that the thickness gradually decreases toward the tip of the detection plate 20. A notch is formed in the front surface of the detection plate 20, and a surface of the notch facing the base plate 10 is a third detection surface 21. The third detection surface 21 is substantially parallel to the surface of the base plate 10, and the distance between them is about 1 to 2 mm, so that the flange portion 4 of the can 1 can be stored between them. .
Further, a positioning piece 24 is provided near the first detection plate 20 on the surface of the base plate 10 so as to position the plate 20 in a direction approaching and separating from the outlet 11 side.
[0022]
The second detection plate 30 is configured in the same manner as the first detection plate 20, and at a position where the first detection plate 20 is disposed along the surface of the base plate 10, a line sandwiching the outlet 11 is provided. They are arranged symmetrically.
Also in the detection plate 30, similarly to the first detection plate 20, an inclined surface 33 is formed at the front end on the outlet 11 side, and a notch is formed on the surface of the front end. The facing surface is the fourth detection surface 31. Further, on the surface of the base plate 10, similarly to the first detection plate 20, a positioning piece 34 that can perform positioning of the second detection plate 30 is provided.
[0023]
The distance between the third and fourth detection surfaces 21 and 31 arranged as described above, that is, the distance B between the tips of the first and second detection plates 20 and 30 (see FIG. 4) is The distance is smaller than the outer diameter C of the flange portion 4 and larger than the outer diameter D of the opening of the can 1.
In this configuration, the opening of the can 1 can be inserted between the tips of the first and second detection plates 20 and 30, and the flange 4 of the can 1 can be connected to the surface of the base plate 10 and the third and fourth detection plates. It is housed between the surfaces 21 and 31. Note that the third and fourth detection surfaces 21 and 31 are arranged so as to be located on the same plane facing the surface of the base plate 10 in parallel.
[0024]
As shown in FIG. 3, the box 40 is provided on the back surface of the base plate 10 so as to cover the outlet 11, flows compressed air supplied from a blower (not shown), and sends the compressed air from the outlet 11 to the surface of the base plate 10. It is configured to blow out to the side.
As shown in FIG. 3, the side supporting mechanism 50 includes a plurality of brackets 52 having a substantially L-shaped cross section and provided on the surface of the base plate 10 at predetermined intervals along the transfer direction A, and upper surfaces of the brackets 52. That is, the first side guide 55 is provided on the surface on the side of the outlet 11 along the transfer direction A to support the lower portion of the body 2 of the can 1 to be transferred, and supports the upper portion of the body 2. A second side guide 56, a bottom guide 57 provided on the first side guide 55 to support the bottom of the can 1, and a side support mechanism 50 provided on the surface of the base plate 10 approaching and separating toward the outlet 11. And a positioning piece 300 to be moved.
[0025]
The bottom guide 57 is provided at an upper portion of the first side guide 55 on the surface opposite to the surface facing the surface of the base plate 10. A concave portion 57 a is formed on the upper surface of the bottom guide 57 over the entire length of the guide 57. The concave portion 57a has a shape substantially along the shape of the vicinity of the outer periphery of the bottom of the can 1 when viewed from the side. In this configuration, when the opening surface of the can 1 is brought into contact with the surface of the base plate 10 and the body 2 is placed on the top surfaces of the first and second side guides 56 and 57, the bottom surface of the can 1 and the surface of the recess 57a are formed. Are separated from each other by several mm.
[0026]
Next, the second detection unit 200 will be described with reference to FIGS.
The second detection unit 200 includes a loading mechanism 210 that transports the can 1 conveyed via the conveyor to the detection unit 200 after passing through the first detection unit 100, and the can 1 is rotatable around a can axis. , A driving mechanism 212 that rotationally drives the holding table 211, an unloading mechanism 213 that unloads the can 1 inspected by the detection unit 200 from the detection unit 200, and a terminal end of the loading mechanism 210. A first rotating body 214a and a second rotating body 214b provided at the starting end of the unloading mechanism 213 and having a suction mechanism on a side surface and capable of holding the body 2 of the can 1; 4, a first detecting means 215 for detecting whether or not the outer diameter is larger than a reference upper limit value, an imaging means (not shown) for imaging the outer surface and the inner surface of the can 1, a first detecting means 215 and the imaging By means Based on the results obtained, performs quality determination of the can, and a control unit 216 for controlling the second rotating body 214b.
