JP6831986B2 - cap - Google Patents

Description

The present invention relates to a cap attached to the mouth of a container such as a double container.

In order to ensure good storage of the contents in the container, the so-called hot filling process that sterilizes the inside of the container by filling the container in a high temperature state and attaching a cap to the mouth is It has already been done. The container that has been sterilized by carrying out this hot filling step and sealed with a cap is then cooled by showering cooling water from above.

When there is a space (gas space) inside the container (for example, a place near the mouth in the container), the capacity of the space is reduced by cooling and the pressure is reduced, so that the cooling water is capped. It is sucked into the internal space under reduced pressure, for example, the space inside the cap (more specifically, the space between the inner plug portion of the cap and the upper lid portion covering the inner plug portion) through the gap provided in the cap. There is. When a container filled with contents is shipped, if cooling water remains in the cap, etc., it may cause unsanitary conditions such as mold formation after that, so no cooling water remains. Is desirable. However, if the amount of cooling water remaining in the cap is large, the cooling water may remain in the cap at the time of shipment or opening.

One way to prevent or minimize the amount of cooling water left in the cap is to forcibly seal the container or cap where it is exposed to the outside air so that it will not be sucked in even under reduced pressure. (Also called a forced sealing method) and a method (also called a discharge gap formation structure) in which a gap (discharge gap) that communicates with the outside air is intentionally formed on a cap or the like to facilitate the discharge of cooling water to the outside through the gap. There is. However, when the cap is attached to the container by tapping or screwing it in, if the forced sealing method is used, the part to be sealed may be deformed when the cap is attached and cannot be sealed. In this case, it becomes impossible to prevent the cooling water from remaining.

Meanwhile, the discharge gap forming structures, such as disclosed in Patent Document 1, in this immersion ingress-preventing cap disclosed in Patent Document 1, one portion of the periphery of the upper lid and the fitting of the cap body (more Specifically, an inclined notch is formed in one place opposite to the place where the hinge is provided), and the space between the cap body and the upper lid is configured to communicate with the outside air through the notch. ing. According to this structure, the cooling water accumulated in the cap can be discharged to the outside through one notch. In addition, this structure has the advantage that the notch, which is the discharge gap, is not completely closed even if the cap body or the like is deformed when the cap is attached, so the cap is attached by tapping the cap or the like. Suitable for containers.

Jikkenhei No. 5-24549

However, in the conventional water immersion ingress-preventing cap structure the disclosed in Patent Document 1, the notch portion is not only formed in only one place in the peripheral portion of the cap body. Therefore, when the cooling water collects through the notch, the air in the internal space becomes more difficult to escape than the notch in the cap, and the cooling water remains evenly balanced and stays in the notch and its vicinity due to surface tension or the like. , Cooling water may not be discharged to the outside.

The present invention solves the above problems, and an object of the present invention is to provide a cap capable of satisfactorily discharging the cooling water accumulated inside the cap to the outside.

In order to solve the above problems, the present invention is a cap attached to the mouth of a container, which has a cap main body and an upper lid that covers the cap main body, and a side surface portion and a cap main body provided on the upper lid. Ventilation grooves are provided at a plurality of places to communicate the space between the container and the pouring cylinder provided in the above, and the upper part of the places where the ventilation grooves are provided is covered from the side by the side surface of the upper lid. , It is attached to the mouth of a container that has an outer container and an inner container housed in the outer container, and an intake air that introduces outside air between the outer container and the inner container into the cap body. A portion is provided, a spout is formed in the spouting cylinder, a ventilation groove passes through a portion of the cap body that fits with the upper lid, and the cap body is viewed in a plane, and is separated from the spouting cylinder and the intake portion. The angular range in the circumferential direction where the intake part is provided and the angular range in the circumferential direction where the ventilation groove is provided are different from each other with the spout as the center when the cap body is viewed in a plan view. The feature is that they are arranged so as not to overlap.

