JP6534377B2 - Method of manufacturing liner cap - Google Patents

Description

  The present invention relates to a method of manufacturing a liner cap for sealing a container having a screw on which a cap for beverage or the like is screwed.

  As a cap mounted on a container made of steel, aluminum alloy or the like, one having a metal cap body and a liner provided on the inner surface of a top surface of the cap body is known. The liner abuts on the top of the mouth of the container so that the inside can be sealed.

  Conventionally, in a cap (a cap with a liner) including such a liner, a heated resin ball is dropped to the inner surface of the top surface of the cap body, and a liner having a predetermined shape is formed by embossing using a molding die. In-shell mold type metal caps were the mainstream. However, such a cap with a liner bonds the top surface of the cap body to the liner, so that when the container is opened, the mouth of the container and the liner rub against each other to make the torque very high, making it difficult to open the container. Was a problem.

  Therefore, as in Patent Document 1, a hook portion (bent portion) projecting inward is provided on the side portion near the top surface portion (top plate portion) of the cap main body, and the liner formed into a sheet is provided with the cap main body. It is done to be locked. In this cap, the liner is attached to the cap body by being disposed between the hook portion and the inner surface of the upper surface portion without adhering to the inner surface (upper surface) of the upper surface portion. And in patent document 1, a liner is comprised by a sliding layer and a soft layer, This liner is a sealing layer on the hard sheet, after inserting hard sheets, such as a polypropylene used as a sliding layer, in a cap body. It is described that it mold-molds resin (soft layer), such as an elastomer, as this.

JP, 2008-213039, A

  However, since the sliding layer is formed by punching a hard sheet into a disk shape, punching scraps are generated, the usage rate of the material is low, and the manufacturing cost of the liner is increased. In addition, the sliding layer does not come in direct contact with the beverage etc. inside the container, so it is conceivable to recycle it, but it is difficult as a practical matter.

  The present invention has been made in view of such circumstances, and it is an object of the present invention to provide a method of manufacturing a liner cap which can increase the material usage rate of the liner.

  The inventor considered forming the sliding layer also by an in-shell mold formed in the cap body.

A method of manufacturing a liner cap according to the present invention includes a cap body including a top surface portion and a cylindrical portion substantially suspended from the periphery of the top surface portion, and a liner provided on the inner surface of the top surface portion. A method of manufacturing a liner cap capable of sealing a mouth portion of a cap body, comprising: punching a plate material of aluminum or aluminum alloy into a cup shape and coating a paint made of epoxy phenol resin on the inner surface of a top surface portion Forming the cap body, forming the slide layer slidable with the top surface of the cap body by molding of a resin made of polyethylene or polypropylene on the inner surface of the top surface, and Forming a sealing layer laminated on the dynamic layer and softer than the sliding layer and in contact with the opening of the container by resin molding, and the sliding layer and the sealing layer Characterized by comprising and a sealing layer forming process of forming the liner.

  It is possible to form a liner by molding both the sliding layer and the sealing layer inside the cap body, and to increase the material usage rate because no punching waste occurs as in the case of punching and molding a hard sheet. Can. Further, since the liner having the sliding layer and the sealing layer can be formed only by the in-shell mold, the liner punching process and the liner fitting process can be eliminated, and the productivity can be dramatically improved.

In the method of manufacturing a cap with liner according to the present invention, in the cap main body forming step, a hook portion for projecting radially inward in the vicinity of the top surface portion of the cylindrical portion to lock the sliding layer is formed. In the sliding layer forming step, the molten resin disposed on the inner surface of the top surface portion is pressed by a punch having an outer diameter smaller than an inscribed circle formed by the tip of the hook portion, and The sealing layer may be formed to have an outer diameter larger than the tangent circle, and the sealing layer may be formed to have an outer diameter smaller than the inscribed circle in the sealing layer forming step.
In this case, the resin is pressed against the inner surface of the top surface of the cap main body in a state in which the hook portion is formed, by pressing the molten resin with a punch smaller than the inscribed circle formed by the hook portion. The diameter of the sliding layer is made to flow more than it is, and the outer diameter of the sliding layer can be formed larger than the inscribed circle of the hook portion without being restricted by the mold. Thus, even when the sliding layer is formed by molding in the cap main body, the sliding layer can be provided on the inner surface of the top surface portion by being supported by the hook portion. Therefore, the opening torque can be maintained relatively low.