[0027]
A plurality of holding tables 211 are provided on the outer peripheral surface side of the main body 241 which is formed in a substantially columnar shape and is rotatably supported about the central axis O, with a predetermined gap in the circumferential direction. It is arranged via a projection 242. These holding tables 211 are rotatably supported one by one on the distal end of each projection 242. With this configuration, the holding tables 211 can revolve around the central axis O of the main body 241 while rotating. It has become. The holding table 211 has on its surface suction holes (not shown) for sucking and holding the outer bottom of the can 1.
[0028]
The drive mechanism 212 includes a drive motor (not shown), a plurality of drive pulleys 212a and a belt 212b, and the belt 212b is wound around a pulley provided on the drive motor and the drive pulley 212a. The surface of the belt 212b is in pressure contact with a side surface of a part of the plurality of holding tables 211, and the driving motor drives the driving pulley 212a to rotate. The belt 212b is moved and driven, and the holding table 211 that is in pressure contact with the surface of the belt 212b is driven to rotate. Hereinafter, the holding table 211 that can be rotationally driven is particularly referred to as a rotating table 211a.
[0029]
Here, the above-described camera as an imaging unit (not shown) is provided outside the rotary table 211a, and an illuminating unit (not shown) that irradiates each unit of the can 1 from the side where these cameras are arranged is provided for each camera. Has been. That is, the camera takes an image of the reflected light of the light illuminated on each part of the can 1 by the illumination means.
[0030]
As shown in FIG. 5, the first detecting means 215 is provided above one of the turntables 211 a so that a radially outer portion of the flange portion 4 of the can 1 held on the surface of the turntable 211 a cans 1. Is arranged so as to irradiate substantially in parallel with the can axis from above. Here, “substantially parallel to the can axis” refers to a range of ± 30 ° with respect to the can axis. The first detecting means 215 is, for example, a photoelectric sensor, and can detect even when the flange portion 4 of the can 1 has an outer diameter difference of about 50 μm. In the present embodiment, the first detection means 215 is disposed such that the irradiation center is located at a position radially outwardly separated by 0.5 mm from the reference upper limit of the outer diameter of the flange portion 4. Therefore, if the outer diameter of the flange portion 4 is equal to or less than the reference upper limit value, the irradiation light from the first detecting means 215 is not reflected by the flange portion 4 and the first detecting means 215 receives this reflected light. When the outer diameter of the flange 4 is larger than the reference upper limit, the irradiation light of the first detector 215 is reflected by the flange 4, so that the first detector 215 performs this reflection. It is configured to receive light and enter the ON state.
[0031]
The control unit 216 includes an image processing unit that inspects the outer surface and the inner surface of the can 1 based on the image data of each camera, and a flange unit of the can 1 based on a detection signal from the first detection unit 215. And a storage unit for storing the processing results of these image processing unit and the determining unit, based on these processing results. The second rotating body 214b provided at the starting end of the can 213 is controlled, and the destination of the can 1 that has reached the rotating body 214b is determined.
[0032]
Each of the first and second rotating bodies 214a and 214b includes a grip portion 231 and a driving portion (not shown). The grip portion 231 is rotatably supported by a support portion (not shown), and is rotated by the driving portion. It is configured to be driven. The grip portion 231 has six convex portions 232 formed on the outer peripheral surface thereof at substantially equal intervals around the rotation axis, and a curvature substantially equal to the outer diameter of the body portion 2 of the can 1 between these convex portions 232. Is provided as the curvature portion 233. A suction hole (not shown) for sucking the body 2 of the can 1 is formed on the surface of the curvature portion 233, and vacuum air is supplied to the suction hole to suck and hold the body 2 of the can 1. ing.