According to this configuration, since the ventilation grooves are provided at a plurality of places, some of the ventilation grooves serve as inlets for the outside air (that is, outside air), and other ventilation grooves serve as the inflow of the air from the internal space. As an outlet, air in the cap can easily flow through a plurality of ventilation grooves, and it is possible to minimize sucking of cooling water into the cap during cooling. In addition, even if the cooling water collects in each ventilation groove during cooling, the cooling water and air in the cap can easily flow through the plurality of ventilation grooves, and the cooling water is satisfactorily discharged to the outside from the ventilation grooves. It becomes possible. Further, even if the container to which the cap is attached has an inner container and an outer container and there is a possibility that a relatively large amount of cooling water is sucked into the inside of the cap when cooled, the cooling water is used. Can be discharged satisfactorily. In addition, the ventilation groove is provided at a position away from the pouring cylinder and the intake portion, and the circumferential angle range in which the intake portion is provided and the circumferential angle range in which the ventilation groove is provided. Because they are arranged so that they do not overlap with each other, even if the cooling water enters the space between the cap body and the upper lid through the ventilation groove, the cooling water will be taken in from the spout of the spouting cylinder or the intake part of the intake part. It can be suppressed from entering the mouth.

Further, the cap of the present invention is characterized in that the ventilation groove is provided so as to expand in the circumferential direction at the outer peripheral portion of the cap body. With this configuration, it is relatively easy to provide a large ventilation groove so as to spread in the circumferential direction on the outer peripheral portion of the cap body.

Further, the cap of the present invention is characterized in that a plurality of ventilation grooves are provided at positions diagonally opposite to each other with the spout as the center in a plan view of the cap body. With this configuration, even when such a spout in the cap has penetrated event cooling water immersion, etc. central portion provided, the portions outside air is likely to pass, the water by the cooling water or cooling water outside It becomes easy to be discharged.

The cap of the present invention, caps the body around the spout in plan view, than the radial dimension of the air suction part is provided, even by increasing the radius of the ventilation groove is provided suitable is there. According to such a configuration, to enter immersion when the cooling water has penetrated immersed in space even air inlet of the spout and the intake of the cooling water is pouring cylinder between the cap body and the upper cover from the ventilation groove Can be minimized.

According to the present invention, a part of ventilation is provided by providing ventilation grooves for communicating the space between the side surface portion provided on the upper lid and the injection cylinder provided on the cap body at a plurality of places to communicate with the outside air. The groove serves as an inlet for external air (that is, outside air), and the other ventilation groove serves as an outlet for air from the internal space, making it easier for the air inside the cap to flow through the multiple ventilation grooves, and during cooling. It is possible to minimize the suction of cooling water into the cap. In addition, even if the cooling water collects in each ventilation groove during cooling, the cooling water and air in the cap can easily flow through the plurality of ventilation grooves, and the cooling water is satisfactorily discharged to the outside from the ventilation grooves. It becomes possible.

Further, by providing the ventilation groove so as to spread in the circumferential direction at the outer peripheral portion of the cap body, the outer circumference of the cap body is compared with the case of the conventional configuration in which the ventilation groove is provided at one place on the opposite side of the hinge. It is relatively easy to provide a large ventilation groove so that the portion spreads in the circumferential direction.

In addition, by providing a plurality of ventilation grooves at positions diagonally opposite to each other with the spout as the center in a plan view of the cap body, in the unlikely event that the spout is provided in the cap, etc. even if the cooling water has entered immersion, ambient air this portion is liable to pass through the water by the cooling water and the cooling water is easily discharged to the outside.

Further, when the cap of the present invention is attached to the mouth of a container having an outer container and an inner container housed in the outer container and cooled, a relatively large amount of cooling water is applied to the cap. Even when there is a possibility of suction to the inside, the cooling water can be satisfactorily discharged through the plurality of ventilation grooves.

Further, the ventilation groove, by providing a remote position from the pouring cylinder and the intake section, even if the cooling water has penetrated immersed in the space between the cap body and the upper cover from the ventilation groove, the cooling water is pouring cylinder it can be suppressed to be small to enter immersion spout and intake portion of the inlet of the.