In addition, it is good to provide the adhesion prevention measure process which gives the adhesion prevention measure of the said sliding layer to the inner surface of the said top | upper surface part before the said sliding layer formation process.
In the adhesion preventing step, for example, adhesion between the sliding layer and the top surface portion is prevented by applying a masking ink to the inner surface of the top surface portion, or a non-volatile organic liquid (glycerin or the like is formed on the inner surface of the top surface portion. This is a step of applying silicone oil or the like, and further applying laser irradiation to alter the coated surface of the inner surface of the top surface to give non-adhesiveness.

In the method of manufacturing a liner cap of the present invention, the thickness of the portion of the sealing layer in contact with the mouth of the container may be thicker than the other portions.
By forming the thickness of the portion in contact with the opening of the sealing layer thicker than the other portions, it is possible to obtain high sealability, and to form a thin portion other than the portion in contact with the opening. The amount can be reduced, and the cost can be reduced.

In the method of manufacturing a liner cap according to the present invention, it is preferable that the surface of the sliding layer is provided with a radial gradient which is descending from the central portion toward the peripheral portion.
The surface shape having a radial gradient can be formed at the time of molding of the sliding layer by the pressing surface of the punch, and the radial gradient improves the flowability of the resin from the central portion to the periphery during molding of the sealing layer. It is possible to prevent the occurrence of liner chipping and thickness variations in the portion in contact with the opening of the sealing layer.

In the method of manufacturing a liner cap according to the present invention, a recess may be provided in the center of the surface of the sliding layer.
By providing the depression, centering of the resin at the time of forming the sealing layer can be easily performed, the resin can flow uniformly from the central portion to the peripheral portion, and generation of liner chipping and thickness variation can be prevented. .

  According to the present invention, the material usage rate of the liner can be increased by molding the liner comprising the sliding layer and the sealing layer by molding, and the sliding layer and the sealing layer can be formed only by the in-shell mold Therefore, the productivity of the liner cap can be dramatically improved.

It is the principal part side view which fractured a liner cap of a bottle can with a cap of an embodiment of the present invention. It is a fragmentary sectional view of the bottle can with a cap shown in FIG. It is a partially broken side view showing a cap with a liner before winding and tightening on a bottle can. It is A arrow line view (plan view) of the cap with a liner shown in FIG. It is the principal part top view which expanded FIG. It is an explanatory view showing a manufacturing process of a cap with a liner in this embodiment. It is explanatory drawing which shows the cap with a liner of other embodiment of this invention. It is explanatory drawing which shows the cap with a liner of other embodiment of this invention. It is explanatory drawing which shows the cap with a liner of other embodiment of this invention. It is explanatory drawing which shows the cap with a liner of other embodiment of this invention.

Hereinafter, embodiments of a method of manufacturing a cap with liner according to the present invention, a cap with liner, and a container with a cap will be described with reference to the drawings.
As shown in FIG. 1 and FIG. 2, for example, a 38 mm diameter aluminum or aluminum alloy (metal) bottle can 2 (a container according to the present invention), and the bottle can 2 The cap can 1 is made up of a cap 3 with a liner, which is a pill fur proof cap (also referred to as a PP cap) which is attached to the mouth 21 of the cap and tightly closed.

  In addition, the cap 3 with liner shown in FIGS. 1 and 2 is attached to the bottle can 2 by forming a plate of aluminum or aluminum alloy into a cup shape, and the cap 3 with liner before attachment is shown in FIG. As shown in FIG. 4, it has a cap main body 4 provided with a top surface portion 41 and a cylindrical portion 42 substantially hanging down from the peripheral edge of the top surface portion 41, and a liner 5 provided on the inner surface of the cap main body 4.

  The plate material for forming the cap body 4 uses a painted plate having inner and outer surfaces coated (inner surface: size varnish + top coat, outer surface: size coat + top coat (gloss)). In addition, various lubricant addition types are used for the top coat of the inner and outer surfaces as needed. For example, on the inner surface of the top surface portion 41, a paint in which a polyolefin wax or the like is added as a lubricant to a resin such as epoxy phenol is baked.

