JP4115133B2 - Bottle-type can and manufacturing method thereof - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a metal bottle-shaped can in which a roll-on cap that is covered with a metal cap and sealed is used, and a support ring portion is integrally formed below a screw portion provided in a mouth portion, and a method for manufacturing the same. Transport using a PET bottle transport system is possible.
[0002]
[Prior art]
In general, as a lightweight beverage container that replaces heavy glass bottles, can bodies and cans can be made by appropriate methods such as squeezing and deep drawing (drawing / redrawing) from thin metal plates of aluminum or steel. A two-piece can having a bottom integrally formed and a PET bottle integrally formed into a bottle shape with polyethylene terephthalate resin (hereinafter referred to as a PET bottle) are widely used.
[0003]
This two-piece can is opened by pulling a simple opening of an easy open end (end plate with a simple opening) fastened and fixed to the flange at the upper end of the can body. By opening and removing the pilfer proof cap attached to the mouth and neck, the user can drink the beverage in the container.
[0004]
In such a beverage container, a PET bottle provided with a mouth-and-neck portion is easy to drink when drinking directly from the container, and has the convenience that it can be resealed with a cap.
[0005]
However, since PET bottles are easily deformed by heating, care must be taken in handling them, and since the gas permeability resistance and light shielding properties are low, the shelf life of the contents is shortened and the thermal conductivity is reduced. There is a problem in that the rapid cooling when the contents are cooled in the refrigerator is poor. In addition, the rate at which used PET bottles are collected and recycled as resources is low.
[0006]
Therefore, a two-piece can made of a thin metal plate that is excellent in terms of heat resistance, gas permeation resistance, light shielding properties, rapid cooling properties, etc., and has a high recycling recovery rate, is formed into a bottle shape with a neck and neck. Conventionally, it has been studied to improve convenience by adding a function of re-plugging by using a screw cap to seal the mouth and neck.
[0007]
As a bottle-shaped can made of such a thin metal plate, a small-diameter mouth-neck portion, a shoulder portion having an inclined surface, and a large-diameter trunk portion are integrally formed from a thin metal plate, and the can opposite to the mouth-neck portion is formed. A configuration in which the bottom opening is hermetically sealed by fastening a separate bottom lid and a screw cap can be screwed to the mouth and neck is disclosed in Japanese Patent Application Laid-Open No. 10-509095 as an example. Is described and disclosed.
[0008]
In Japanese Utility Model Publication No. 61-51314, a plastic cylindrical body having a screw portion formed on the outer periphery thereof is externally fitted to the mouth and neck of a bottle, and the cylindrical body is externally fitted to the mouth and neck. Then, there is described a bottle in which the cylindrical body is made non-rotatable with respect to the mouth-and-neck portion by providing concave and convex portions that are engaged with each other at the contact portions of both.
[0009]
Furthermore, in Japanese Utility Model Laid-Open No. 60-120920, a cylindrical body having a screw portion formed on the outer periphery of the mouth and neck portion formed in the cylindrical shape of the metal container body is non-rotatably fitted. A metal container is described, and a claw portion is provided at the distal end on the insertion side of the cylindrical body, and a concave portion that is engaged with the claw portion is formed in the metal container body, and the cylindrical body is fitted to the mouth and neck. Then, the claw portion of the cylindrical body is engaged with the concave portion of the metal container main body so that the cylindrical body cannot be rotated with respect to the mouth-and-neck portion.
[0010]
Japanese Patent Laid-Open No. 2001-213416 discloses that at least one or more recesses that are smoothly curved inward from the lower end of the threaded portion of the mouth around the upper end of a tapered shoulder that expands in the radial direction. The metal can with a screw in which the convex part which curves smoothly on the outside was formed is indicated. Therefore, according to this structure, it is supposed that the strength of the region of the mouth portion of the threaded metal can, in particular, the region from the lower end of the screw portion to the upper end of the shoulder portion can be improved.
[0011]
[Problems to be solved by the invention]
By the way, the resin PET bottle has a tendency to buckle or deform in the body wall portion when the cap is stoppered, so a support ring for supporting the stoppering load below the screw portion at the neck portion of the bottle. Is provided. In other words, by supporting the support ring portion on the bottle support mold, even if a stopper pressure or a sealing torque necessary for sealing is applied when the cap is stoppered, the body of the bottle located below the support ring portion is supported. The wall is prevented from buckling or deforming.
[0012]
In addition, a holding ring or a double layer portion (annular protrusion) is integrally formed on the cylindrical body fixed to the mouth and neck portion of the above-mentioned Japanese Utility Model Laid-Open Nos. 61-51314 and 60-120920. When the stopper is plugged, the retaining ring or the double layer portion is supported by another member so as to receive the axial load and prevent the deformation of the lower portion.
[0013]
However, since the structure described in these is a structure in which a separate cylindrical body having a threaded portion formed on the outer periphery is fixed to the mouth-and-neck portion so as not to rotate, equipment for manufacturing a separate cylindrical body Is required to attach the cylindrical body to the bottle-shaped can, and the engaging portion such as the claw provided on the cylindrical body is engaged with the engaging portion provided on the bottle-shaped can. Since it is necessary to perform alignment and the like, it is complicated, and in order to automate this operation and operate at high speed, there is a disadvantage that the apparatus configuration becomes complicated and the cost is increased.
[0014]
Further, JP-A-2001-213416 is intended to reinforce a shoulder portion having an inclined surface, that is, a tapered shoulder portion that expands in the radial direction. Bottle type cans with shoulders are excluded.
[0015]
Further, Japanese Patent Publication No. 10-509095 discloses a bottle-shaped can having a metal sleeve fixed to the mouth and neck in order to prevent similar buckling and deformation of the body wall. In this case, a cylindrical metal sleeve manufactured separately is fitted on the outside of the mouth and neck, and the metal sleeve is fastened to the shoulder by a flange portion where the tip of the mouth and neck is bent. The sleeve is fixed so that it does not rotate.
[0016]
However, in order to prevent the metal sleeve from rotating relative to the bottle-shaped can, it is necessary to adhere the metal sleeve to the can in addition to the above configuration. Therefore, the drying process and the equipment for realizing these processes are required, so that the equipment is large and the equipment cost is increased.
[0017]
The present invention has been made in view of such circumstances, and by forming a part of the mouth and neck portion into a support ring portion, it has excellent buckling resistance at the time of capping and can perform stable capping, It is an object of the present invention to provide a bottle-type can that can be used with a transfer means and production line for PET bottles, and a method for producing the bottle-shaped can.
[0018]
[Means for Solving the Problem and Action]
In order to achieve the above-mentioned object, the invention of claim 1 comprises a resin-coated metal plate in which a resin layer is laminated on both sides of a metal thin plate, a small-diameter mouth-neck portion and a shoulder portion having an inclined surface or a curved surface. In a bottle-type can having a structure in which a large-diameter body is integrally formed, a screw portion in which a cap is screwed to the mouth-neck portion, and a cylindrical portion extending from the screw portion of the mouth-neck portion to a shoulder portion. And a support ring part formed by molding the support part. The support ring part is connected to the horizontal shoulder part projecting part and the shoulder part projecting part, and the cross-sectional shape in the plate thickness direction is the shoulder part. An arcuate shape having a radius of curvature of 1.3 to 2.8 times the thickness of the part-side overhanging part is set, and an outer peripheral edge located above the shoulder-side overhanging part and continuous to the outer peripheral edge And at least a part of the protruding portion on the screw side that is in contact with the protruding portion on the shoulder side. And it is characterized in that it is composed of a part.
[0019]
According to the first aspect of the present invention, even if the support neck is formed by forming the mouth and neck as described above, the outer peripheral edge has a curvature radius of 1.3 to 2.8 times the plate thickness. Therefore, stress generated in the resin film covering the inner surface side of the outer peripheral edge is relieved to prevent the resin film from being damaged, and sufficient corrosion resistance can be ensured by protecting the resin film.
[0020]
In addition, by setting the radius of curvature of the outer peripheral edge portion to be smaller than 2.8 times the plate thickness, the ratio of the curved portion of the outer peripheral edge portion to the horizontal portion of the support ring portion is reduced. The lower surface of the horizontal portion of the part can be used as a guide surface or a support surface during conveyance.