[0033]
The unloading mechanism 213 includes an unloading path 213a for transferring the can 1 to the next process, and a discharge path 213b for discharging the can 1 from the production line. The starting end of the unloading mechanism 213, that is, the unloading path 213a and the discharging path 213b. The second rotator 214b disposed at the start end of the receives the output signal from the control unit 216 and distributes the can 1 to the carry-out path 213a or 213b based on the output signal. .
[0034]
A method of inspecting the can 1 using the inspection device 6 configured as described above will be described.
First, when the inspection device 6 is driven, compressed air is supplied to the box 40 of the first detection unit 100 in advance, and the compressed air is blown out from the outlet 11 onto the surface of the base plate 10. In this state, the can 1 is supplied from the supply unit 80 of the first detection unit 100 in a state where the can shaft is inclined at approximately 90 ° with respect to the vertical direction, that is, in a state where the can is tilted in the horizontal direction. Then, the can 1 having passed through the supply unit 80 reaches the upper ends of the first and second detection plates 20 and 30 provided on the base plate 10.
[0035]
At this time, as shown in FIG. 4, the distance B between the tips of the first and second detection plates 20 and 30 is smaller than the outer diameter C of the flange portion 4 of the can 1 and the opening of the can 1 Is larger than the outer diameter D of the can 1, the opening of the can 1 is inserted between the tips of the first and second detection plates 20, 30, and the flange 4 of the can 1 It passes through the gap between the surface of the base plate 10 and the third and fourth detection surfaces 21 and 31. Therefore, when the outer diameter of the flange portion 4 is formed to be equal to or more than the reference lower limit value while the can 1 passes through the first detection portion 100, the flange portion 4 is located in the gap, When the lower part of the part 4 and the third and fourth detection surfaces 21 and 31 are in contact with each other, the axial movement of the can 1 is prevented. Therefore, the movement of the can 1 upward in the axial direction is prevented by the opening surface of the can 1 being in contact with the surface of the base plate 10, so that the outer diameter of the flange portion 4 is not less than the reference lower limit value. As long as there is, the can 1 can be prevented from dropping from the first detection unit 100.
[0036]
The can 1 thus held moves toward the lower end of the first detection unit 100 while rotating by its own weight or the like, and reaches the outlet 11 formed in the base plate 10. At this time, the can 1 is urged toward the lower end of the first detection unit 10 by the compressed air from the outlet 11 and the inner bottom of the can 1 receives a force directed downward in the can axial direction. Therefore, the transfer speed of the can 1 is maintained at a high speed, and the can 1 can be transferred toward the lower end while rotating.
[0037]
Therefore, when the outer diameter of the flange portion 4 of the can 1 is smaller than the reference lower limit, the lower portion of the flange portion 4 is disengaged from the detection surfaces 21 and 31 by the force that the can 1 receives on the inner bottom portion, and the first It is removed from the detection unit 100. Thus, when the outer diameter of the flange portion 4 is smaller than the reference lower limit, the can 1 supplied to the first detecting portion 100 is surely removed before reaching the lower end of the detecting portion 100. Only the can 1 in which the outer diameter of the flange 4 is equal to or larger than the reference lower limit reaches the lower end of the detection unit 100 and is conveyed to the next step via the discharge unit 90.
[0038]
Next, from the can 1 having the outer diameter of the flange portion 4 selected by the first detecting section 100 and having the outer diameter equal to or larger than the reference lower limit value, it is determined that the outer diameter of the flange portion 4 is larger than the reference upper limit value, and A method of discharging from the line will be described.
[0039]
The can 1 having passed through the first detection unit 100 reaches a loading mechanism 210 of the second detection unit 200 shown in FIG. When the can 1 conveyed by the loading mechanism 210 reaches the first rotating body 214a provided at the end of the mechanism 210, the suction hole formed in the grip portion 231 of the rotating body 214a. Is supplied, and the body 2 of the can 1 is suction-held on the surface of the curved surface 233 where the suction holes are opened. Thereafter, the grip 231 is rotated clockwise by a drive mechanism (not shown), and the can 1 is placed on the surface of the holding table 211. At this time, the can 1 is positioned by a positioning mechanism (not shown) such that the can axis of the can 1 substantially coincides with the rotation axis of the holding table 211. Thereafter, vacuum air is supplied to suction holes (not shown) formed on the surface of the holding table 211, and the can 1 is suction-held on the surface of the holding table 211.