Also, when the cap body is viewed in a plan view, the angular range in the circumferential direction where the intake portion is provided and the angular range in the circumferential direction where the ventilation groove is provided are not differently overlapped with each other centering on the spout. Cooling water is immersed in the space between the cap body and the upper lid from the ventilation groove by arranging it or making the radial dimension where the ventilation groove is provided larger than the radial dimension where the intake part is provided. even if you enter, the cooling water enters or immersion spout and intake portion of the intake port of the pouring cylinder can be minimized.

It is a vertical cross-sectional view of the cap which concerns on embodiment of this invention, and shows the state which the cap is opened. It is a perspective view of the cap and shows the state which the cap is opened. It is a top view of the cap, and shows the state in which the cap is opened. It is a front sectional view of the cap, and is the sectional view taken along the line AA in a state where the cap is closed from the state shown in FIG. It is a side sectional view of the cap, and is the sectional view taken along the line BB from the state shown in FIG. 3 with the cap closed. It is a side view of the cap. It is a front view of the cap. It is an enlarged cross-sectional view of the main part of the cap and its vicinity, and shows the state in which the contents are poured out. It is an enlarged cross-sectional view of the main part of the cap and its vicinity, and shows the state which the outside air is sucked between the inner container and the outer container.

Hereinafter, the cap according to the embodiment of the present invention will be described with reference to the drawings.
In FIG. 1, reference numeral 1 denotes a container to which the cap 30 according to the present embodiment is mounted, which is made of a synthetic resin such as polyethylene terephthalate resin (PET). The container 1 is composed of an outer container 10 and an inner container 20 which is housed in the outer container 10 in a shrinkable state and is filled with the contents, and the mouth 12 of the outer container 10 and the inner container 20. , 22, the cap 30 according to the present embodiment is attached. The container 1 is also referred to as a double container, and the outer container 10 and the inner container 20 are each flexible and elastically deformable.

As shown in FIGS. 1 to 7, the cap 30 includes a cap main body 31 that is attached to the mouth portions 12 and 22 of the container 1 in a state of being externally fitted, an upper lid 45 that covers the cap main body 31, and a cap main body. It has an inner plug 50 provided inside the 31 and fitted into the mouth portion 22 of the inner container 20, and an internal valve device 60 provided inside the cap body 31.

As shown in FIGS. 1 to 7, the cap body 31 has a cylindrical body portion 32 and a disc-shaped top plate portion 33 provided at the tip (upper portion) of the body portion 32. .. The body portion 32 is screwed into the threaded portion 12a of the outer container 10 via the threaded portion 32a. A pouring cylinder 35 is integrally provided on the top plate portion 33, and a pouring outlet 34 for pouring out the contents is opened at the upper end of the pouring cylinder 35. The top plate portion 33 is also integrally provided with an intake cylinder 37 as an intake portion having an intake port 36 for sucking outside air into the space between the inner container 20 and the outer container 10. Further, inside the cap body 31, a communication flow path 38 that communicates with the intake port 36 and the gap (gap space) 2 between the inner container 20 and the outer container 30 is formed.

Further, the upper lid 45 has a top surface portion 45a and a side surface portion 45b, and is connected to the cap body 31 so as to be openable and closable via a hinge portion 44. The upper lid 45 has a protruding portion 46 protruding downward on the top surface portion 45a, and when the upper lid 45 is closed, the protruding portion 46 is inserted into the pouring cylinder 35 from the pouring outlet 34 to dispense the product. The cylinder 35 is sealed.

As shown in FIGS. 1 to 5, the upper outer peripheral portion (connecting portion between the body portion 32 and the top plate portion 33) of the cap main body 31 has a cap fitting portion 39 recessed in a stepped vertical cross section and a lower portion thereof. An undercover portion 40 is formed, and an upper lid fitting portion 47 and an upper lid covering portion 48 that fit into the cap fitting portion 39 are formed on the outer periphery of the lower end portion of the top surface portion 45a of the upper lid 45.