[0021]
In addition, since the bottle-shaped can can be capped while being supported by the support ring, even if there is a variation in the overall height of the can from the bottom of the can to the opening of the mouth and neck, there is no effect of this variation. Since capping can be performed, stable capping can be performed, the tightness of the wrapping can be improved, and the product quality as a bottle-shaped can can be improved.
[0022]
That is, in the case of the configuration supported by the bottom of the can body, even if the movement amount of the same member is secured in the axial direction for capping when capping, due to the variation in the height of the entire can, Since the position in the vertical direction where the capping member comes into contact with the mouth and neck and the load starts to be applied is different, the load applied to the mouth and neck varies. However, when supported by the support ring part, the length of the part from the support ring part below the support ring part in the axial direction to the bottom of the can becomes irrelevant. Can be avoided.
[0023]
In addition, the shoulder projecting portion and the threaded portion projecting portion forming the support ring portion are substantially elastic in the support ring portion because at least a part of the inner wall surface is in contact with and in contact with each other. Since the gap that acts automatically can be prevented, it is possible to avoid the occurrence of uneven load due to the gap even when pressed from the opening side of the mouth and neck, such as during capping, in the mouth and neck. It is possible to prevent the portion above the support ring portion from buckling unevenly.
[0024]
Furthermore, by forming the neck and neck part and providing an integral support ring part, the process and equipment for fixing the metal sleeve with an adhesive as in the case of providing a separate metal sleeve is not required. The inconvenience of lowering the property can be solved in advance.
[0025]
According to a second aspect of the present invention, in addition to the configuration of the first aspect, the curl-side cylindrical portion and the shoulder-side cylindrical portion to which the support ring portion of the mouth-neck portion is connected are formed to have substantially the same diameter. The cross-sectional shape in the thickness direction of the connecting portion between the shoulder projecting portion and the shoulder side cylindrical portion is formed in an arc shape having a radius of curvature of 1.0 mm or less.
[0026]
According to the invention of claim 2, in addition to obtaining the same operation as that of the invention of claim 1, the outer peripheral edge portion is formed by the connection portion being formed in an arc shape having a curvature radius of 1.0 mm or less. In the same way, the proportion of the curved portion of the connecting portion in the horizontal portion of the shoulder overhanging portion is reduced, so that a sufficient horizontal plane supported by the lower surface of the shoulder overhanging portion is secured, and the support ring portion is guided during transportation. The use as a surface or a support surface is promoted.
[0027]
Also, since the surface of the shoulder-side overhanging portion facing the screw-side overhanging portion is similarly increased in the horizontal and flat surface portion, the contact area between the shoulder-side overhanging portion and the screw-side overhanging portion is increased. A sufficiently secured configuration can be obtained, and in this case, the effect of obtaining the buckling resistance can be promoted.
[0028]
Further, the invention of claim 3 is a cup molding step in which a lubricant is applied on the surface of a resin-coated metal plate in which a resin layer is laminated on both surfaces of a thin metal plate and punched to form a cup shape, and the cup A can-molding step of forming a cup-shaped molded product into a bottomed cylindrical can having a small diameter and a thin barrel, and a barrel and a bottom near the bottom of the bottomed cylindrical can A small-diameter cylindrical portion forming step for forming a shoulder portion and an unopened small-diameter cylindrical portion; Mouth process And a screw part forming step for forming a screw part on the outer peripheral surface of the opened small-diameter cylindrical part, a forming process for a bottomed cylindrical can with a thinned barrel part, and a cutting end of the small-diameter cylindrical part And a lubricant removing step for removing the lubricant from the outer surface of the bottomed cylindrical can provided between the opening step and the shoulder having a small-diameter mouth-neck portion and an inclined surface or a curved surface. In the bottle-shaped can manufacturing method of manufacturing a bottle-shaped can having a configuration in which the portion and the large-diameter body portion are formed integrally, after the threaded portion forming step Before reaching the shoulder from the screw Small diameter cylinder Part , A pre-ring portion forming step for forming a pre-ring portion protruding outward in a convex bead shape by an inner tool and an outer tool, and a horizontal shoulder portion side by pressing the pre-ring portion in the axial direction An overhanging portion, an arcuate outer peripheral edge having a radius of curvature 1.3 to 2.8 times the plate thickness of the shoulder side overhanging portion continuous to the shoulder side overhanging portion, and the outer peripheral edge. It is a method characterized by providing a support ring part forming step in which at least a part thereof is re-formed into a support ring part composed of a threaded part side protruding part brought into contact with the shoulder part side protruding part.
[0029]
According to the invention of claim 3, among the series of steps for manufacturing the bottle-shaped can, the step of forming the support ring portion is arranged after the lubricant removing step, so that the screw portion and the neck portion are arranged. Even if the support ring part is molded, it is possible to prevent cracks and the like from occurring in the resin film covering the molded part and the vicinity thereof, so that the corrosion resistance by the resin film can be sufficiently secured.
[0030]
The invention of claim 4 is a method characterized in that, in addition to the configuration of claim 3, the step of forming the pre-ring portion is configured by a spin roll forming process of at least two stages. is there.
[0031]
According to the invention of claim 4, in addition to obtaining the same action as the invention of claim 3, by molding the pre-ring part by performing a multi-stage spin roll molding process on the mouth and neck, Since the amount of deformation at each stage is reduced, the mouth and neck can be deformed without difficulty, and the shape accuracy and dimensional accuracy of the pre-ring portion can be improved.
[0032]
DETAILED DESCRIPTION OF THE INVENTION
DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments of a bottle-shaped can with a support ring portion and a manufacturing method thereof according to the present invention will be described in detail with reference to the drawings. FIG. 1 is a front view showing an overall configuration of a bottle-shaped can according to an embodiment of the present invention, FIG. 2 is a cross-sectional view showing details of a support ring portion, and FIG. It is process drawing which shows the outline of each process.
[0033]
As shown in FIG. 1, the bottle-shaped can 1 of the present example has a shoulder portion formed in a dome-shaped curved surface having a curved longitudinal section from the trunk portion 2 formed in a large-diameter cylindrical shape. 3, a mouth and neck portion 4 formed in a small diameter cylindrical shape for attaching a cap is integrally formed, and the opening at the lower end of the body portion 2 is sealed by a bottom lid 5. ing.
[0034]
That is, this bottle-shaped can 1 includes a small-diameter mouth-and-neck portion 4, a shoulder portion 3 having a curved surface, and a large-diameter trunk portion 2 from a resin-coated metal plate in which a thermoplastic resin layer is laminated on both surfaces of a thin metal plate. The mouth neck 4, the shoulder 3, and the body 2 are integrally formed.
[0035]
Further, the mouth / neck portion 4 has a curled portion 6 formed by winding the front end portion of the cylindrical portion, and a spiral unevenness continuously on the shoulder portion 3 side starting from the vicinity of the curled portion 6. A threaded portion 7 formed with a portion and an annular bead portion 8 formed below in the vicinity of the terminal end of the threaded portion 7 are provided. The curled portion 6 is formed in a substantially circular cross-sectional shape, and the diameter of the peripheral edge on the inner peripheral side of the curled portion 6 is set slightly smaller than the inner diameter of the mouth-and-neck portion 4. ing.
[0036]
Further, a support ring portion 10 formed integrally with the mouth neck portion 4 is provided in a cylindrical portion from the screw portion 7 to the shoulder portion 3 of the mouth neck portion 4, and the support ring portion 10 will be described later. Further, a convex bead-shaped prering 11 protruding outward is once formed, and the convex bead-shaped prering portion 11 is further pressed in the axial direction.
[0037]
As shown in FIG. 2, the support ring portion 10 has a shoulder-side overhanging portion 12 whose cross-sectional shape is substantially horizontal, and 1.3 to 2.8 times the plate thickness of the shoulder-side overhanging portion 12. The outer peripheral edge portion 13 having a radius of curvature and a threaded portion side projecting portion 14 connected from the outer peripheral edge portion 13 to the cylindrical portion of the mouth-and-neck portion 4 through an annular recess, and on the shoulder side The projecting portion 12 and the threaded portion side projecting portion 14 are configured to contact each other in the axial direction between a part of the inner wall surfaces that are substantially opposed to each other.
