This is the U.S. National Phase Application under 35 U.S.C. §371 of International Patent Application No. PCT/JP2012/082484 filed Dec. 14, 2012, which designated the United States and was published in a language other than English, which claims the benefit of Japanese Patent Application No. 2011-285164 filed on Dec. 27, 2011, both of which are incorporated by reference in their entirety herein. The International Application was published in Japanese on Jul. 4, 2013 as WO2013/099655 A1 under PCT Article 21(2).
The present invention relates to a synthetic resin cap for closing a container mouth, a synthetic resin cap liner, a closing device using the synthetic resin cap, and a beverage-contained closing device.
A synthetic resin cap (hereinbelow, simply referred to as a cap) is known which has: a cap body that is constituted of a top plate and a cylinder that is vertically lowered from the peripheral edge thereof; a liner that is provided on a lower surface of a top plate and made of a soft resin; and a thread that is formed on the inner surface of the cylinder and fits into a male screw of a container mouth (for example, refer to Japanese Unexamined Patent Application, First Publication No. 2009-113833).
An inter-seal projection 42, that contacts an inner edge of an opening end 21A of a mouth 21 of a container 20, is formed on a lower surface of the liner 35.
On a lower surface of the liner 55, an inter-seal projection 62 that contacts an inner edge of an opening end 21A of a mouth 21 of a container 20 and an outer-seal projection 63 that contacts an outer edge of the opening end 21A.
The outer-seal projection 63 is formed to reach the cylinder 3.
When a container is filled with a content fluid, generally, attachment of a cap thereto is carried out in a state where a container is filled with a content fluid having a high temperature such as 80° C. or more, that is, a so-called hot packaging is used.
Additionally, in order to enhance a sterilization effect, after the cap attachment is carried out, heating up of the container and the cap by use of a high-temperature water is also carried out.
When such operation is performed, it is necessary to prevent a sealing performance from being degraded which is due to that, the container is subjected to a high temperature, the mouth is deformed by heat shrinkage or the like (for example, inward or outward bending deformation of the opening end), and the adhesiveness between the container mouth and the cap thereby becomes insufficient.
In addition, even in cases where filling is not carried out at a high temperature, it is necessary to prevent the sealing performance from being affected which is due to variation in adhesiveness between the cap and the mouth due to variations in sizes of the mouth (internal diameter, outer diameter, or the like).
The invention was conceived in view of the above-described circumstances and has an object thereof to provide a cap capable of preventing a sealing performance from being degraded, a liner used for a cap, a closing device, and a beverage-contained closing device.
The invention provides a synthetic resin cap to be attached to a mouth of a container, including: a cap body having a top plate and a cylinder that is vertically lowered from a peripheral edge thereof; and a liner provided on a lower surface of the top plate, the liner having: a flat plate; an inter-seal projection that is formed on a lower surface of the flat plate and contacts an inner-edge side of an opening end of the mouth; and an outer-seal projection that is formed on the lower surface of the flat plate and contacts an outer-edge side of an opening end of the mouth, the liner having an outer edge that is separated from the cylinder in an internal side and is formed to ensure a space between the outer edge and the cylinder, the outer-seal projection having an outer diameter smaller than an outer diameter of the opening end.
In the invention, it is preferable that an outer edge of the outer-seal projection be formed to reach an outer edge of the flat plate.
It is preferable that an outer face of the outer-seal projection be formed on the same plane as an edge surface of an outer edge of the flat plate.
It is preferable that the outer-seal projection have an inner surface to be in contact with the opening end and the inner surface be an inclined surface that lowers according to a direction in which a diameter gradually increases.
It is preferable that an intermediate contact portion that is located along the lower surface of the top plate be formed on the liner and between the inter-seal projection and the outer-seal projection and the intermediate contact portion be capable of contacting an opening edge surface of the opening end.
It is preferable that a cleaning-water introduction hole for introducing a cleaning water into the cap body be formed at the cylinder.
The invention provides a liner provided on a lower surface of a top plate of a synthetic resin cap, the synthetic resin cap comprising a cap body having the top plate and a cylinder that is vertically lowered from a peripheral edge thereof, the synthetic resin cap being attached to a mouth of a container. The liner has; a flat plate; an inter-seal projection that is formed on a lower surface of the flat plate and contacts an inner-edge side of an opening end of the mouth; and an outer-seal projection that is formed on the lower surface of the flat plate and contacts an outer-edge side of an opening end of the mouth, the liner having an outer edge that is separated from the cylinder in an internal side and is formed to ensure a space between the outer edge and the cylinder, the outer-seal projection having an outer diameter smaller than an outer diameter of the opening end.
The invention provides a closing device including: a container capable of containing a beverage; and the above-described synthetic resin cap that is to be attached to a mouth thereof.
The invention provides a beverage-contained closing device including: a container which is filled with a beverage; and the above-described synthetic resin cap that is attached to a mouth thereof.
According to the invention, since the outer edge of the liner is formed and spaced apart from the cylinder in the internal side, the outer-seal projection is formed at the position separated from the cylinder in an internal direction, and a space is ensured at the outside of the outer-seal projection.