As shown in FIGS. 1, 8 and 9, the inner plug 50 has a circular fitting portion 51 fitted into the tip opening of the inner container 20 and a protruding portion radially outward from the upper tip of the fitting portion 51. It has a flange portion 52, a recessed portion 53 formed on the upper surface of the fitting portion 51 and recessed in a concave shape, and an inner cylinder portion 54 erected in the recessed portion 53. The inner cylinder portion 54 has a continuous passage 55 and a central protrusion 56 inside. In the communication passage 55, one end (lower end) communicates with the inner container 20 and the other end (upper end) communicates with the inside of the pouring cylinder 35.

The internal valve device 60 is made of an elastic member such as silicon rubber, and has a check valve 61 for pouring out to discharge the contents and a check valve 65 for intake air to introduce outside air. The check valve 61 for dispensing is a valve having an M-shaped cross section, and has a thin circular dispensing valve body 62 that covers the inner cylinder portion 54 of the inner plug 50 and a cylindrical support cylinder 63. ing. A plurality of flow holes 64 through which the contents can pass are formed at a portion of the pouring valve body 62 that can come into contact with the inner cylinder portion 54.

The intake check valve 65 is provided integrally with the injection check valve 61 to open and close the intake port 36, and is an elastically deformable intake valve body 67 supported by a cylindrical support cylinder 66. have.

When the container 1 is not subjected to an external force, as shown in FIG. 1, the flow hole 64 of the check valve 61 for pouring is closed, and the contents are sealed so as not to come out. The intake valve body 67 of the intake check valve 65 closes the flow path from the intake port 36 to the communication flow path 38, and the outside air enters the gap (space) 2 between the outer container 10 and the inner container 20. It is blocked so as not to enter immersion.

On the other hand, when this container 1 presses the outer container 10 inward during use, that is, when it is squeezed, the intake check valve 65 is maintained in a closed state by the action of air pressure from the inside, whereby the outside The inner container 20 is indirectly pressed by the air pressure in the gap (space) 2 between the container 10 and the inner container 20. Then, as shown in FIG. 8, since the inner container 20 is contracted, the pouring valve body 62 of the pouring check valve 61 swells due to the contents and the flow hole 64 is opened, so that the flow hole 64 is opened. The contents are extracted from the spout 34 through.

Further, by stopping the squeeze operation on the outer container 10 and releasing the hand from the outer container 10, as shown in FIG. 9, the check valve 61 for dispensing is closed and the pouring of the contents is prevented. At the same time, the intake valve body 67 of the intake check valve 65 is opened, and air is introduced into the gap (space) 2 between the outer container 10 and the inner container 20 through the communication flow path 38. By such an operation, while the content liquid can be poured out, oxidation of the content filled in the inner container 20 is prevented, and the content liquid is kept in a fresh state.

In addition to the above configuration, as shown in FIGS. 2 to 7, the cap 30 of the container 1 has a ventilation groove 70 for communicating the space between the cap body 31 and the upper lid 45 with the outside air (outside space). It is provided. Here, a plurality of the ventilation grooves 70 are provided, and in this embodiment, two are provided.

Each ventilation groove 70 is formed so that the outer peripheral portion of the cap body 31 is recessed in a concave shape so that the thickness of the body portion 32 is partially reduced. Each ventilation groove 70 passes vertically through a cap fitting portion 39 that fits with the upper lid 45 in the body portion 32 of the cap body 31, and the upper end of each ventilation groove 70 reaches the outer peripheral portion of the top plate portion 33. Further, the lower end of each ventilation groove 70 reaches the lower portion of the body portion 32 of the cap body 31. In this embodiment, each ventilation groove 70 is inclined so as to have a smaller radial dimension when flattened upward in the upper region, and is formed as an inclined ventilation groove 70a, and in the lower region, a substantially vertical plane (vertical surface). ) Is a vertical ventilation groove 70b, and these depressions are smoothly connected vertically. The vertical cross-sectional shape of the cap body 31 provided with each ventilation groove 70 may be a curved shape that bulges outward.