[0038]
Further, the bottle-shaped can 1 has its lower end opening portion sealed off by tightening and fixing a metal bottom cover 5 on the outer surface of the body portion 2, and desired characters, decorative patterns, etc. A top coat layer for protecting the outer surface of the can is formed.
[0039]
As shown in FIG. 3, the manufacturing process of such a bottle-shaped can 1 is made of a resin-coated metal plate in which a thermoplastic resin layer is laminated on both surfaces of a metal plate. A blank obtained by punching a plate into a disk shape is drawn and formed into a cup shape. In the next can body forming process, this cup-shaped product is redrawn at least once (simultaneously bending and stretching). And the ironing process is performed to form a bottomed cylindrical can in which the body portion 2 has a small diameter and is thinned.
[0040]
Next, in the top dome molding process, in order to mold the bottom of the bottomed cylindrical can into the neck 4 and the shoulder 3, the first step is the bottom corner of the DI can. (The bottom portion and the portion of the body portion 2 in the vicinity of the bottom portion) are molded so that the longitudinal section is a curved surface of the lower portion of the shoulder portion 3 having an arc shape, and the bottomed cylindrical portion having a small diameter is formed by drawing. In the process, the diameter of the bottomed cylindrical portion is reduced to be substantially the same as the diameter of the neck 4 by performing a plurality of drawing processes on the can bottom side. After repeating the drawing process, the shoulder 3 formed after the curved surface at the bottom of the shoulder 3 is reshaped into a continuous smooth curved surface. The cylindrical portion is subjected to two times of mouth-drawing, and is formed to have substantially the same diameter as the mouth-and-neck portion 4.
[0041]
In the lubricant removing step, the can is formed in the opening and neck portion 4 and the shoulder portion 3 in which the bottom of the can is not opened in the top dome forming step, and the lubricant is removed from at least the outer surface thereof, followed by trimming. In the process, the opening end side of the body part 2 opposite to the mouth / neck part 4 is trimmed to set the can to a predetermined height. Furthermore, in the printing / painting process, a design such as a desired character or decorative pattern is printed on the outer surface of the cylindrical body 2 whose end opposite to the mouth / neck 4 is open, and the printing is performed. A transparent curable paint such as a clear paint for protecting the outer surface of the applied can is applied to the outer surface of the body portion 2 as a top coat. This printing and painting process is the same as the printing and painting process for the cylindrical body of a normal two-piece can.
[0042]
Then, the can body subjected to printing and painting is sent to the next drying step, and the printing ink layer and the top coat layer are sufficiently dried. In this drying step, the laminated thermoplastic resin layer is heated and melted to a temperature equal to or higher than its crystal melting temperature, and then is made amorphous by cooling to 160 ° C. within 8 seconds. After that, in the screw / curl forming process, first, the front end of the mouth-neck portion 4 is opened by trimming the closed portion of the front end of the unopened mouth-neck portion 4, and then the open end portion is wound outward (or inside). And then forming a screw portion 7 for screwing a cap on the cylindrical peripheral wall, and forming an annular bead portion 8 for a cap clamp below the screw forming portion.
[0043]
Then, the can body in which the screw portion 7 and the annular bead portion 8 are molded is transferred to the next support ring portion molding step, and in the support ring portion molding step, the mouth neck portion 4 below the annular bead portion 8 is A support ring portion 10 having an outer diameter larger than the outer diameter of the screw portion 7 is formed through a plurality of overhanging steps and a clamping step.
[0044]
That is, this overhanging process is constituted by a two-stage spin roll forming process. First, as shown in FIG. 4A, the neck and neck are formed in an intermediate portion with the shoulder portion 3 below the annular bead portion 8. The inner tool 16A disposed inside the portion 4 and the outer tool 17A disposed outside the mouth-and-neck portion 4 form a ring-shaped annular convex portion 18 whose section is projected outward, and thereafter 4 (b), an inner tool 16 and an outer tool 17 are arranged inside and outside of the mouth and neck portion 4, and they are moved toward and away from each other while being relatively rotated, and a ring-shaped convex portion having a cross-sectional shape. The pre-ring 11 is formed while expanding the outer diameter of 18.
[0045]
Therefore, since the step of forming the pre-ring 11 is configured by a plurality of spin roll forming processes, the shape after deformation targeted by each stage of the spin roll forming process is close to the shape before deformation. Thus, the amount of deformation shared at each stage can be reduced. For this reason, it is possible to suppress the occurrence of coining (metal surplus) in the deformed portion of the mouth-and-neck portion 4 and to provide a sufficient margin without affecting the other portions of the mouth-and-neck portion 4 other than the deformed portion. Can be deformed. As a result, the quality of the resin film covering the inner surface of the deformed portion of the mouth-and-neck portion 4, that is, the coating quality of the resin coating is maintained, and the shape accuracy and dimensional accuracy of the final pre-ring 11 and the inner surface quality are maintained. Can be improved.
[0046]
Next, in the clamping step, the support ring portion is formed by re-molding an intermediate portion of a portion of the pre-ring 11 formed in a convex bead shape that protrudes radially outward from the outer surface of the mouth-and-neck portion 4 into a laminated shape. 10 is molded.
[0047]
As a result of such molding, the overhanging portion facing the shoulder 3 side of the support ring portion 10 is substantially horizontal, and the height from the support ring portion 10 to the tip of the mouth neck 4 is It becomes a predetermined height. That is, the lower surface of the projecting portion of the support ring portion 10 is a surface along a direction orthogonal to the axial direction of the can body, and the lower surface of the projecting portion is supported by a horizontal surface provided on the support member, as will be described later. By doing so, the bottle-shaped can 1 is supported at a location above the bottle-shaped can 1 and the can-type can 1 can be held in an upright posture with the axis of the can body extending along the vertical direction. By moving the member, the bottle-shaped can 1 can be moved in its posture.
[0048]
As a means for re-forming the pre-ring 11 into the support ring portion 10, as shown in FIG. 4 (c), the pre-ring 11 is divided into upper split molds 20A and 20B and lower split molds 21A and 21B described later. In addition to the forming method of sandwiching and clamping at, known means such as another forming method of spinning forming with an inner surface side roll and an outer surface side roll can be appropriately employed.
[0049]
Further, in this example, as shown in FIG. 2 again, the support ring portion 10 is formed on the outer peripheral edge portion 13 of the support ring portion 10 so that the cross-sectional shape of the support ring portion 10 is a substantially horizontal shoulder side protruding portion 12. And an outer peripheral edge portion 13 having a radius of curvature 1.3 to 2.8 times the plate thickness of the shoulder-side protruding portion 12, and a screw portion side connected from the outer peripheral edge portion 13 to the cylindrical portion through an annular recess The projecting portion 14 is configured so that at least a part of the mutually opposed inner wall surfaces of the shoulder portion side projecting portion 12 and the screw portion side projecting portion 14 are in contact with each other.
[0050]
Accordingly, by setting the radius of curvature R of the outer peripheral edge portion 13 within the above range, the corrosion resistance by the coating film is sufficiently ensured, and the surface supported by the support ring portion 10 is sufficiently secured. ing.
[0051]
That is, when the outer peripheral surface radius of curvature R of the outer peripheral edge portion 13 is less than 1.3 times the plate thickness, cracks are likely to occur in the coated film, so that sufficient corrosion resistance by the coated film cannot be obtained. .
[0052]
First, in order to form the support ring portion 10 in the mouth / neck portion 4, the inner peripheral surface of a predetermined portion of the mouth / neck portion 4 is first brought into contact with an inner tool for coining processing, and the inner neck tool 4 Is pressed from the inside in the radial direction to the outside, an external force is directly applied to the coating film protecting the inner surface of the portion, and the strength as a material is partially weakened. And when it is shape | molded by the support ring part 10 and the curvature radius R of the outer periphery part 13 becomes less than 1.3 times of plate | board thickness, since the inner surface shape of the location becomes a curved surface shape bent sharply. A large stress is generated in the coated film along the inner surface. As a result, the coated film covering the inner peripheral surface of the outer peripheral edge portion 13 having a radius of curvature R less than 1.3 times the plate thickness is likely to break, so that sufficient corrosion resistance by the coated film is obtained. Inconvenience that can not be generated.
