JP6431406B2 - Cap liner manufacturing method and manufacturing apparatus - Google Patents

Description

  The present invention relates to a method and an apparatus for manufacturing a cap liner in which a ring-shaped sealing layer is formed on a sliding layer.

  Conventionally, a cap liner in which a ring-shaped sealing layer is molded on a sliding layer such as PP (polypropylene) is known. For example, Patent Document 1 discloses a cap liner provided with a disk-shaped sliding layer and an annular (ring-shaped) sealing layer that is a flexible synthetic resin laminated on the sliding layer, and an apparatus for manufacturing the same. A manufacturing method is also described. When such a ring-shaped sealing layer is used, it is possible to reduce the weight of the liner and reduce the raw material.

  In this apparatus and method, a sliding layer is installed between the fixed side mold plate and the movable side template plate, and when the mold is clamped, an annular cavity is formed on the installed sliding layer, and the cavity is formed in the cavity. A ring-shaped sealing layer is formed on the sliding layer by injection molding the molten synthetic resin.

Japanese Patent No. 5603742

  Conventionally, a ring-shaped sealing layer is formed on the sliding layer. However, since the sealing layer is ring-shaped, the bonding area is small, and the adhesive strength between the sliding layer and the sealing layer is relatively small. There was an inconvenience. For this reason, when a strong force is applied in the direction in which the sealing layer is peeled off from the sliding layer, the sealing layer may be peeled off, and if the peeling occurs, the content liquid may leak. Therefore, there is a demand for higher adhesive strength between the sliding layer and the ring-shaped sealing layer.

  The present invention has been made in view of the above-described problems, and an object of the present invention is to provide a cap liner manufacturing method and manufacturing apparatus capable of forming a ring-shaped sealing layer on a sliding layer with high adhesive strength. .

  The present invention employs the following configuration in order to solve the above problems. That is, the manufacturing method of the cap liner according to the first invention is for a cap installed in a bottomed cylindrical cap body comprising a top plate portion and a cylindrical peripheral wall portion depending from the periphery of the top plate portion. A method of manufacturing a liner, wherein the cap liner includes a disc-shaped sliding layer disposed in contact with the inner surface of the top plate portion, and a synthetic layer that is laminated on the sliding layer and is more flexible than the sliding layer. An annular sealing layer that is a resin, and a resin application step of applying the molten synthetic resin to be the sealing layer on the sliding layer; and the applied synthetic resin in the annular shape A sealing layer molding step for molding into a sealing layer, and in the resin coating step, the molten synthetic resin is applied in a state where the sliding layer is heated in advance.

  In this cap liner manufacturing method, the sliding layer is pre-heated when the molten synthetic resin is applied, so that the sliding layer is preheated so that the adhesive strength of the synthetic resin applied thereon is increased. Is improved and high adhesion of the sealing layer is obtained.

The manufacturing method of the cap liner according to the second invention is the sheet according to the first invention, wherein the cap body is made of metal and the sliding layer is installed in the cap body before the resin coating step. An installation step, and in the resin coating step, the cap body is preheated by induction heating to heat the sliding layer.
That is, in this cap liner manufacturing method, the cap body is preheated by induction heating in a state where the sliding layer is installed in the cap body, so that the metal cap body is guided. By being heated by heating, the sliding layer disposed on the top plate portion can also be heated.

The manufacturing method of the cap liner according to the third invention is characterized in that, in the first or second invention, in the resin coating step, the sliding layer in the cap body is heated by applying hot air or infrared rays. And
That is, in this cap liner manufacturing method, the sliding layer in the cap body is heated by applying hot air or infrared rays, so that the sliding layer can be directly heated.
In addition, the mechanism for generating hot air or infrared rays is simpler and smaller than the induction heating method, and it is possible to reduce the space and cost of the apparatus.