The liner 5 abuts on the opening 21 when the bottle can 2 is closed by the liner cap 3 and is formed so as to seal the inside of the bottle can 2. The liner 5 is disposed on the inner surface side of the top surface portion 41 of the cap body 4, and the sliding layer 51 sliding on the inner surface of the top surface portion 41 and the sliding layer 51 directly or an intermediate layer such as a barrier layer. And a sealing layer 52 that is softer than the sliding layer 51 and has a smaller outer diameter.
The sliding layer 51 is formed in a disk shape of polypropylene or the like. The sealing layer 52 is formed of an elastomer resin or the like softer than the sliding layer 51 and has a sealing function. The sealing layer 52 is formed in a circular shape coaxial with the sliding layer 51 and having a small diameter, as shown in FIG. Further, in the sealing layer 52, the outer peripheral portion 54 in close contact with the mouth portion 21 of the bottle can 2 is formed thicker than the central portion 55.

  Further, the cylindrical portion 42 of the cap main body 4 has a cylinder upper portion 44 and a cylinder lower portion 45 which are divided up and down through slits 43 formed intermittently in the circumferential direction on the lower end surface thereof. The upper part 44 and the lower part 45 of the cylinder are connected by a plurality of bridges 43a formed therebetween.

  Then, as shown in FIG. 1, a bulging portion 22 projecting radially outward is formed at the lower end portion of the mouth portion 21 of the bottle can 2 to which the cap 3 with liner is attached, A curled portion 24 formed by rounding the open end is formed above the bottle side screw portion 23 and the bottle side screw portion 23. The liner cap 3 placed on the opening 21 follows the shape of the bulging portion 22, the bottle side screw portion 23, and the curling portion 24 by, for example, screwing the cylindrical portion 42 inward with a screw roller (not shown) It is plastically deformed by pressing. Thus, the cap-side screw 46 is formed, and the lower end of the cylindrical portion 42 of the liner cap 3 attached to the opening 21 is engaged with the lower surface of the bulging portion 22, and the liner 5 is held by the curled portion 24. It is pressure-welded and the bottle can 2 is sealed to be a capped bottle can 1.

As shown in FIG. 3, the cylindrical portion 42 of the cap main body 4 has a plurality of knurled recesses 11 arranged in the circumferential direction in the vicinity of the top surface portion 41 of the cylinder upper portion 44 and an opening 12 for releasing the internal pressure at the time of opening. And a plurality of hooks 13 for locking the liner 5.
The knurled recess 11 and the hook portion 13 have a concave shape on the outer peripheral surface of the cylindrical portion 42, and by arranging them at intervals, an uneven surface is formed on the outer peripheral surface of the cylindrical portion 42. The frictional resistance between the liner cap 3 and the finger gripping it can be increased. This makes it possible to grip without sliding the hand, and can be opened easily.

The hook portion 13 is formed by radially inward pushing the lower portion of the notch formed along the circumferential direction of the cylindrical portion 42, and as shown in FIGS. 4 and 5, the radially inward chevron is formed. It is protrudingly formed in (V shape). Then, the opening 12 is formed by opening the cut.
Further, as shown in FIG. 3, the upper end surface 15 of the hook portion 13 is formed at a position separated from the inner surface of the top surface portion 41 by at least the thickness of the sliding layer 51 constituting the liner 5. The inscribed circle C (FIG. 4) formed by each hook portion 13 is set smaller than the outer diameter of the sliding layer 51 of the liner 5, and this sliding layer 51 is the upper end face 15 of the hook portion 13. The liner 5 is supported by the hook portion 13 and attached to the cap main body 4 by being disposed between the upper surface portion 41 and the inner surface of the top surface portion 41.
The opening 12 functions as a vent hole for releasing the gas inside the bottle can 2 to the outside when the liner cap 3 is rotated while breaking the bridge 43a. Further, the thickness of the liner 5, the outer diameter of the sliding layer 51 constituting the liner 5, the outer diameter of the sealing layer 52 and the like are determined according to the dimension of the cap body 4.

Next, a method of manufacturing the liner cap 3 of the present embodiment will be described with reference to FIG.
(Painting process)
First, the inner and outer surfaces of the plate member 40 forming the cap body 4 are coated. Usually, a size coat and a top coat are applied to the surface on the inner side of the cap body 4, a size coat is printed on the surface on the outer side as needed, and then a top coat (gloss) is applied. Their thickness is generally 1 to 10 μm, and each is baked and dried at 150 to 200 ° C. for 8 to 12 minutes.