[0040]
Thereafter, the main body 241 is driven to rotate about the central axis O by a driving unit (not shown) until the can 1 reaches the position where the first detecting unit 215 is disposed (in the present embodiment, counterclockwise. 22.5 °). Here, in the present embodiment, the holding table 211 to which the first rotating body 214a delivers the can 1 is not driven to rotate by the driving mechanism 212, and the main body 241 is driven to rotate as described above. When the side surface of the holding table 211 comes into pressure contact with the surface of the belt 212 of the drive mechanism 212, the holding table 211 becomes a rotatable rotary table 211a. At about the same time as the rotation is stopped, the motor (not shown) of the drive mechanism 212 is driven to rotate, and the belt 212b is moved and driven via the drive pulley 212a. Thus, the rotating table 211a located below the first detecting means 215 is driven to rotate about this axis while being pressed against the surface of the belt 212b, and the can 1 held on the surface of the table 211 also rotates about the can axis. Driven.
[0041]
While the can 1 is driven to rotate at least one rotation around the axis of the can, the first detecting means 215 determines whether or not the first detecting means 215 receives the reflected light of the irradiation light from the detecting means 215. Perform the outer diameter inspection of 4.
That is, when the outer diameter of the flange portion 4 of the can 1 is equal to or less than the reference upper limit value over the entire circumference, as shown by a solid line in FIG. Since the outer side in the radial direction is irradiated from the peripheral edge, the first detecting means 215 does not receive the reflected light of the irradiation light. On the other hand, when the outer diameter of the flange portion 4 of the can 1 is at least partially larger than the reference upper limit over the entire circumference, as shown by the two-dot chain line in FIG. Since the part of the outer periphery of the part 4 is irradiated, the first detecting means 215 receives the reflected light from the part of the flange part 4.
[0042]
Then, the detection result by the first detection unit 215 is transmitted to the control unit 216 each time it is detected regardless of whether the detection result is good or not. Then, the control unit 216 specifies the cans inspected by the first detection unit 215 and stores the detection result for each can.
After that, after the main body 241 is driven to rotate counterclockwise around the axis O, the operation of rotating the rotary table 211a is repeated. The location is appropriately imaged, the image data is transmitted to the control unit 216, and the control unit 216 performs image processing and quality judgment. Then, the control unit 216 specifies and stores each can 1 in the same manner as the detection result by the first detection unit 215, based on the determination result based on the imaging data.
[0043]
When all the inspections are completed, the can 1 reaches the position where the second rotating body 214b is provided. At this time, the body 2 of the can 1 is suction-held on the surface of the curved portion 233 formed on the grip portion 231 of the second rotating body 214b, as described above. Then, the control unit 216 places the can 1 determined to be defective in any one of the stored detection result and the pass / fail judgment result on the discharge path 213b and discharged from the production line. On the other hand, the can 1 for which all of the detection result and the quality determination result are determined to be good is placed on the carry-out path 213a and transported to the next process.
[0044]
As described above, according to the first detection unit 100 in the can inspection device of the first embodiment, it is possible to reliably inspect whether the outer diameter of the flange portion 4 of the can 1 is smaller than the reference lower limit value. When the outer diameter is smaller than the reference lower limit, the can 1 can be reliably removed from the first detection unit 100.
That is, a configuration in which the can 1 is transported along the transport direction A while the flange 4 of the can 1 is supported by the third detection surface 21 and the fourth detection unit 31 can be realized. For the can 1 whose outside diameter is equal to or larger than the reference lower limit, the third and fourth detection surfaces 21 and 31 support the lower part of the flange portion 4, but the outer diameter of the flange portion 4 is smaller than the reference lower limit. For the can 1, the detection surfaces 21, 31 cannot support the lower part of the flange portion 4. Therefore, in the latter can 1, the compressed air blown out from the outlet 11 toward the can 1 can be reliably removed from the first detection unit 100.