[0053]
On the other hand, when the curvature radius R is larger than 2.8 times the plate thickness, the ratio of the curved portion of the outer peripheral edge portion 13 to the horizontal portion of the support ring portion 10 is increased. The area of the horizontal surface of the side overhanging portion 12 and the protruding length protruding outward in the radial direction cannot be secured sufficiently. For this reason, there arises a disadvantage that the lower surface of the support ring portion 10 protruding outward in the radial direction cannot be used as a guide surface or a support surface during conveyance.
[0054]
Therefore, by forming the cross-sectional shape in the radial direction of the outer peripheral edge portion 13 into an arc shape and forming the radius of curvature R to be 1.3 to 2.8 times the plate thickness of the shoulder side protruding portion 12. The above disadvantages are avoided in advance.
[0055]
That is, as described above, the outer peripheral edge portion 13 of the support ring portion 10 is formed so as to have a radius of curvature R larger than 1.3 of the plate thickness, so that the film adhered to the inner surface of the outer peripheral edge portion 13. Since stress generated in the film is relieved, damage to the coated film is prevented, and sufficient corrosion resistance can be ensured by protecting the coated film. In addition, since the curvature radius R of the outer peripheral edge portion 13 is smaller than 2.8 times the plate thickness, the ratio of the curved portion of the outer peripheral edge portion 13 to the horizontal portion of the support ring portion 10 is reduced. The lower surface of the horizontal portion of the support ring unit 10 can be used as a guide surface or a support surface during conveyance.
[0056]
Further, in addition to this, the outer peripheral edge portion 13 of the support ring portion 10 is formed such that the cross-sectional shape in the plate thickness direction is an arc shape, and the shoulder portion does not protrude downward from the shoulder side protruding portion 12. Since it is positioned above the side overhanging portion 12 and is continuous with the shoulder side overhanging portion 12, a flat ring surface free from obstructions is secured as a support surface formed in the support ring portion 10. Stable support can be performed using this surface.
[0057]
Further, the shoulder projecting portion and the threaded portion projecting portion 14 forming the support ring unit 10 are substantially in contact with each other at least a part of the inner wall surface, so that the mouth neck 4 The upper portion from the support ring portion 10 is prevented from buckling unevenly.
[0058]
That is, by capping at least a part of the mutually opposed inner wall surfaces of the shoulder-side overhanging portion 12 and the screw-side overhanging portion 14 constituting the support ring portion 10, etc. Even when a load is applied in the axial direction downward from the opening end of the mouth-and-neck portion 4, sufficient buckling resistance for preventing unintended deformation of the bottle-type can 1 can be ensured.
[0059]
First, when a gap is formed inside the support ring part 10, the support ring part 10 acts elastically against being pressed from above the mouth-and-neck part 4, and that Since there is a screw portion formed in a spiral shape above, an uneven load is likely to be applied, that is, the load distribution state is deviated between the mouth-neck portion 4 and the support ring portion 10, and as a result, the load is concentrated. There is a tendency that a part in the circumferential direction of the mouth-and-neck portion 4 that is made, particularly the starting end portion of the screw portion below the curled portion, buckles.
[0060]
Further, for example, over the entire circumference in the circumferential direction on the inner periphery side of the support ring portion 10, the screw portion side overhanging portion 14 and the shoulder portion side overhanging portion 12 are not in contact with each other, and a gap is generated between them. When the gap is narrowed or widened, the axial load is not transmitted uniformly from the screw portion side overhanging portion 14 to the shoulder portion side overhanging portion 12 over the entire circumference in the circumferential direction. Further, a screw portion formed in a spiral shape is provided above the screw portion side overhanging portion 14, and this screw portion has a groove portion formed in a spiral shape when viewed from the inner peripheral surface side of the mouth / neck portion 4, that is, Since it can be considered that a groove is formed on the inner peripheral surface of the mouth-and-neck portion 4 so as to obliquely cross the longitudinal direction of the mouth-and-neck portion 4, the axial load is directed downward from the opening end of the mouth-and-neck portion 4. It becomes difficult to be transmitted in a straight line.
[0061]
Then, the shoulder part side overhang | projection part 12 and the thread part side overhang part 14 which comprise the support ring part 10 are made to contact the at least one part of the opposing inner wall surfaces, and the inside of the support ring part 10 is carried out. This prevents the above-described inconvenience by preventing the generation of a gap that acts elastically.
[0062]
Further, the curl-side cylindrical portion and the shoulder-side cylindrical portion to which the support ring portion 10 of the mouth-and-neck portion 4 is connected are formed to have substantially the same diameter, and the shoulder protruding portion 12 and the shoulder-side cylindrical portion are connected to each other. The cross-sectional shape in the thickness direction of the portion is formed in an arc shape having a curvature radius r of 1.0 mm or less.
[0063]
Therefore, since the connection portion is formed in an arc shape having a curvature radius r of 1.0 mm or less, the proportion of the connection portion occupying the horizontal portion of the shoulder overhanging portion 12 is reduced similarly to the outer peripheral edge portion. Therefore, a sufficient horizontal surface used as a support surface is secured on the lower surface of the shoulder overhanging portion 12, and the use of the support ring portion 10 as a guide surface or support surface during transportation is promoted.
[0064]
Further, since the surface of the shoulder portion side overhanging portion 12 facing the screw portion side overhanging portion 14 is also increased in the same horizontal and flat surface portion, the shoulder portion side overhanging portion 12 and the screw portion side overhanging portion 14 In this case, the effect of obtaining the buckling resistance can be promoted. Further, since the degree of integration in which the shoulder portion side overhanging portion 12 and the screw portion side overhanging portion 14 are in contact with each other increases, the strength as the support ring portion 10 protruding outward from the mouth and neck portion 4 is increased. Since the limit of the load that can be received without increasing the deformation of the support ring portion 10 itself is increased, the usability of the support ring portion 10 can be improved.
[0065]
Next, the can body in which the support ring portion 10 is formed on the mouth and neck portion 4 in this manner is transferred again to the neck and flange forming step as shown in FIG. After the neck-in process and the flange process are sequentially performed on the opening which is the lower end of the body part 2 on the side opposite to the part 4, it is transferred to a bottom cover tightening process (not shown). In the process, the bottom cover 5, which is a separate member made of a metal plate material, is integrally formed on the flange portion formed at the lower end opening of the body portion 2 using a double winding method by a seamer (can lid winding machine). The bottle-shaped can 1 shown in FIG.
[0066]
The bottle-type can 1 is filled with a predetermined content into the bottle-type can 1 from the opening of the mouth-and-neck portion 4 using a PET bottle transfer means and a filling line, and transferred to the capping step.
[0067]
In this capping step, as shown in FIG. 5, a cap 22 made of a metal plate is attached to the mouth and neck portion 4 of the can bottle type can 1, and the bottle type can 1 is sealed.
[0068]
That is, the capping device 23 to which the cap 22 is attached includes a top pressure 24, a screw forming roll 25, a lower end squeezing roll 26, and a support member 27.
[0069]
In the capping process using this capping device 23, an aluminum alloy cap 22 having a tamper evidence mechanism is placed on the neck 4 of the transferred bottle-type can 1, and just below the capping device 23. Be transported. Next, the top pressure 24 is lowered to press the top plate portion of the cap 22 with a predetermined top pressure pressure, and the support member 27 supports the support ring portion 10 formed on the mouth neck portion 4 of the bottle-type can 1. To do.
[0070]
The screw forming roll 25 is arranged at the starting end of the screw part formed on the cap 22 located above the skirt part of the cap 22, and the lower end squeezing roll 26 is arranged at the lowermost end part of the cap 22. Pressing in the center direction is started.
[0071]
That is, by rotating and lowering the screw forming roll 25 gradually, the capping device itself 23 is rotated around the cap 22, whereby the screw portion corresponding to the screw portion 7 positioned inward is formed on the cap 22 skirt portion. Is formed. At this time, the lower end squeezing roll 26 squeezes the lowermost end portion of the cap 22 and follows the lower side surface of the annular bead portion 8 below the screw portion 7 of the bottle-type can 1, thereby preventing the cap 22 from loosening. A bridge is formed that allows confirmation of opening.