The upper portion of each ventilation groove 70 is covered from the side with a gap by the lower portion of the side surface portion 45b of the upper lid 45 on which the upper lid fitting portion 47 and the upper lid covering portion 48 are formed. Further, in this embodiment, the upper lid fitting portion 47 is formed in the gap between the surface of the body portion 32 of the cap body 31 where each ventilation groove 70 is formed and the side surface portion 45b of the upper lid 45. The lower region is larger (wider) than the upper region where the upper lid covering portion 48 above the upper lid fitting portion 47 is formed.

Further, as shown in FIG. 5, the ventilation groove 70 extends in the circumferential direction on the outer peripheral portion of the cap body 31 at positions diagonally opposite to each other with the spout 34 as the center in a plan view of the cap body 31. It is provided in. In this embodiment, each ventilation groove 70 is formed at an angle (angle range α) of 45 degrees or more with respect to the spout 34 in a plan view of the cap body 31.

Further, the ventilation groove 70 is provided at a position away from the injection cylinder 37 and the intake cylinder 37 in a plan view of the cap body 31. Specifically, when the cap body 31 is viewed in a plan view, the circumferential angle range β where the intake cylinder 37 is provided and the circumferential angle range α where the ventilation groove 70 is provided are centered on the spout 34. Are differently arranged so that they do not overlap. Further, the ventilation groove 70 is larger than the radial dimension (specifically, the radial dimension of the outer peripheral side portion of the intake cylinder 37) R1 in which the intake cylinder 37 is provided with the spout 34 as the center when the cap body 31 is viewed in a plan view. The provided radial dimension (specifically, the radial dimension of the inner peripheral side portion of the ventilation groove 70) R2 is large (that is, the ventilation groove 70 is provided on the outer peripheral side of the cap body 31 rather than the intake cylinder 37).

In the above configuration, ventilation grooves 70 for communicating the space between the cap body 31 and the upper lid 45 with the outside air are provided at a plurality of locations (two locations in the present embodiment). As a result, one of the ventilation grooves 70 (specifically, the gap 3 at the place where the ventilation groove 70 is provided) becomes the inflow port of the outside air (that is, the outside air), and the other ventilation groove 70 (specifically, ventilation). The gap 3) at the location where the groove 70 is provided serves as an outlet for air from the internal space, and during cooling (cooling by showering cooling water after the hot filling process), cooling water is provided inside the cap. Inhalation can be minimized. Further, even if the cooling water is sucked into the cap 30 and the cooling water is accumulated in each ventilation groove 70, the cooling water and air in the cap 30 can easily flow through the two ventilation grooves 70 (gap 3). Therefore, the cooling water can be satisfactorily discharged to the outside from the ventilation groove 70. Therefore, it is possible to prevent or minimize the amount of cooling water remaining in the cap 30 when the container 1 is shipped.

That is, in the conventional water immersion ingress-preventing cap, cutout portions, because they are not only formed only on one place of the periphery of the cap body, the cooling water is collected in the cut-out portion, than the notch portion in the cap In some cases, the air in the internal space became difficult to escape, and the cooling water remained evenly balanced and remained in the notch or its vicinity due to surface tension (that is, the cooling water was not discharged to the outside). Such a defect is unlikely to occur in the configuration of the embodiment.

Further, according to the above configuration, since each ventilation groove 70 is provided so as to expand in the circumferential direction on the outer peripheral portion of the cap body 31, a ventilation groove formed of a notch or the like is provided at one place on the opposite side of the hinge. Compared with the case of the conventional configuration, it is relatively easy to provide a large ventilation groove 70 so as to spread in the circumferential direction on the outer peripheral portion of the cap body 31. Therefore, even if the inner container 20 and the outer container 10 are provided and a relatively large amount of cooling water is sucked into the cap 30 when the cooling water is cooled, the cooling water can be satisfactorily discharged.

Further, according to the above configuration, by providing the cap body 31 at positions opposite to each other on the diagonal line with the spout 34 as the center in a plan view, the central portion of the cap 30 where the spout 34 and the like are provided, etc. even when input event cooling water immersion, the outside air the point tends to pass water by the cooling water and the cooling water is easily discharged to the outside.