  According to a fourth aspect of the present invention, there is provided a cap liner manufacturing apparatus comprising: a cap liner installed in a bottomed cylindrical cap body having a top plate portion and a cylindrical peripheral wall portion hanging from the periphery of the top plate portion. In the manufacturing apparatus, the cap liner is a disc-shaped sliding layer disposed in contact with the inner surface of the top plate portion, and a synthetic resin that is laminated on the sliding layer and is more flexible than the sliding layer. An annular sealing layer, and a resin application mechanism for applying the molten synthetic resin to be the sealing layer on the sliding layer; and the annular sealing layer for applying the applied synthetic resin And a sheet heating mechanism that preheats the sliding layer when the molten synthetic resin is applied.

  According to a fifth aspect of the present invention, there is provided the cap liner manufacturing apparatus according to the fourth aspect, wherein the cap body is made of metal, and the sheet heating mechanism is provided with the sliding layer installed in the cap body. The cap main body is preliminarily heated by induction heating and has an induction heating section for heating the sliding layer.

  The cap liner manufacturing apparatus according to a sixth aspect of the present invention is the direct heating apparatus according to the fourth or fifth aspect, wherein the sheet heating mechanism heats the sliding layer in the cap body by applying hot air or infrared rays. It has the part.

The present invention has the following effects.
That is, in the cap liner manufacturing method and manufacturing apparatus according to the present invention, the sliding layer is preheated when the molten synthetic resin is applied, so that the sliding layer is preheated. The adhesive strength of the applied synthetic resin is improved, and high adhesion of the sealing layer is obtained.
Therefore, according to the present invention, the sealing layer is hardly peeled off, and leakage of the contents liquid due to peeling can be prevented.

In the first embodiment of the cap liner manufacturing method and manufacturing apparatus according to the present invention, it is an explanatory view showing a schematic cross-section of the manufacturing process. In 1st Embodiment, it is schematic sectional drawing which shows a synthetic resin application | coating process to process order. In 2nd Embodiment of the manufacturing method and manufacturing apparatus of the cap liner which concern on this invention, it is explanatory drawing which shows a manufacturing process with a schematic cross section.

  A first embodiment of a cap liner manufacturing method and manufacturing apparatus according to the present invention will be described below with reference to FIGS. 1 and 2.

As shown in FIG. 1, the manufacturing method of the cap liner according to this embodiment includes a bottomed cylindrical cap body 1 including a top plate portion 1a and a cylindrical peripheral wall portion 1b suspended from the periphery of the top plate portion 1a. It is a manufacturing method of the liner 2 for caps installed in an inside.
The cap liner 2 includes a disc-shaped sliding layer 2a disposed in contact with the inner surface of the top plate portion 1a, and an annular shape that is a synthetic resin that is laminated on the sliding layer 2a and is more flexible than the sliding layer 2a. The sealing layer 2b.

The manufacturing method of the cap liner 2 includes a resin application step of applying a molten synthetic resin R to be a sealing layer 2b on the sliding layer 2a, and a sealing process in which the applied synthetic resin R is molded into an annular sealing layer 2b. A layer molding process.
Moreover, in this embodiment, the cap main body 1 is metal, and has the sheet | seat installation process which installs the sliding layer 2a in the cap main body 1 before the resin application | coating process.
In the resin application step, the synthetic resin R melted in a state where the sliding layer 2a is heated in advance is applied. That is, the resin coating step includes a step of heating the cap body 1 in advance by induction heating to heat the sliding layer.

As shown in FIGS. 1 and 2, the cap liner manufacturing apparatus of the present embodiment used in this manufacturing method has a resin application mechanism 4 for applying a molten synthetic resin R to be a sealing layer 2b on a sliding layer 2a. And a molding die mechanism 5 that molds the molten synthetic resin R into the annular sealing layer 2b, and a sheet heating mechanism 6 that preheats the sliding layer 2a when the molten synthetic resin R is applied. ing.
The sheet heating mechanism 6 includes an induction heating unit 7 that heats the sliding layer 2a by heating the cap body 1 in advance by induction heating in a state where the sliding layer 2a is installed in the cap body 1. Yes.