[0045]
Further, since the third and fourth inspection surfaces 21 and 31 are inclined downward and are spaced apart in the vertical direction, the supplied can 1 is rotated downward by its own weight. Can be transported. Therefore, the outer diameter inspection of the flange portion 4 can be performed over the entire circumference, and a highly accurate inspection can be realized.
[0046]
Here, when the flange portion 4 is formed in the opening of the can 1, wax is applied to the opening of the can in order to smoothly perform this formation. Therefore, when the can 1 is transferred while supporting the flange portion 4 by the third and fourth detection surfaces 21 and 31, the wax may adhere to the surface of the base plate 10 and the detection surfaces 21 and 31 and solidify. There is. In this case, the gaps between the detection surfaces 21 and 31 and the surface of the base plate 10 become narrow, and problems such as stopping the transfer of the can 1 having the normal flange portion 4 occur. However, in the first detection unit 100 according to the present embodiment, since the heat plates 12 and 13 are provided on the back surface of the base plate 10, the surface of the base plate 10 and the detection surfaces 21 and 31 can be heated. Even when wax adheres to the can, the wax is prevented from solidifying, so that the flange portion 4 removes the wax when the can 1 is transferred, so that the occurrence of the problem can be reliably suppressed. Can be.
[0047]
Further, since the outlet 11 is formed on the surface of the base plate 10 so as to extend along the transfer direction A, compressed air can be reliably blown onto the can 1 to be transferred, and the inspection of the flange portion 4 can be performed. The accuracy can be further improved, and the transfer speed can be maintained at a high speed.
Further, positioning pieces 24, 34, and 300 are provided on the surface of the base plate 10, and the detection plates 20, 30 and the side support mechanism 50 can be positioned by these pieces 24, 34, and 300. When the size of the can 1 is changed or when the mold for molding the can 1 is changed, the positioning of the plates 20, 30 and the support mechanism 50 can be performed easily and with high precision. Therefore, the outer diameter inspection of the flange portion 4 can be reliably performed with high accuracy.
[0048]
Further, according to the second detection unit 200 in the can inspection apparatus of the first embodiment, the first detection unit 215 that detects the flange portion 4 whose outer diameter is larger than the reference upper limit value is provided. When the inspection is performed by the detecting means 215, the can 1 is rotated around the can axis by the rotary table 211a and the positioning means (not shown), so that the outer diameter can be detected over the entire circumference of the flange portion 4. And high-accuracy inspection can be realized. The control unit 216 that determines the quality of the can based on the highly accurate detection result, and switches the operation of the second rotating body 214b based on the determination result so that the transport destination of the can 1 is switched. If the can 1 is good, the can 1 is placed on the carry-out path 213a and transported to the next step, while if the can 1 is defective, the can 1 is placed on the discharge path 213b. Can be automatically discharged out of the production line, and appropriate pass / fail sorting can be performed with high efficiency.
[0049]
Furthermore, since the second detection unit 200 is provided with a camera (not shown) and configured to take an image of the outer surface and the inner surface of the can 1, the second detector 200 detects the flange portion 4 whose outer diameter is larger than the reference upper limit. In addition, it is possible to inspect whether or not each of the surfaces of the can 1 is scratched. Furthermore, the inspection device 6 according to the present embodiment can detect the flange portion 4 whose outer diameter is smaller than the reference lower limit value by the first detection unit 100, so that not only the flange portion 4 of the can 1 but also the can 4 It is possible to reliably inspect almost all of the defective forms of the apparatus itself.
[0050]
The present invention is not limited to the above-described embodiment, and various changes can be made without departing from the spirit of the present invention. For example, in the first detection unit 100 according to the present embodiment, the detection surfaces 21 and 31 are vertically separated from each other, but are separated horizontally and the can 1 is inserted between them. Is also good. In short, any configuration may be used as long as the flange portions 4 of the can 1 are supported by the detection surfaces 21 and 31 and the can 1 having the flange portion 4 whose outer diameter is equal to or larger than the reference lower limit can be prevented from falling off.
[0051]
Furthermore, in the first detection unit 100 according to the present embodiment, the configuration has been described in which the detection surfaces 21 and 31 that are surfaces substantially parallel to the surface of the base plate 10 are used as the third and fourth detection units. The detection unit is not limited to a surface, and may be, for example, a ridge line.