[0072]
Then, the screw forming roll 25 and the lower end squeezing roll 26 are separated from the cap 22 and retracted to the storage position, and the top pressure 24 is separated from the upper surface of the cap 22 and retracted to the storage position, thereby completing the capping of the bottle-shaped can 1. To do.
[0073]
And when the drink with which the bottle-shaped can 1 sealed in this way is a low acid drink with high PH, the retort sterilization method which heat-sterilizes after filling the bottle-shaped can 1 is used. For example, the retort process which heats to 125 degreeC and maintains this temperature for 30 minutes is performed, and it finally becomes a product and is shipped.
[0074]
Here, the resin-coated metal plate that can be used in the present invention will be described. The metal plate to be resin-coated is not particularly limited, and is subjected to surface treatment such as an aluminum alloy plate and various metal platings and chemical conversion treatments. Surface-treated steel sheets such as ultrathin tin-plated steel sheets, nickel-plated steel sheets, electrolytic chromic acid-treated steel sheets, and galvanized steel sheets can be used. As the surface treatment, it is desirable to use a surface-treated metal plate for the purpose of ensuring adhesion with the thermoplastic polyester resin film.
[0075]
For example, chromic acid chromic acid treatment or zirconium phosphate treatment, which is used as a surface treatment after molding of ordinary drawn iron cans, is applied. In the case of a processing degree, an organic-inorganic composite chemical conversion treatment of phosphoric acid or zirconium phosphate and an organic resin is effective. Specifically, for example, an aluminum alloy plate having a thickness of 0.24 mm to 0.38 mm, and 3004 series or 3104 series aluminum alloy specified in Japanese Industrial Standard (JIS), chromium is added in an amount of 1 to 40 mg / m. ² , Treatment with adhering phosphate chromate or zirconium 4-17 mg / m ² In addition, a material subjected to a chemical conversion treatment such as an attached zirconium phosphate treatment is used.
[0076]
Moreover, the steel plate in the present invention is a surface-treated steel plate having a thickness of 0.15 mm to 0.25 mm, for example, and the amount of adhesion on one side is 20 to 2000 mg / m on both sides of the steel plate. ² Nickel plating layer, 1 mg / m as the amount of C on one side of the upper layer ² ~ 100mg / m ² Those having a chemical conversion treatment film layer mainly composed of the above organic resin are used. In addition, the steel plate before nickel plating and chemical conversion treatment is not specifically limited, What is normally used as a steel plate for cans is applied.
[0077]
As the resin film coated on the metal plate, a thermoplastic polyester resin film having good heat resistance and characteristics suitable for can applications is used. Examples of the polyester resin include polyethylene terephthalate (PET) and polybutylene. Homopolymers such as terephthalate (PBT) and polyethylene isophthalate (PEI), copolymers such as copolymers of polyethylene terephthalate and polyethylene isophthalate, blends of such homopolymers, homopolymers and copolymers, etc. Examples thereof include blends and blend resins of copolymers. Lamination of a resin film to a metal plate is performed by a heat fusion method, a dry lamination method, an extrusion coating method, or the like. If the adhesiveness with the coating resin is poor, for example, a urethane adhesive, an epoxy adhesive, an acid An olefin adhesive, a copolyamide adhesive, and a copolyester adhesive can be interposed.
[0078]
Further, the melting point of the thermoplastic polyester resin used in the present invention can be appropriately selected depending on the degree of the copolymer, the selection of the resin to be blended and the blend ratio thereof. For example, the melting point (Tm) is 200 ° C. to 260 ° C. The resin film is applied. In addition, the resin-coated metal plate of the present invention is made amorphous after being laminated, after being heated and melted above the melting point of the thermoplastic resin film that has been thermally bonded, and then rapidly cooled below the glass transition point. A resin-coated metal plate in which biaxially oriented crystals remain on the upper layer side of the thermoplastic resin coating layer may be used.
[0079]
Further, as a method of laminating the thermoplastic resin to the metal plate, a thermosetting adhesive layer is applied to a thermoplastic resin film previously formed into a film, and the film is thermally bonded to the metal plate through the adhesive. In some cases, a thermosetting adhesive is preliminarily applied to a metal plate, and a thermoplastic resin melted from a T-die is extruded onto a preheated metal plate and thermally bonded to the thermoplastic resin film or metal plate. As means for applying the adhesive, appropriate known techniques such as gravure coating, die code coating, and roll coat coating can be applied.
[0080]
As an adhesive for bonding the metal plate and the thermoplastic resin, a thermosetting adhesive is used, and this thermosetting adhesive has a polyester polyurethane adhesive as a main agent, For example, a polyester urethane adhesive containing 2 to 6 parts by weight of an isocyanate curing agent and 0.05 to 2 parts by weight of a phosphoric acid curing catalyst is used as a main ingredient with respect to 100 parts by weight of a polyester polyurethane resin. The adhesive as the main agent must have good adhesion to the metal plate and the thermosetting resin, good workability, and have cohesive strength after processing.
[0081]
Note that if the above curing agent exceeds 6 parts by weight, the workability and cohesive strength after processing are reduced, whereas if it is less than 2 parts by weight, the adhesion is reduced. May occur. Therefore, it is preferable to eliminate these problems by adding an isocyanate curing agent in the range of 2 to 6 parts by weight with respect to 100 parts by weight of the resin.
[0082]
In addition, when titanium oxide powder, which is a white pigment, is added to the above thermosetting adhesive, the thermosetting adhesive is 60 to 150 mg / dm as a dry film weight. ² It is necessary to apply in the range.
[0083]
That is, the coating amount is 60 mg / dm ² If it is less than 1, the ability to conceal the metal base is insufficient, and this adhesive layer cannot be a base for ensuring color development and sharpness by the printing ink layer. On the other hand, the coating amount is 150 mg / dm ² If it exceeds 1, the adhesiveness of the adhesive itself, the workability, and the cohesive force after processing are reduced, so that the coating film may be peeled off during the subsequent molding of the can.
[0084]
Further, regarding the thermosetting adhesive to which the titanium oxide powder is added as described above, the thermosetting adhesive as the main agent is preferably one that does not develop color by thermosetting, and the titanium oxide to be added is a rutile type. Titanium dioxide is preferable in terms of hiding properties. Further, depending on the printing design applied to the outer surface of the can, it is preferable to add about several percent of a coloring pigment or toner other than white to the adhesive in addition to the titanium oxide powder which is a white pigment.
[0085]
For the resin-coated metal plate on which both sides of the thermoplastic resin layer are laminated via the thermosetting adhesive as described above, from above the thermoplastic resin layer on both sides, normal butyl stearate, liquid paraffin, A resin-coated metal plate coated with one or more types of lubricants such as petrolatum, polyethylene wax, edible oil, hydrogenated edible oil, palm oil, synthetic paraffin, dioctyl sebacate, etc. As a material, the bottle-shaped can 1 of this embodiment is manufactured by the manufacturing process shown in FIG.
[0086]
In the manufacturing process of the bottle-shaped can 1 of the present embodiment integrally molded from such a resin-coated metal plate, in the printing / painting process, first, with respect to the outer surface of the body 2 formed in a thin cylindrical shape, Desired designs such as letters and decorative patterns are printed.
[0087]
In this printing / painting process, for example, printing inks conventionally used for printing on cans such as printing inks using thermosetting urethane resin as a binder are used, and the printing method is dry offset. A printing method is preferred.
[0088]
Further, in order to protect the printing ink layer and to give gloss to the surface of the can body, a transparent curable coating (clear coating) is further applied on the printing ink layer. As this clear paint, conventionally used thermosetting paint, electron beam curable paint, ultraviolet curable paint, etc. are used, and this clear paint is used to further improve the slipperiness when transporting the bottle type can. A lubricant such as silicon or wax may be added to the paint.