Further, according to the above configuration, since the upper part of the portion where the ventilation groove 70 is provided is covered from the side by the side surface portion 45b of the upper lid 45, the cooling water is sprayed like a shower from above at the time of cooling. even when the cooling water can be prevented it is so fewer to enter immersed in the cap 30 through the vent groove 70 from the side.

Further, according to the above configuration, the ventilation groove 70 is provided at a position away from the injection cylinder 35 and the intake cylinder 37. That is, when the cap body 31 is viewed in a plan view, the circumferential angle range β where the intake cylinder 35 is provided and the circumferential angle range α where the ventilation groove 40 is provided are centered on the spout 34. They are arranged so that they do not overlap differently. Further, the radial dimension R2 in which the ventilation groove 70 is provided is made larger than the radial dimension R1 in which the intake cylinder 37 is provided.

This configuration immersion when the cooling water has penetrated immersed in space even, the air inlet 36 of the spout 34 and the inlet pipe 37 of the cooling water is pouring cylinder 35 between the cap body 31 and the upper cover 45 from the vent grooves 70 It is possible to reduce the amount of entry. That is, the intake valve body 67 is arranged in the intake check valve 65 provided with the intake cylinder 37, and the cooling water adheres to the portion where the intake valve body 67 is arranged. If mold or foreign matter adheres to the cooling water, the check function of the intake check valve 65 may be impaired, but the occurrence of such a problem can be reduced. As a result, the reliability of the intake check valve 65 can be improved.

In the above embodiment, the case where the ventilation grooves 70 are provided at two locations on the cap body 31 has been described, but the present invention is not limited to this, and the ventilation grooves 70 may be provided at three or more locations. Further, the ventilation groove 70 may be provided so as to be partially covered and penetrate the hole shape. Further, a ventilation groove may be provided in, for example, the upper lid 45 other than the cap body 31.

Further, in the above embodiment, the case where the container 1 to which the cap 30 is attached is a so-called double container having the outer container 10 and the inner container 20 is described, but the present invention is not limited to this, and the outer container is not limited to this. The same configuration can be applied to a cap attached to the mouth of a general container that does not have the 10 and the inner container 20.

1 Container 10 Outer container 20 Inner container 30 Cap 31 Cap body 32 Body 33 Top plate 34 Injection port 34 Outlet cylinder 36 Intake port 37 Intake cylinder (intake part)
38 Communication flow path 39 Cap fitting part 40 Undercover part 44 Hinge part 45 Top lid 47 Top lid fitting part 48 Top lid covering part 50 Inner plug 60 Internal valve device 61 Check valve for injection

Claims (4)

A cap that is attached to the mouth of the container
It has a cap body and an upper lid that covers the cap body.
Ventilation grooves are provided in a plurality of places to communicate the space between the side surface portion provided on the upper lid and the injection cylinder provided in the cap body to the outside air, and the upper part of the place where the ventilation groove is provided is , Covered from the side by the side of the top lid ,
It is attached to the mouth of a container having an outer container and an inner container housed in the outer container.
The cap body is provided with an intake part that introduces outside air between the outer container and the inner container, and a spout is formed in the spout cylinder.
A ventilation groove is provided at a position away from the pouring cylinder and the intake portion in a plan view of the cap body and passing through a portion of the cap body that fits with the upper lid.
When the cap body is viewed in a plan view, the circumferential angle range where the intake portion is provided and the circumferential angle range where the ventilation groove is provided are arranged so as not to overlap with each other centering on the spout. A cap characterized by being. The cap according to claim 1, wherein the ventilation groove is provided so as to spread in the circumferential direction at the outer peripheral portion of the cap body. The cap according to claim 1, wherein a plurality of ventilation grooves are provided at positions diagonally opposite to each other with respect to the spout as the center of the cap body in a plan view. The cap according to claim 1, wherein the radial dimension in which the ventilation groove is provided is larger than the radial dimension in which the intake portion is provided with the spout as the center in a plan view of the cap body.

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