  The induction heating unit 7 includes a coil 7 a disposed below the top plate 1 a of the cap body 1. In the induction heating unit 7, an eddy current is generated in the top plate portion 1 a facing above the coil 7 a by electromagnetic induction by passing a high-frequency alternating current through the coil 7 a, and the top plate portion 1 a is contacted by the Joule heat without contact. Can be heated.

The manufacturing method of the cap liner of this embodiment will be described in more detail. The cap main body 1 to be used is previously formed with a liner locking protrusion 1c that protrudes inward from the cylindrical peripheral wall 1b.
For example, first, a coating material such as epoxyphenol or polyester is baked and applied 2 to several times to a thickness of 1 to 10 μm on the inner and outer surfaces of an aluminum alloy plate, and this is punched into a cup shape with a press. And a sewing machine part, a knurl, liner latching protrusion 1c, etc. are processed into this at the cup side, and cap body 1 is produced.

First, as shown in FIG. 1, the disc-shaped sliding layer 2 a is inserted into the cap body 1. At this time, the sliding layer 2a, which is a resin disk, is placed on the inner surface of the top plate portion 1a beyond the liner locking projection 1c.
The sliding layer 2a is made of PP (polypropylene), HDPE (high density polyethylene), PVC (polyvinyl chloride), various nylons, PET (polyethylene terephthalate), PAN (polyacrylonitrile), PBT (polybutylene terephthalate), PC ( (Polycarbonate) or the like.

Moreover, the hard sheet used for the sliding layer 2a was produced as follows. First, a single layer sheet for a hard sheet is produced from a hard synthetic resin using an extruder and a T die. The thickness of the single layer sheet at this time is preferably between 0.1 and 1.0 mm. More preferably, it is in the range of 0.2 to 0.8 mm. This synthetic resin requires a certain rigidity, and preferably has a flexural modulus of 400 MPa or more, although it depends on the thickness. Corona discharge treatment or the like may be performed on the surface of the hard sheet as necessary.
The sliding layer 2a is not necessarily made of synthetic resin, but may be, for example, an aluminum sheet laminated or painted on both surfaces with synthetic resin.

  Next, the cap body 1 on which the sliding layer 2a is installed is installed above the induction heating unit 7, and an alternating current is passed through the coil 7a to heat the top plate unit 1a. At this time, the top plate portion 1a is heated so that the surface temperature of the sliding layer 2a on the top plate portion 1a is 45 to 158 ° C. In the case of the PP sliding layer 2a, if the surface temperature of the sliding layer 2a is lower than 45 ° C, sufficient adhesive strength cannot be obtained, and if it exceeds 158 ° C, the sliding layer 2a is deformed or a strange odor is generated. Or The surface temperature of the sliding layer 2a is more preferably in the range of 65 to 105 ° C. Moreover, it is preferable that the preheating heating temperature of the sliding layer 2a is set to be 100 to 180 ° C. lower than the temperature of the melted synthetic resin R to be applied.

Next, in a state where the sliding layer 2a is preheated and heated, a molten synthetic resin R that becomes the sealing layer 2b is applied onto the sliding layer 2a.
As the synthetic resin R, an elastomer or a blend of a resin and an elastomer shows a good result. As the elastomer, olefin elastomer, styrene elastomer, polyamide elastomer, polyester elastomer, polyurethane elastomer, vinyl chloride elastomer and the like can be used.