Furthermore, although the configuration in which the outlet 11 extends on the surface of the base plate 10 along the transfer direction A is shown, the present invention is not limited to this shape. A plurality of gaps may be formed intermittently.
[0052]
Next, a second embodiment of the present invention will be described. The same parts as those of the inspection apparatus according to the first embodiment are denoted by the same reference numerals, and the description thereof will be omitted.
In the inspection device according to the second embodiment of the present invention, the first detection unit 100 inspects whether the outer diameter of the flange portion 4 is larger than a reference upper limit and whether it is smaller than a reference lower limit. .
[0053]
As shown in FIG. 6, the first and second detection plates 20 and 30 of the inspection device 100 of the inspection device according to the second embodiment have the third and fourth detection surfaces 21 and In addition to 31, first and second detection surfaces 25 and 35 are formed.
The first and second detection surfaces 25 and 35 are configured to rise substantially perpendicularly from the third and fourth detection surfaces 21 and 31 toward the surface of the base plate 10. The separation distance E is set to be about 0.25 mm larger than the reference upper limit of the outer diameter C of the flange portion 4 of the can 1. The positional relationship between the third and fourth detection surfaces 21 and 31 with respect to the can 1 is the same as that in the first embodiment.
[0054]
When the can 1 is supplied to the first detection unit 100 configured as described above, if the outer diameter of the flange portion 4 is larger than the reference upper limit, the first and second detection surfaces 25 and 35 and the When the can 4 comes into contact with the first detection unit 100, the transfer of the can 1 in the first detection unit 100 is prevented. On the other hand, when the outer diameter of the flange portion 4 is smaller than the reference lower limit, the flange portion 4 is located between the surface of the base plate 10 and the third and fourth detection surfaces 21 and 31 as in the first embodiment. Are not engaged, and the can 1 is removed from the first detection unit 100 by the compressed air supplied from the outlet 11.
[0055]
Then, the can 1 having the flange portion 4 whose outer diameter is within the reference range is conveyed to the second detection unit 200 shown in FIG. 1, and here, similarly to the first embodiment, by a camera (not shown). The inspection of the outer surface and the inner surface of the can 1 is performed, and based on the inspection result, the operation of the second rotating body 214b is switched, and is placed on the carry-out path 213a or the discharge path 213b, and is placed on the carry-out path 213a. The placed can 1 is transferred to the next step, and the can 1 placed in the discharge path 213b is discharged.
[0056]
As described above, according to the inspection device according to the second embodiment, when the outer diameter of the above-described flange portion 4 is larger than the reference upper limit, the transfer of the can 1 in the first detection portion 100 is performed. Since it is blocked by the first and second detection units 25 and 35, it is possible to reliably prevent the can 1 from being transported to the next step. Here, in the case where such a can 1 is formed, there is a high possibility that the mold itself used in forming the opening of the can in the previous step is damaged, and in this case, the same Will be continuously formed. Accordingly, it is desirable to detect that such a can has been formed as early as possible, to minimize the formation of defective cans, and to investigate the cause early and repair the mold apparatus. By the way, in the inspection device according to the present embodiment, the transport of the can itself is stopped by the first detection unit 100, and further, the transport of the can following the can is prevented. Can be detected early and reliably, and the high quality control system described above can be reliably realized, and the occurrence of such defective cans can be suppressed to a minimum.
[0057]
Next, a third embodiment of the present invention will be described. The same parts as those of the inspection apparatus according to the first and second embodiments are denoted by the same reference numerals, and the description thereof will be omitted.
In the inspection device according to the third embodiment of the present invention, the second detection unit 200 inspects whether the outer diameter of the flange portion 4 is larger than a reference upper limit and whether it is smaller than a reference lower limit. .
[0058]
The second detection unit 200 of the inspection apparatus according to the third embodiment includes a second detection unit 217 as shown in FIG. 7 in addition to the first detection unit 215 shown in the first embodiment. Is established.