[0089]
In the drying process following the printing / painting process, the printing ink layer by printing and the top coat layer by clear paint are sufficiently dried by hot air, and then laminated on the metal surface of the can through the adhesive layer. After the thermoplastic resin layer is heated and melted above its crystal melting temperature, it is further cooled to 160 ° C. within 8 seconds by blowing cold air of 40 ° C. or less, preferably 30 ° C. or less. Before entering the screw / curl forming process for severe processing, the thermoplastic resin layer crystallized by the processing so far is made amorphous again.
[0090]
The reason why the thermoplastic resin layer is made amorphous is as follows. First, even if the thermoplastic resin layer of the resin-coated metal plate as a material is made amorphous from the beginning, the thermoplastic resin layer is stretched by subsequent molding (cup molding, can body molding, top dome molding). Thus, when these moldings are completed, the thermoplastic resin layer is crystallized. In the subsequent screw / curl molding process, processing more severe than these moldings is to be performed. Therefore, before the screw / curl molding process is performed, the thermoplastic resin layer is amorphized again to improve the adhesion between the thermoplastic resin layer and the metal plate. Even if harsh processing is performed, the thermoplastic resin layer can follow the metal plate, and the adhesion workability between the thermoplastic resin layer and the metal plate during support ring molding is improved, so that The plastic resin layer can follow the metal plate.
[0091]
Furthermore, according to the manufacturing method of the bottle-shaped can 1 of the present embodiment, after the top dome is formed, the can is heated to a temperature equal to or higher than the melting point of the thermoplastic resin by using the heating of the oven to remove the lubricant. Since the thermoplastic resin is amorphized before entering the trimming step, the opening end portion of the body portion 2 on the opposite side of the can neck portion 4 is cut and the edges are aligned in the trimming step. In this case, it is possible to prevent the film hair of the thermoplastic resin layer from being generated at the cut portion. Similarly, since the printing ink layer and the topcoat layer are dried and cured in the drying process, the thermoplastic resin layer is amorphized before entering the screw / curl molding process. When the upper end of the mouth-and-neck portion 4 is cut and opened at the beginning of the molding process, it is possible to prevent the film hair of the thermoplastic resin layer from being generated at the cut portion. In addition, the can can be efficiently amorphized using the heating of the can in the drying process, and further, since there is no heating process in the subsequent can manufacturing process, By heating again, microcrystallization does not proceed to a part of the thermoplastic resin layer.
[0092]
Next, an embodiment of a pre-ring forming device 29 used for forming the annular projection 18 formed on the mouth-and-neck portion 4 of the bottle-shaped can 1 shown in FIG. Is described below. FIG. 6 is a front view showing a schematic configuration of a pre-ring forming device 29 that forms the annular convex portion 18 into the pre-ring 11. The annular convex forming device used for forming the annular convex portion 18 in the mouth / neck portion 4 includes an inner tool 16A disposed inside the mouth / neck portion 4 and an outer side of the mouth / neck portion 4. Since the configuration of the outer tool 17A to be arranged is different from the configurations of the inner tool 16 and the outer tool 17 of the pre-ring molding device 29, it is substantially the same configuration and operation as the pre-ring molding device 29. The description will be omitted.
[0093]
The pre-ring molding device 29 includes an inner tool 16 disposed inside the mouth-and-neck portion 4 and an outer tool 17 disposed outside the mouth-and-neck portion 4, the center axes of which are disposed parallel to each other. The mandrel 30 and the shaft member 31 are fixed to each other, and these members can be driven to rotate and can be moved in the longitudinal direction of the shaft and in directions toward and away from each other.
[0094]
That is, the inner tool 16 is formed in a disk shape having a predetermined thickness using a material harder than the metal used in the bottle-type can 1 and having excellent wear resistance. Is formed in an arc shape having a predetermined radius of curvature. The inner tool 16 is fixed to a small-diameter portion 30a of a mandrel 30 having an outer shape reduced in size similar to the outer shape of the bottle-type can 1 so that the axial center of the mandrel 30 is concentric. The shaft is rotationally driven about a shaft and is held by a support mechanism (not shown) so as to be movable in an arbitrary direction.
[0095]
Further, the outer tool 17 is made of a hard material having excellent wear resistance, like the inner tool 16, and the two pressing portions formed in a disk shape each having a predetermined thickness are predetermined in parallel with each other. The center distance of the shaft member 31 is fixed concentrically. The shaft member 31 is rotationally driven with the shaft center as a rotation center, and is held by a support mechanism (not shown) so as to be movable in an arbitrary direction.
[0096]
Therefore, when the bottle-shaped can 1 transferred from the upstream process is rotatably held by a holding device (not shown) and set in the pre-ring molding device 29, the bottle-shaped can 1 passes through the opening of the trunk portion 2. Then, the mandrel 30 is inserted into the bottle-shaped can 1, and the inner tool 16 is positioned and arranged inside the mouth-and-neck portion 4, and the mouth-and-neck portion 4 corresponds to the inner tool 16. An outer tool 17 is disposed outward. Then, the inner tool 16 is brought into contact with a predetermined position on the inner periphery of the mouth-and-neck portion 4 and the inner tool 16 is shown in FIG. 6 in a state where the body portion 2 of the bottle-type can 1 is held by the holding device. The bottle-shaped can 1 is rotationally driven in the clockwise direction. In this state, the outer tool 17 is moved in the radial direction approaching the inner tool 16, and the two outer edge portions of the outer tool 17 and the outer edge portion of the inner tool 16, as shown in FIG. A predetermined portion of the mouth-and-neck portion 4 of the bottle-shaped can 1 is sandwiched in the radial direction, and by adjusting the distance between the two, the predetermined portion of the mouth-and-neck portion 4 gradually becomes the inner tool 16. The outer ring is stretched radially outward along the outer shape, coined, and a pre-ring 11 is formed on the mouth and neck portion 4. When the pre-ring 11 is formed in this way, both the tools 16 and 17 are released, the mandrel 30 provided with the inner tool 16 is pulled out from the bottle-type can 1 and moved to the standby position, and the outer tool 17 is moved to the standby position, and the bottle-shaped can 1 formed with the pre-ring 11 is discharged from the pre-ring forming device 29 by a holding means (not shown) and delivered to a transfer means (not shown) for sending to the next process. It is.
[0097]
Next, an embodiment of the support ring forming apparatus 33 of the present invention used for forming the pre-ring 11 formed on the mouth-and-neck portion 4 of the bottle-type can 1 into the support ring portion 10 will be described below. FIG. 7A is a longitudinal sectional view showing a schematic configuration of a support ring molding apparatus 33 that molds the pre-ring 11 into the support ring portion 10, and FIG. 7B shows that the pre-ring 11 is formed. FIG. 7C is a longitudinal sectional view showing a state in which the bottle-shaped can 1 is set in the support ring forming device 33, and FIG. 7C shows a support ring portion on the mouth neck 4 of the bottle-shaped can 1 by the support ring forming device 33. It is a longitudinal cross-sectional view which shows the state by which 10 was shape | molded.
[0098]
This support ring forming device 33 has a two-part structure, is provided so as to be separable in the left-right direction in the figure, and supports a lower surface of the pre-ring 11, and a pair of support members 34A and 34B, similar to the support members 34A and 34B A pair of pressing members 35A, 35B provided with upper split molds 20A, 20B which are divided into two and are provided so as to be separable in conjunction with the support members 34A, 34B in the left-right direction in the drawing and press a predetermined range of the pre-ring 11 from above. These members 34A, 34B, 35A, and 35B are held by a drive mechanism (not shown), and are driven to be separated and coupled in the left-right direction in the drawing.
[0099]
These support members 34A and 34B include a lower mold portion provided so that the upper surface that is in contact with the lower surface of the pre-ring 11 is flat and horizontal when both the support members 34A and 34B are joined together. And a frame member for stably holding the lower mold part.
[0100]
Further, the lower molds 21A and 21B have half the inner diameter secured to be equal to the outer diameter of the mouth and neck part 4 in plan view from the ends of the lower molds 21A and 21B opposed in the horizontal direction. A circular inner peripheral surface is formed.