  As shown in FIG. 2, the synthetic resin R is applied in a ring shape on the sliding layer 2 a by the resin application mechanism 4. The resin coating mechanism 4 is installed on an inner cylinder portion 8 in which a resin supply path 8a of the synthetic resin R is formed on the central axis, and is installed on the outer periphery of the inner cylinder portion 8 so as to be movable in the axial direction with respect to the inner cylinder portion 8. The outer cylindrical portion 9 is provided. The inner cylindrical portion 8 includes a conical portion 8b having a circular bottom at the bottom, and a branch path 8c formed on the conical shape portion 8b by branching a plurality of portions radially outward from the lower end of the resin supply passage 8a. Yes. The tips of these branch paths 8c are opened in an annular gap 8d formed on the outer periphery of the conical portion 8b with the outer cylindrical portion 9 moving upward.

The resin supply path 8a is connected to an extruder (not shown) capable of supplying a molten synthetic resin R.
When the outer cylindrical portion 9 is moved upward, an annular gap 8 d is formed between the conical portion 8 b of the inner cylindrical portion 8 and the lower portion of the outer cylindrical portion 9. That is, it is set so that the supplied synthetic resin R is pushed out from each branch path 8c into the gap 8d.

When the synthetic resin R is applied onto the sliding layer 2a, the inner cylindrical portion 8 and the outer cylindrical portion 9 are inserted from the upper opening of the cap body 1 as shown in FIG. The conical portion 8b of the inner cylindrical portion 8 is brought into contact with the layer 2a. Further, the outer cylindrical portion 9 is moved upward, and the tip of each branch path 8c is opened. In this state, the melted synthetic resin R is supplied to the resin supply path 8a. The synthetic resin R supplied to the resin supply path 8a is sent out by a predetermined amount into the outer peripheral gap 8d through each branch path 8c.
Next, in this state, as shown in FIG. 2 (b), when the outer cylindrical portion 9 is moved downward, the synthetic resin R in the gap 8d is pushed downward to form a ring shape on the sliding layer 2a. Dropped.

  Next, as shown in FIG. 1, a cylindrical molding punch 10 of the molding die mechanism 5 and a cylindrical molding sleeve 11 provided on the outer periphery of the molding punch 10 are inserted into the cap body 1, These lower parts are pressed against the synthetic resin R on the sliding layer 2a for embossing. Between the lower part of the molding punch 10 and the molding sleeve 11, a groove 10a having a rectangular cross section which is a cavity extending in an annular shape is formed. Further, the molding punch 10 has a cooling water passage (not shown) through which cooling water flows, and is cooled by the cooling water. Therefore, by pressing the lower portions of the molding punch 10 and the molding sleeve 11 against the synthetic resin R, the synthetic resin R is molded by the groove 10a and is cooled and solidified to form the annular sealing layer 2b.

Thus, in the manufacturing method of the cap liner of this embodiment, since the sliding layer 2a is preheated when the molten synthetic resin R is applied, the sliding layer 2a is preheated. The adhesive strength of the synthetic resin R applied to the surface is improved, and high adhesion of the sealing layer 2b is obtained.
In addition, in the state where the sliding layer 2a is installed in the cap body 1, the cap body 1 is preheated by induction heating to heat the sliding layer 2a, so that the metal cap body 1 is heated by induction heating. Thus, the sliding layer 2a disposed on the top plate 1a can also be heated.

  Next, a second embodiment of a cap liner manufacturing method and manufacturing apparatus according to the present invention will be described below with reference to FIG. Note that, in the following description of the embodiment, the same components described in the above embodiment are denoted by the same reference numerals, and the description thereof is omitted.

  The difference between the second embodiment and the first embodiment is that, in the first embodiment, the top plate 1a is heated by induction heating by the induction heating unit 7, and the sliding layer 2a is also heated by the heat. In contrast, in the cap liner manufacturing method according to the second embodiment, as shown in FIG. 3, as the sheet heating mechanism 26, a sheet direct heating unit that heats the sliding layer 2 a in the cap body 1 by applying hot air W thereto. 27 is used. That is, in the second embodiment, the sheet heating mechanism 26 includes the sheet direct heating unit 27 that can blow the hot air W from the plurality of air outlets 27a. The sheet direct heating unit 27 is disposed above the upper opening of the cap body 1 and directly blows the sliding layer 2a by blowing hot air W from the air blowing port 27a toward the internal sliding layer 2a. Yes.