(Cap body molding process)
Then, a lubricant is applied to the coated plate member 40 and punched into a cup shape by a press to form the top surface portion 41 and the cylindrical portion 42 of the cap main body 4. In addition, a notch is formed along the circumferential direction of the cylindrical portion 42, and the notch is opened by pushing the lower portion of the notch radially inward to open the notch, and a hook which is protruded radially inward (V-shaped) A plurality of portions 13 are formed. At this time, the opening 12 is formed by opening the cut.
In addition, when forming the hook part 13 and the opening part 12, processing of the knurled recessed part 11 and the bridge 43a etc. is also given.

(Adhesion prevention measures process)
Next, an adhesion preventing measure is applied to the inner surface of the top surface portion 41. The adhesion preventing measure is performed, for example, by applying a non-volatile organic liquid (glycerin or silicone oil or the like), or changing the coated surface of the plate 40 by laser irradiation to form a masking. In the coating process, it is also possible to apply an anti-adhesion measure in advance by applying a masking ink (lacquer) to the coated surface of the plate 40.

(Sliding layer forming process)
Then, the sliding layer 51 is formed on the cap body 4 to which the adhesion preventing measure has been applied by resin molding (in-shell mold). The formation of the sliding layer 51 is performed in a state where the cap body 4 is placed with the open end facing upward.
First, a fixed amount of a hard resin such as polyethylene extruded and melted from the extruder is supplied (dropped) to the center on the inner surface side of the top surface portion 41, and the molten resin R1 disposed on the inner surface of the top surface portion 41 is immediately cooled The sliding layer 51 is formed by pressing with the punch P1 of the mold M1.

The punch P1 is provided such that its movement in the pressing direction is guided by a guide G1 inserted into the cylindrical portion 42 of the cap main body 4, and the outer diameter is constituted by the tips of the hook portions 13 of the cylindrical portion 42. It is provided smaller than the inscribed circle C, and the pressing surface of the punch P 1 is pressed against the top surface portion 41 beyond the hook portion 13. Then, the molten resin R1 supplied to the center on the inner surface side of the top surface portion 41 is radially expanded by being pressed by the pressing surface of the punch P1, and the diameter is larger than the inscribed circle C of the hook portion 13 A disc-like sliding layer 51 is formed.
The peripheral portion of the sliding layer 51 is preferably formed so as not to contact the inner side surface of the cylindrical portion 42.
Further, since the adhesion preventing means is applied to the inner surface of the top surface portion 41, the sliding layer 51 is formed inside the cap main body 4 in the non-bonded state. Since the peripheral edge of the sliding layer 51 is provided with a diameter larger than the inscribed circle C of the hook portion 13, the peripheral edge of the sliding layer 51 is supported by the hook 13 and comes out of the cap main body 4 Instead, the inner surface of the top surface portion 41 is provided in a non-adhesive state.

(Sealing layer forming process)
Then, the sealing layer 52 is formed by inserting the mold M2 for molding in the cap main body 4 in a state where the sliding layer 51 is formed in the cap main body 4 and resin-molding an elastomer resin or the like. Ru.
The mold M2 for molding is constituted by a guide G2 and a punch P2 provided so as to be able to move back and forth in the guide G2, and a sealing layer 52 is formed by the inner peripheral surface of the guide G2 and the pressing surface of the punch P2. It has become so. The outer diameter of the guide G2 is set to be smaller than the inscribed circle C (see FIG. 4) of the hook portion 13, and the tip of the hook portion 13 is for the mold M2 when the mold M2 (guide G2) is inserted. By acting as a guide, centering (positioning) of the mold M2 is performed.

Then, the sealing layer 52 supplies (drops) a certain amount of soft resin such as elastomer extruded and melted from the extruder to the center of the sliding layer 51 supported by the cap main body 4, and the surface of the sliding layer 51 Is molded by pressing the molten resin R2 placed in the above with the punch P2 immediately cooled, whereby the liner 5 composed of the sliding layer 51 and the sealing layer 52 is formed.
At this time, the sealing layer 52 is formed by filling the space surrounded by the inner peripheral surface of the guide G2 and the pressing surface of the punch P2 with the molten resin R2, and is coaxial with the sliding layer 51 and smaller in diameter. The outer peripheral portion 54 in close contact with the opening 21 of the bottle can 2 is formed thicker than the central portion 55.