The second detecting means 217 is provided in the vicinity of the first detecting means 215, and is a position where the outer diameter of the flange portion 4 of the can 1 held on a certain rotary table 211a can be simultaneously detected by the two detecting means 215 and 217. It is arranged in. The second detecting means 217 is disposed so as to irradiate the peripheral portion of the flange portion 4 of the can 1 held on the surface of a certain rotary table 211a from above the can 1 substantially in parallel with the can axis. Here, “substantially parallel to the can axis” refers to a range of ± 30 ° with respect to the can axis. Like the first detecting means 215, the second detecting means 217 is, for example, a photoelectric sensor, and can detect even when the outer diameter difference of the flange portion 4 of the can 1 is about 50 μm. It has become.
[0059]
Further, in the present embodiment, the second detection means 217 is disposed so that the irradiation center is located at a position 0.5 mm radially inward from the reference lower limit value of the outer diameter of the flange portion 4. I have. Therefore, if the outer diameter of the flange portion 4 is equal to or larger than the reference lower limit, the second detecting means 217 receives the reflected light since the irradiation light from the detecting means 217 is reflected on the flange portion 4. When the outer diameter of the flange portion 4 is smaller than the reference lower limit value, the reflected light of the irradiation light is not received, and the flange portion 4 is turned off.
Here, as described in the first embodiment, with respect to the first detecting means 215, if the outer diameter of the flange portion 4 is equal to or less than the reference upper limit, the irradiation light from the first detecting means 215 Since the light is not reflected by the portion 4, the first detecting means 215 does not receive the reflected light and is turned off. If the outer diameter of the flange portion 4 is larger than the reference upper limit, the first detecting means 215 Since the irradiation light is reflected by the flange portion 4, the first detection means 215 receives the reflected light and is turned on.
That is, the detection means 215 and 217 can be configured to inspect whether the outer diameter of the flange portion 4 is within the reference range.
[0060]
The control unit 216 includes an image processing unit that inspects the outer surface and the inner surface of the can 1 based on the imaging data of each camera, and a flange of the can 1 based on the detection signals from the detection units 215 and 217. A determination unit that determines whether the outer diameter of the unit 4 is within a reference range; and a storage unit that stores processing results of the image processing unit and the determination unit. The second rotator 214b provided at the starting end of the mechanism 213 is controlled, and the destination of the can 1 that has reached the rotator 214b is switched.
[0061]
As described above, according to the inspection device of the third embodiment, since each of the detection means 215 and 217 is provided, it is determined whether the outer diameter of the flange portion 4 is within the reference range. Inspection can be performed with high accuracy. Further, the control unit 216 for judging the quality of the can 1 based on the detection results and switching the operation of the second rotating body 214b based on the judgment result is provided. Conveyance to the next step is performed by the path 213a, and on the other hand, in the case of a defective product, discharge to the outside of the production line can be automatically performed by the discharge path 213b, and appropriate pass / fail sorting can be performed with high efficiency.
[0062]
The present invention is not limited to the first to third embodiments, and various changes can be made without departing from the spirit of the present invention. For example, in the first detection unit 100 according to the first embodiment, by disposing the block materials in the notch portions having the third and fourth detection surfaces 21 and 31, respectively, these block materials are removed by the second detection unit. The first and second detection surfaces 25 and 35 described in the embodiment may be used. Further, a configuration in which a plurality of the block members as the first and second detection surfaces 25 and 35 are provided intermittently with a predetermined gap in the extending direction of the third and fourth detection surfaces. Good.
Furthermore, in the first and third embodiments, a so-called reflection type photoelectric sensor has been described as the detection means 215, 217, but the present invention is not limited to this, and may be, for example, a transmission type.
Further, in the first to third embodiments, the configuration in which the second rotating body 214b of the second detection unit 200 is provided to switch the transport destination of the can is shown. When the can is detected, the production line itself may be stopped. Also in this case, the high quality control system described above can be reliably realized, and the occurrence of such defective cans can be suppressed to a minimum.