  Thus, in 2nd Embodiment, since the hot air W is applied and heated to the sliding layer 2a in the cap main body 1, the sliding layer 2a can be heated directly. Further, the sheet direct heating unit 27 for generating hot air is simpler and smaller than the induction heating method, and the space of the apparatus can be reduced and the cost can be reduced.

A cap liner was manufactured based on the second embodiment, and the adhesive layer strength was evaluated by changing the preheating temperature of the sliding layer.
The sliding layer used was made of a PP sheet, and the sealing layer was made of an olefin elastomer or a styrene elastomer. The surface roughness of the sliding layer was set to Rz ≦ 20 μm.

  The sliding layer was preheated by blowing hot air from the upper opening side of the cap body, and the surface temperature of the sliding layer at that time was measured with a radiation thermometer to evaluate the adhesive strength and the sealing performance. In addition, as a comparative example, what formed the sealing layer without performing preheating was evaluated similarly. These evaluation results are shown in Table 1.

The measurement of the adhesive strength was performed under the following conditions.
・ Measurement temperature: Room temperature (room temperature)
・ Tensile strength: 780 mm / min
-Measuring machine: Model No. FGC-10 manufactured by SHIMPO
・ Pulling machine: ORIENTAL MOTOR Model No. 4RK25RGN-A (speed control motor) 4LB20N-2 (linear head)
In addition, the numerical value of Table 1 has described the peak value (N = 10).

The sealing property was evaluated by the following method.
First, the prepared cap with liner is attached to the can body, a hole is made in the bottom of the bottle can, the pressure is increased at 5 psi / sec (0.35 kg / cm ² ) in water, and the internal pressure leaks. It was confirmed.
At this time, it was held at 1 MPa for 1 minute, and if it did not leak, it was judged as good (◯), and if one or more leaked, it was judged as defective (x) (number of samples: N = 100).

Moreover, the sealing evaluation sample was prepared with the following capacity.
Water: 275 ml (total amount 338 ml), filling temperature 85 ° C., LN 2 filling Initial internal pressure setting 0.1 MPa (1.02 kgf / cm ² ): at 20 ° C.
The sample was allowed to stand for 1 day and returned to room temperature, and the sealing performance was evaluated.

As a result of these evaluations, all of the examples of the present invention in which the sliding layer was preheated had improved adhesive strength as compared with the comparative example, and good sealing performance was obtained. It can also be seen that the higher the preheating temperature, the higher the adhesive strength.
In addition, when preheating was lower than 45 degreeC, the improvement of adhesive strength was small and favorable sealing performance was not obtained. Moreover, when preheating was higher than 158 degreeC, the sliding layer of PP sheet | seat deform | transformed or the bad smell generate | occur | produced.
Furthermore, if the adhesive force between the sliding layer of the PP sheet and the sealing layer of the elastomer is weak, the sealing layer is shifted to the outside in the radial direction of the sliding layer due to the influence of heat and internal pressure, and it is detached from the bottle mouth. It was found that the sealing performance could not be maintained.

  The technical scope of the present invention is not limited to the above embodiments and examples, and various modifications can be made without departing from the spirit of the present invention.

For example, in the second embodiment, hot air is blown to directly heat the sliding layer. However, a sheet direct heating unit that applies infrared rays (radiant heat) may be provided to directly heat the sliding layer with infrared rays. . That is, as the sheet direct heating section, an infrared irradiation section that radiates infrared rays having a heating wire or the like that can generate infrared rays is disposed above the cap body, and infrared rays are irradiated from the infrared irradiation section toward the sliding layer. You may make it heat.
Further, as the sheet heating mechanism, the induction heating unit of the first embodiment and the sheet direct heating unit of the second embodiment may be used in combination.