  The sliding layer 51 and the sealing layer 52 are completely adhered at the time of molding by selecting a material, but if the adhesion is weak, after the sliding layer 51 is formed, the surface of the sliding layer 51 is formed. A surface treatment process such as corona discharge treatment, glow discharge treatment, plasma treatment, anchor coating treatment, adhesive application and the like may be added.

Then, by performing capping processing in a state where the cap 3 with a liner is put on the mouth 21 of the bottle can 2, the cap 3 with a liner is adhered in a state of being wound around the mouth 21, and this embodiment The capped bottle can 1 is formed.
Capping processing of the liner cap 3 is performed using a capping device including a pressure block, a screw roller, a skirt roller, and the like. That is, the top surface 41 of the cap body 4 placed on the mouth 21 is pressed by the pressure block P in the direction of the bottom of the bottle can 2 as shown by the two-dot chain line in FIG. By drawing, the stepped portion 48 is formed on the shoulder portion of the cap 3 with a liner.

  Further, in this state, the cap side screw portion 46 is formed by a screw roller (not shown), and the pill fur proof portion 47 is wound around the bulging portion 22 of the mouth 21 by a skirt roller (not shown) Is done. In this case, a bottle side screw portion 23 and a bulging portion 22 are formed at the mouth 21 of the bottle can 2 to which the cap 3 with a liner (cap main body 4) is attached. In the cap 3, the cap-side screw 46 and the pill-ferr proof part 47 are plastically deformed so as to follow the shapes of the bottle-side screw 23, the bulging part 22 and the like. As a result, the cap 3 with liner is attached to the mouth 21 of the bottle can 2 and the bottle can 2 is sealed. At this time, the liner 5 is disposed inside the top surface portion 41 of the cap body 4 as described above, and the opening of the bottle can 2 is sealed by the liner 5.

In the bottled can 1 configured as above, when the liner cap 3 is rotated to open, the cylinder upper portion 44 on which the cap-side screw 46 is formed is the bottle-side screw 23 of the bottle can 2. Rotate while lifting up along. On the other hand, the lower part 45 of the cylinder in which the pill fur proof part 47 is formed is engaged with the bulging part 22 of the bottle can 2 and rotates without being integrally held with the upper part 44 of the cylinder.
At this time, each bridge 43a to which a pulling force in the upward direction and a pulling force (frictional force) in the circumferential direction are applied is broken independently and sequentially. And when each bridge | bridging 43a fractures | ruptures, the cylinder upper part 44 and the cylinder lower part 45 of the cap 3 with a liner are parted. Thereafter, by further rotating the cylinder upper portion 44 with respect to the bottle side screw portion 23 of the opening 21, the cylinder upper portion 44 of the cap 3 with liner can be detached from the bottle can 2 and opened. On the other hand, the lower portion 45 of the liner cap 3 is left in the bottle can 2 as a ring-shaped pill fur proof portion 47.

  In the liner cap 3 of the present invention, the punch formed on the inner surface of the top surface portion 41 of the cap main body 4 in a state in which the hook portion 13 is formed has a diameter smaller than the inscribed circle C formed by each hook portion 13 By pressing the molten resin R1 with P1, the molten resin R1 is caused to flow by expanding the diameter of the pressing surface of the punch P1, and the hooks of the sliding layer 51 are not restricted by the mold. It can be formed larger than the inscribed circle C of the part 13. Thus, even when the sliding layer 51 is formed by molding in the cap main body 4, the sliding layer 51 in the non-adhered state can be supported by the hook portion 13 on the inner surface of the top surface portion 41. . Therefore, the opening torque can be maintained relatively low.

  On the other hand, since the sealing layer 52 is formed in a state where the peripheral portion is restrained by the guide G2 when pressed by the punch P2, the thickness of the outer peripheral portion 54 in close contact with the opening 21 of the bottle can 2 is constant. Thus, high sealability can be secured. In addition, the thickness of the outer peripheral portion 54 of the sealing layer 52 is formed to be thicker than that of the other portion (the central portion 55), and high sealing performance can be obtained. Therefore, the material usage fee can be reduced, and the cost can be further reduced.

  Further, the liner 5 can be formed by molding both the sliding layer 51 and the sealing layer 52 inside the cap main body 4 and no punched chips are generated as in the case of molding a hard sheet. , Can increase the material usage rate. Since the liner 5 having the sliding layer 51 and the sealing layer 52 can be formed only by the in-shell mold, the liner punching process and the liner fitting process can be eliminated, and the productivity can be dramatically improved.