[0063]
【The invention's effect】
As is clear from the above description, according to the first aspect of the present invention, it is possible to reliably perform the inspection as to whether the outer diameter of the flange portion is within the reference range, and to reduce the load required for this processing. The increase can be minimized. Furthermore, in this inspection apparatus, in a configuration in which a switching mechanism for switching the transport destination of the can based on the determination result is provided, if the can is a good product, the process proceeds to the next step. The transfer destination can be switched so as to discharge, and appropriate pass / fail sorting can be automatically performed with high efficiency.
[0064]
According to the invention according to claim 2, when the flange portion of the transported can is larger than the reference upper limit, the flange portion comes into contact with the first detection portion and the second detection portion, so that the flange portion Can be reliably prevented from being carried out to the next step. Further, in a configuration in which this inspection device is disposed on a production line on which molded cans are continuously transferred, when the cans come into contact with the detection unit and the transfer is stopped, all subsequent cans are stopped. Since the transfer of cans is stopped, a good quality control system can be reliably realized, and the occurrence of such defective cans can be suppressed to a minimum.
[0065]
According to the third aspect of the present invention, when the outer diameter of the flange portion is equal to or larger than the reference lower limit, the third detector and the fourth detector resist the force of the compressed air from the outlet. Can hold the can. On the other hand, in the case where the outer diameter of the flange portion is smaller than the reference lower limit value, since the flange portion is not engaged with the third and fourth detection portions, the can is easily and easily transferred from the transfer path by the compressed air from the outlet. It can be reliably eliminated.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of a can inspection apparatus shown as one embodiment of the present invention.
FIG. 2 is a schematic configuration diagram of a first inspection unit in the can inspection device shown in FIG. 1;
FIG. 3 is a sectional view taken on line XX of FIG. 2;
FIG. 4 is an enlarged view of a region Y shown in FIG. 3 shown as the first embodiment of the present invention.
FIG. 5 is a schematic layout diagram of the detection means shown in FIG. 1 shown as the first embodiment of the present invention.
FIG. 6 is an enlarged view of a region Y shown in FIG. 3 shown as a second embodiment of the present invention.
FIG. 7 is a schematic layout diagram of a detection unit shown as a third embodiment of the present invention.
FIG. 8 is a schematic view of a can inspected by the inspection device of the present invention.
[Explanation of symbols]
1 can
4 Flange
6 Inspection equipment
10 Base plate (base part)
11 outlet
12,13 Heat plate (heating means)
21. Third detection surface (third detection unit)
25 First Detection Surface (First Detection Unit)
31 fourth detection surface (fourth detection unit)
35 second detection surface (second detection unit)
211 holding table
211a Rotary table
213a Transfer path
213b discharge path
214b Second rotating body (switching mechanism)
215 First detection means (detection means)
216 control unit
217 Second detection means (detection means)
A Transfer direction of cans
B Separation distance between the tip of the first detection plate and the tip of the second detection plate (distance between the third detection unit and the fourth detection unit)
C Outer diameter of flange
D Outside diameter of can opening
E Separation distance between the first detection surface and the second detection surface

Claims (3)

A can inspection apparatus for inspecting a can that has a bottomed cylindrical shape and has a flange at an opening,
Detecting means for irradiating the irradiation light substantially parallel to the can axis and detecting the presence or absence of the flange portion in the irradiation direction,
A control unit having a determination unit for determining the quality of the can based on the detection result of the detection unit. A can inspection apparatus for inspecting the outer diameter of a flange portion of a can having a flange portion at an opening while the can is being transported, the cylinder having a bottom having a cylindrical shape,
A first detection unit and a second detection unit disposed apart from each other in a direction intersecting with the transport direction of the can,
The separation distance between the first detection unit and the second detection unit is set so that when the outer diameter of the flange portion of the can is larger than a reference upper limit, the separation distance comes into contact with the flange portion. Inspection equipment for cans. The can inspection device according to claim 1 or 2,
A third detection unit and a fourth detection unit that are arranged on one plane facing the base unit and extend substantially parallel to each other;
The separation distance between the third detection unit and the fourth detection unit is smaller than the outer diameter of the flange of the can, and is a distance larger than the outer diameter of the opening of the can.
An outlet for blowing compressed air toward the can to be transferred is formed at a position of the base portion between the third detection portion and the fourth detection portion. And can inspection equipment.

Images