[0101]
Further, a step 40 having a height at least twice the plate thickness of the support ring 10 is provided around the inner peripheral surface of the upper surface of the lower molds 21A and 21B. Therefore, as will be described later, when the bottle-shaped can 1 is set in the support ring forming device 33 and the pressing members 35A and 35B are driven downward to press the pre-ring 11 and deform it into a support ring, Since the lower surfaces of the members 35A and 35B are brought into contact with the upper surface of the holding portion, further movement of the pressing members 35A and 35B is prevented, and the support formed by the upper split molds 20A and 20B of the pressing members 35A and 35B. An excessive pressing force is not applied to the ring portion 10.
[0102]
The pressing members 35A and 35B include upper split molds 20A and 20B whose outer peripheral shapes are the same as the inner peripheral shapes of the lower split molds 21A and 21B of the support members 34A and 34B. At the lower end of 20B, an arc-shaped pressing surface having a predetermined width is formed.
[0103]
Next, the operation of the support ring forming apparatus 33 will be described. That is, as shown in FIG. 7A, when the bottle-shaped can 1 is stopped at the molding position of the support ring molding device 33 in an upright posture by the holding means (not shown), the above-described support is performed from the left and right. The members 34A and 34B and the pressing members 35A and 35B are moved to the molding position, and the lower surface of the pre-ring 11 is supported by the support members 34A and 34B as shown in FIG. The bottle-type can 1 is set in the support ring molding device 33 in a state. Then, as shown in FIG. 7 (c), the pressing members 35A and 35B are driven downward, and a predetermined range on the upper surface of the pre-ring 11 is pressed from above by the upper split molds 20A and 20B of the pressing members 35A and 35B. As a result, the support ring portion 10 is formed. Finally, the support members 34A and 34B and the pressing members 35A and 35B are moved from the molding position to the standby position, and the bottle-shaped can 1 in which the support ring is molded is discharged from the support ring molding apparatus 33 by the holding means, and the next process Is delivered to a transfer means (not shown) for delivery.
[0104]
As described above, according to the present embodiment, the cross-sectional shape of the shoulder-side overhanging portion that is substantially horizontal and the thickness of the shoulder-side overhanging portion that is continuous with the shoulder-side overhanging portion is 1.3. Or a coating film adhered to the inner surface of the outer peripheral edge by integrally forming a support ring composed of an outer peripheral edge having a curvature radius of 2.8 times and a threaded portion side protruding portion. Since the stress generated in the film is relieved, damage to the coated film is prevented, and sufficient corrosion resistance can be ensured by protecting the coated film.
[0105]
In addition, since the curvature radius of the outer peripheral edge portion is smaller than 2.8 times the plate thickness, the ratio of the curved portion of the outer peripheral edge portion to the horizontal portion of the support ring portion is reduced. The lower surface of the horizontal portion can be used as a guide surface or a support surface during conveyance.
[0106]
That is, by forming the support ring part integrally with the mouth and neck of the bottle-shaped can formed in the same bottle shape as the PET bottle in this way, the existing PET bottle production line can be used as it is in the bottle-shaped can. be able to. In other words, the support ring unit formed integrally with the mouth-and-neck portion of the bottle-shaped can can be supported and transported in the same manner as the PET bottle, and the transport means for the PET bottle installed along the production line is used. And a production line for PET bottles can be used.
[0107]
Therefore, by providing a support ring portion in the mouth and neck of the bottle-type can in this way, using this support ring, the bottle-type can can be transferred using the conventional PET bottle transport means, The equipment of the conventional beverage filling line with PET bottles can be used as it is, the beverage can be filled into the bottle-shaped cans, the transporting device can be made the same, and the manufacturing equipment can be shared. The investment cost of equipment can be saved. That is, for example, a transfer means using a support ring and a beverage filling line for cans can be shared by PET bottles and bottle-shaped cans, and installation space and equipment costs can be greatly reduced. .
[0108]
In addition, since the load applied to the can body in the axial direction during capping can be supported by the support ring portion or both the support ring portion and the can bottom portion, the buckling load acting on the can body can be reduced or eliminated. . For this reason, it is not necessary to reinforce the can body in order to withstand capping, and the can body can be thinned.
[0109]
That is, for example, when a metal cap is tightened, generally the cap is put on the mouth and neck, the threaded part formed on the mouth and neck of the bottle-shaped can is rolled on the side of the cap, and the top surface of the cap A tightening operation for narrowing the corner portion (side seal portion) is performed, and this operation is called roll-on capping.
[0110]
In this embodiment, since it can be supported and capped by the support ring part, even if there is a variation in the overall height of the can from the bottom of the can to the opening of the mouth and neck, there is no effect of this variation. Since capping can be performed, stable capping can be performed, the tightness of the wrapping can be improved, and the product quality as a bottle-shaped can can be improved.
[0111]
That is, in the case of the configuration supported by the bottom of the can body, even if the movement amount of the same member is secured in the axial direction for capping when capping, due to the variation in the height of the entire can, Since the position in the vertical direction where the capping member comes into contact with the mouth and neck and the load starts to be applied is different, the load applied to the mouth and neck varies. However, when supported by the support ring part, the length of the part from the support ring part below the support ring part in the axial direction to the bottom of the can becomes irrelevant. Can be avoided.
[0112]
In addition, the shoulder projecting portion and the threaded portion projecting portion forming the support ring portion are substantially elastic in the support ring portion because at least a part of the inner wall surface is in contact with and in contact with each other. This prevents a gap that acts automatically, so that even when pressed from the opening side of the mouth and neck, such as during capping, it is avoided that an uneven load due to the gap occurs. It is possible to prevent the portion above the support ring portion from buckling unevenly, and the quality of the product can be improved.
[0113]
Furthermore, among the series of processes for manufacturing bottle-shaped cans, the process of forming the support ring part is arranged after the lubricant removal process, so that the screw part and the support ring part are formed on the mouth and neck part. However, since cracks and the like can be prevented from occurring in the molded part and the nearby coating film, the corrosion resistance by the coating film is sufficiently secured, and the product quality as a bottle-shaped can can be improved.
[0114]
In addition, when forming the support ring part on the neck of the bottle-type can, in addition to forming the pre-ring part and re-molding it from the pre-formed pre-ring part to the support ring part, By forming the pre-ring part on the neck and neck by a multi-stage spin roll molding process, the amount of deformation required in each stage is reduced, and the other parts of the mouth and neck other than the part to be deformed are reduced. It can be deformed with a sufficient margin without giving an extra influence, and a dedicated molding tool is used for each stage, so that the shape accuracy and dimensional accuracy of the pre-ring portion can be improved. As a result, the shape accuracy and dimensional accuracy of the support ring portion re-formed from the pre-ring portion formed in this manner are also improved, and the product quality as a bottle-type can can be improved.
[0115]
Here, the correspondence between the configuration of the embodiment and the configuration of the present invention will be described. The bottle-type can 1 corresponds to the bottle-type can of the present invention, the trunk portion 2 corresponds to the trunk portion of the present invention, and the shoulder. The portion 3 corresponds to the shoulder portion of the present invention, the mouth and neck portion 4 corresponds to the mouth and neck portion of the present invention, the screw portion 7 corresponds to the screw portion of the present invention, and the support ring portion 10 corresponds to the support ring of the present invention. The pre-ring 11 corresponds to the pre-ring of the present invention, the shoulder-side overhanging portion 12 corresponds to the shoulder-side overhanging portion of the present invention, and the outer peripheral edge portion 13 corresponds to the outer peripheral edge portion of the present invention. The threaded portion side overhanging portion 14 corresponds to the threaded portion side overhanging portion of the present invention, the inner tools 16, 16A correspond to the inner tool of the present invention, and the outer tools 17, 17A correspond to the outer tool of the present invention. The annular projection 18 is the annular projection of the present invention. The metal cap 22 corresponds to the cap of the present invention, the radius of curvature R corresponds to the radius of curvature of the outer peripheral edge of the present invention, and the radius of curvature r corresponds to the shoulder overhanging portion and shoulder side cylindrical portion of the present invention. This corresponds to the radius of curvature of the connecting portion.