In the above embodiment, the liner 5 is configured by forming the disc-like sliding layer 51 in the cap main body 4 and forming the sealing layer 52 on the surface (flat surface) of the sliding layer 51. However, as in the cap 3A with liner shown in FIG. 7, the surface S of the sliding layer 51A can be configured to have a radial gradient which is a downward slope from the central portion to the peripheral portion.
The radial gradient of the surface S of the sliding layer 51A can improve the flowability of the molten resin from the center to the periphery during molding of the sealing layer 52A, so the liner chipping and thickness of the peripheral part of the sealing layer 52A Can be prevented from occurring. The surface shape of the sliding layer 51A having a radial gradient can be formed when the sliding layer 51A is formed by the pressing surface of the punch.

Further, as in the cap 3B with liner shown in FIG. 8, by providing the depression 57 in the center of the surface of the sliding layer 51B, the centering of the molten resin R2 can be easily performed at the time of molding of the sealing layer 52B. R2 can flow uniformly from the central portion to the peripheral portion. This can prevent the occurrence of liner chipping and thickness variations.
Furthermore, as in the cap 3C with liner shown in FIG. 9, a radial gradient is provided on the surface of the sliding layer 51C in such a manner as to make a downward slope from the central portion to the peripheral portion. Good. In this case, when molding the sealing layer 52C, centering of the molten resin R2 can be easily performed, and the fluidity of the molten resin R2 can be improved by the radial gradient of the surface S of the sliding layer 51C.
Further, in the above embodiment, as shown in FIGS. 2 and 3, the hook portion 13 is formed by pressing the lower portion of the cut formed along the circumferential direction of the cylindrical portion 42 radially inward. Like the cap 3D with liner shown in FIG. 10, the hook portion 13 can also be formed by pressing the top surface 41 side of the cut inward in the radial direction. In this case, it is possible to prevent the sliding layer 51 from blocking the opening 12 for releasing the internal pressure at the time of opening.

The present invention is not limited to the above embodiment, and various modifications can be made without departing from the scope of the present invention.
For example, in the above embodiment, although the cap can and the liner cap attached to the bottle can have been described, the container of the cap container in the present invention is not limited to the bottle can, In addition to bottle cans, containers such as glass bottles and PET bottles are also included.

1 Bottle can with bottle can (container with cap)
2 bottle can (container)
3, 3A to 3D Liner cap 4 Cap body 5, 5A to 5C Liner 11 Nal recess 12 Opening 13 Hook part 21 Mouth part 22 Expansion part 23 Bottle side screw part 24 Curl part 41 Top part 42 Cylindrical part 43 Slit 43a Bridge 44 cylinder upper portion 45 cylinder lower portion 46 cap side screw portion 47 pill fur proof portion 48 step portion 51, 51A to 51C sliding layer 52, 52A to 52C sealing layer 54 outer peripheral portion 55 central portion 57 hollow

Claims (2)

A cap with a liner having a cap body including a top surface portion and a cylindrical portion substantially suspended from the periphery of the top surface portion, and a liner provided on the inner surface of the top surface portion, which can seal the mouth of the container. A method of manufacturing, comprising: forming a cap body formed by punching a plate material of aluminum or aluminum alloy in a cup shape and coating a paint made of epoxy phenol resin on the inner surface of a top surface; A sliding layer forming step of forming a sliding layer capable of sliding on the top surface portion of the main body by molding of a resin made of polyethylene or polypropylene on the inner surface of the top surface portion; A sealing layer molding method comprising forming a sealing layer soft and in contact with an opening of the container by resin molding to form the liner comprising the sliding layer and the sealing layer. Method of manufacturing a liner cap with, characterized in that it comprises and.   In the cap main body forming step, a hook portion for projecting radially inward in the vicinity of the top surface portion of the cylindrical portion to lock the sliding layer is formed, and in the sliding layer forming step The sliding layer is formed to have an outer diameter larger than the inscribed circle by pressing the molten resin disposed on the inner surface of the top surface with a punch having an outer diameter smaller than the inscribed circle formed by the tip of the hook portion; The method according to claim 1, wherein in the sealing layer forming step, the sealing layer is formed to have an outer diameter smaller than the inscribed circle.

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