  DESCRIPTION OF SYMBOLS 1 ... Cap main body, 1a ... Top plate part, 1b ... Cylindrical peripheral wall part, 2 ... Cap liner, 2a ... Sliding layer, 2b ... Sealing layer, 4 ... Resin application mechanism, 5 ... Mold mechanism, 26 ... sheet heating mechanism, 7 ... induction heating unit, 27 ... sheet direct heating unit, W ... hot air

Claims (10)

A method for producing a liner for a cap installed in a bottomed cylindrical cap body comprising a top plate portion and a cylindrical peripheral wall portion suspended from the periphery of the top plate portion,
A disc-shaped sliding layer in which the cap liner is disposed in contact with the inner surface of the top plate portion, and an annular sealing layer that is laminated on the sliding layer and is a synthetic resin that is more flexible than the sliding layer. With
Inserting a resin disk into the cap body to form the sliding layer;
A resin application step of applying the molten synthetic resin to be the sealing layer on the sliding layer;
A sealing layer molding step of molding the coated synthetic resin into the annular sealing layer;
In the resin application step, the synthetic resin melted in a state where the sliding layer is heated in advance is applied. In the manufacturing method of the liner for caps according to claim 1,
A method for producing a cap liner, wherein a surface temperature of the sliding layer when the sliding layer is preheated is set to a temperature range of 45 to 158 ° C. In the manufacturing method of the liner for caps according to claim 1 or 2,
A method for producing a cap liner, characterized in that the surface temperature of the sliding layer is set lower by 100 to 180 ° C than the temperature of the molten synthetic resin to be applied . In the manufacturing method of the liner for caps as described in any one of Claim 1 to 3 ,
The cap body is made of metal;
Before the resin coating step, has a sheet installation step of installing the sliding layer in the cap body,
In the resin coating step, the cap body is preheated by induction heating to heat the sliding layer. In the manufacturing method of the liner for caps as described in any one of Claim 1 to 4 ,
In the resin coating step, the cap liner is produced by heating the sliding layer in the cap body by applying hot air or infrared rays. A cap liner manufacturing apparatus installed in a bottomed cylindrical cap body comprising a top plate portion and a cylindrical peripheral wall portion hanging from the periphery of the top plate portion,
A disc-shaped sliding layer in which the cap liner is disposed in contact with the inner surface of the top plate portion, and an annular sealing layer that is laminated on the sliding layer and is a synthetic resin that is more flexible than the sliding layer. With
A resin application mechanism for applying the molten synthetic resin to be the sealing layer on the sliding layer, which is a resin disk inserted into the cap body ;
A molding die mechanism for molding the coated synthetic resin into the annular sealing layer;
An apparatus for manufacturing a liner for a cap, comprising: a sheet heating mechanism that preheats the sliding layer when the molten synthetic resin is applied. In the cap liner manufacturing apparatus according to claim 6,
The apparatus for producing a cap liner, wherein the sheet heating mechanism sets the surface temperature of the sliding layer when the sliding layer is preheated to a temperature range of 45 to 158 ° C.   In the cap liner manufacturing apparatus according to claim 6 or 7,
  The apparatus for producing a cap liner, wherein the sheet heating mechanism sets a surface temperature of the sliding layer to be lower by 100 to 180 ° C than a temperature of the melted synthetic resin to be applied. In the cap liner manufacturing apparatus according to any one of claims 6 to 8 ,
The cap body is made of metal;
The sheet heating mechanism includes an induction heating unit that heats the sliding layer by heating the cap body in advance by induction heating in a state where the sliding layer is installed in the cap body. A cap liner manufacturing apparatus. In the cap liner manufacturing apparatus according to any one of claims 6 to 9 ,
The apparatus for producing a cap liner, wherein the sheet heating mechanism includes a sheet direct heating unit that heats the sliding layer in the cap body by applying hot air or infrared rays.

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