[0116]
As mentioned above, although one embodiment of the bottle type can of the present invention was described, the present invention is not limited to the above embodiment. For example, for printing / coating on the can body, the body of the can body It is not limited to the method of printing and painting on the outer surface in order, and then drying, so that a printed resin film on which a printing ink layer or topcoat layer has been formed in advance is heat-bonded to the body of the can It is possible not only to use the body part as the printing area, but also to the body part at the stage of the bottomed cylindrical can before forming the mouth and neck part and the shoulder part. By printing and painting, it is also possible to make the printing area up to a part of the shoulder of the can after molding.
[0117]
Furthermore, the shape of the bottle-shaped can is not limited to the side seamless type bottle shape shown in the above embodiment, and the can body and the bottom of the can are integrally formed by drawing and ironing from a resin-coated metal plate. It may be a bottle-shaped can of other shapes such as a mono-metal type bottle-shaped can having a neck portion formed by reducing the diameter of the opening end of the mouth and further having a screw portion formed on the mouth-neck portion. Needless to say, the design can be appropriately changed.
[0118]
【The invention's effect】
According to the invention of claim 1, even if the support neck is formed by forming the mouth and neck portion, the outer peripheral edge is set to a radius of curvature 1.3 to 2.8 times the plate thickness. The stress generated on the coated film attached to the inner surface of the film is relieved to prevent damage to the coated film, and sufficient corrosion resistance can be secured by protecting the coated film. Since the proportion of the outer peripheral edge occupied is small, the lower surface of the horizontal portion of the shoulder side overhanging portion can be used as a guide surface or a support surface during transportation, and has been conventionally used as a transfer means using a support ring. The PET bottle equipment can be diverted without major modifications, and the process line for filling beverages into cans can be shared by PET bottles and bottle-type cans. Can be, it is possible to significantly reduce the installation space and equipment cost.
[0119]
According to the invention of claim 2, in addition to obtaining the same effect as that of the invention of claim 1, a sufficient horizontal surface supported by the lower surface of the shoulder overhanging portion is secured, so the support ring portion is provided. Since it can be used stably as a guide surface and a support surface during transportation, and the surface of the shoulder side overhanging portion facing the screw side overhanging portion is similarly increased in the horizontal and flat surface portion, It can be set as the structure which fully ensured the contact area of a part side overhang | projection part and a thread part side overhang | projection part, and in this case, the effect of obtaining said buckling resistance can be accelerated | stimulated.
[0120]
According to the invention of claim 3, among the series of steps for manufacturing the bottle-shaped can, the step of forming the support ring portion is arranged after the lubricant removing step, so that the screw portion and the neck portion are arranged. Even if the support ring part is molded, cracks and the like can be prevented from occurring in the molded part and the nearby coating film, so that sufficient corrosion resistance due to the coating film can be ensured. Product quality can be improved.
[0121]
According to the invention of claim 4, in addition to obtaining the same effect as that of the invention of claim 3, by forming the pre-ring part by performing a multi-stage spin roll molding process on the mouth and neck, Since the amount of deformation at each stage is reduced, the neck and neck can be deformed without difficulty, and the shape accuracy and dimensional accuracy of the pre-ring can be improved. The shape accuracy and dimensional accuracy of the ring portion can be improved, and the product quality as a bottle-type can can be improved.
[Brief description of the drawings]
FIG. 1 is a partially cutaway front view showing a bottle-shaped can according to an embodiment of the present invention, the right half of which is a cross section.
FIG. 2 is a partially enlarged cross-sectional view illustrating the bottle-type can according to the present embodiment and enlarging and showing the vicinity of the mouth and neck of the bottle-type can.
FIG. 3 is a process diagram showing an outline of the production process of the bottle-shaped can of this example.
4A and 4B show an example of a forming process of the support ring part of this example, FIG. 4A is a cross-sectional view showing a first process of forming a pre-ring, and FIG. 4B is a first view of forming the pre-ring. It is sectional drawing which shows the process of 2, (c) is sectional drawing which shows the process of shape | molding a support ring part from a pre ring.
FIG. 5 is a front view showing a schematic configuration of a capping device used in the bottle-type can of this example.
6 is a front view showing a schematic configuration of a pre-ring molding apparatus used in the process shown in FIG. 4 (b) used for the bottle-shaped can of this example. FIG.
FIGS. 7A and 7B illustrate a schematic configuration of a support ring molding apparatus used in the bottle-shaped can of the present example. FIG. 7A is a longitudinal sectional view illustrating a schematic configuration of the support ring molding apparatus, and FIG. FIG. 5C is a longitudinal cross-sectional view showing a state where the bottle-shaped can formed with is set in the support ring molding device, and FIG. It is a longitudinal cross-sectional view which shows the shape | molded state.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Bottle type can, 2 ... Can trunk, 3 ... Shoulder part, 4 ... Mouth neck part, 5 ... Bottom cover, 7 ... Screw part, 10 ... Support ring part, 11 ... Pre-ring, 12 ... Shoulder side projecting part , 13 ... outer peripheral edge part, 14 ... screw part side projecting part, 16, 16A ... inner tool, 17, 17A ... outer tool, 22 ... metal cap, 20A, 20B ... upper split type, 21A, 21B ... lower split type .

Claims (4)

A bottle type with a structure in which a small-diameter neck and neck, a shoulder with an inclined surface or a curved surface, and a large-diameter body are integrally molded from a resin-coated metal plate with a resin layer laminated on both sides of a thin metal plate In the can,
A screw part to which a cap is screwed and a support ring part formed by molding a part of a cylindrical part from the screw part of the mouth and neck part to the shoulder part are provided on the mouth and neck part,
The support ring portion is connected to a horizontal shoulder-side overhanging portion and the shoulder-side overhanging portion, and the cross-sectional shape in the plate thickness direction is 1.3 to 2.8 of the plate thickness of the shoulder-side overhanging portion. It is formed in a circular arc shape with a double radius of curvature, and is located on the upper side of the shoulder-side overhanging portion, and at least part of the outer edge is in contact with the shoulder-side overhanging portion. A bottle-shaped can characterized by comprising a protruding portion on the screw side. The curl-side cylindrical portion and the shoulder-side cylindrical portion to which the support ring portion of the mouth-and-neck portion is connected are formed to have substantially the same diameter,
The cross-sectional shape in the thickness direction of the connecting portion between the shoulder projecting portion and the shoulder side cylindrical portion is formed in an arc shape having a radius of curvature of 1.0 mm or less. Bottle type can. A cup forming step of forming a cup shape by applying a lubricant on the surface of a resin-coated metal plate having a resin layer laminated on both surfaces of a thin metal plate and punching it, and the cup shape formed into the cup shape A can molding process for forming an object into a cylindrical can with a bottom having a small diameter and a thin body, and a body and a bottom near the bottom of the bottomed cylindrical can with a shoulder and an unopened small diameter cylinder and a small diameter cylindrical portion forming step of forming on the parts, and an open mouth step of opening by cutting the tip of the small-diameter cylindrical portion, the threaded portion forming step of forming the threaded portion on the outer peripheral surface of the small-diameter cylindrical portion having an opening Lubricating from the outer surface of the bottomed cylindrical can provided between the forming step of the bottomed cylindrical can whose body is thinned and the step of cutting and opening the tip of the small diameter cylindrical portion A lubricant removing step for removing the agent, and a small-diameter mouth-neck portion and an inclined surface or The method of manufacturing a bottle-shaped cans of manufacturing the bottle-shaped can of structure molded integrally with the shoulder portion having a curved surface and the large diameter of the body portion,
After the threaded portion forming process, before Symbol small-diameter cylindrical portion extending to the shoulder portion from the threaded portion, the pre-ring portion forming step of forming a pre-ring portion that protrudes outward in a convex bead shape by the inner tool and an outer tool By pressing the pre-ring part in the axial direction, the plate thickness of the horizontal shoulder part overhanging part and the shoulder part overhanging part continuous with the shoulder part overhanging part is 1.3 to 2. The support ring part is composed of an arcuate outer peripheral edge having a radius of curvature of 8 times and a threaded part projecting part which is continuous with the outer peripheral part and at least a part of which is in contact with the shoulder part projecting part. A bottle-shaped can manufacturing method comprising a support ring forming step for forming.   The method of manufacturing a bottle-shaped can according to claim 3, wherein the step of forming the pre-ring portion is configured by a spin roll forming process of at least two stages.

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