Because of this, when a force is applied to the outer-seal projection in radial-outer direction, the space is utilized, and the outer-seal projection can be easily deformed outward.
Therefore, when the cap is attached to the mouth, the outer-seal projection deforms outward and covers at least part of the outer edge of the opening end.
Since the outer diameter of the outer-seal projection is smaller than the outer diameter of the opening end, the outer-seal projection comes into contact with the outer edge of the opening end in a state of being pressed by the opening end and being deformed outward, an elastic repulsion force acts, and the outer-seal projection is always in contact with the outer edge by an adequate push pressure.
Accordingly, reliable tight sealing is possible.
Furthermore, since the outer-seal projection can be deformed outward, even in a case where the outer diameter of the mouth varies (particularly, in the case where the outer diameter is larger than the designed value), the outer-seal projection is shaped depending on the opening end and reliably comes into contact with the opening end by an adequate push pressure.
Consequently, even in a case where the outer diameter of the mouth varies, reliable tight sealing is possible.
Additionally, not only the outer-seal projection of the liner but also the inter-seal projection thereof comes into contact with the opening end, reliable tight sealing is possible, it is possible to increase pressure resistance.
Moreover, in addition to that the liner comes into contact with the opening end by an adequate pressing force which is due to deformation of the outer-seal projection, since the liner is in contact with the opening end at a plurality of points thereof, it is possible to make each of push pressures of the points lower.
Since an excessive force is not locally applied to the opening end, it is possible to prevent the mouth from being deformed even under a condition of a high temperature.
Furthermore, since an excessive force is not locally applied to the opening end in the cap, it is possible to reduce a disconnecting torque, and therefore, it is advantageous in terms of ease of disconnecting.
Moreover, since a pressing force does not locally increase, it is possible to prevent the generation of broken shards which is due to a crushed part of the liner.
These and other features and advantages of the present invention will become more readily appreciated when considered in connection with the following detailed description and appended drawings, wherein like designations denote like elements in the various views, and wherein:
In
In the explanation described below, a vertical direction and a height direction mean downward and upward direction shown in
As shown in
A male screw 22 is formed on an outer face 21c of the mouth 21.
An engagement step portion (not shown in the figure) serving as a ring-shaped protrusion protruding in a radial-outer direction is formed on the outer face 21c.
The inner surface 21a and the outer face 21c of the mouth 21 are surfaces along the axial direction of the container 20.
An opening edge surface 21b of the opening end 21A is a surface vertical to the axial direction of the container 20.
The portion that is from an inner edge of the opening edge surface 21b to an upper edge of the inner surface 21a is an inner-edge curved portion 21d (inner edge) having a substantially circular are cross-section, and the portion that is from an outer edge of the opening edge surface 21b to an upper edge of the outer face 21c is an outer-edge curved portion 21e (outer edge) having a substantially circular arc cross-section.
The opening end 21A includes the inner-edge curved portion 21d, the opening edge surface 21b, and the outer-edge curved portion 21e.
In order to ensure transparency, it is preferable that the mouth 21 be amorphous.
It is preferable that the mouth 21 have a light transmittance of, for example, 50% or more of visible light in the wall thickness direction.
In other cases, the mouth 21 may be crystallized by heating or the like.
As shown in
As shown in
The outer-edge curved portion 2c is a curve portion that is formed to extend from the outer edge of the main portion 2b to the upper edge of the cylinder 3.
The outer-edge curved portion 2c is formed in a curved shape that gradually lowers according to the direction in which the diameter thereof increases.
As shown in
A thread 10 that is to be threadably fitted into the male screw 22 of the container 20 is formed on the inner surface of the main portion 8.
The thread 10 is one or a plurality of spiral-shaped protuberances.
A cleaning-water introduction hole 16 for introducing a cleaning water into the inside of the cap 1 (the cap body 4) is formed at the upper portion of the cylinder 3.
The cleaning-water introduction hole 16 introduces a cleaning water to the inside of the cap 1 and is communicated with a space (outer space 15) between the outer edges 5c and 13d and the cylinder 3.
That is, the opening of the cleaning-water introduction hole 16 at the inner surface of the cylinder 3 is located at the position to which the space (space between the cap 1 and the mouth 21) in communication with the outer space 15 is exposed.
The cleaning-water introduction hole 16 preferably has a slit shape extending in the circumferential direction of the cap 1.
The length of the cleaning-water introduction hole 16 in the circumferential direction may be, for example, 0.5 to 5 mm.
The maximum width of the cleaning-water introduction hole 16 (the length in the vertical direction thereof) may be, for example, 0.01 to 0.1 mm.
It is preferable that the cleaning-water introduction hole 16 be formed at the position higher than the upper end of the thread 10.
The cleaning-water introduction hole 16 shown as an example in the drawing is located lower than the opening edge surface 21b.
The outer diameter of the cap body 4 is not particularly limited and may be 30 mm or more (for example, greater than or equal to 35 mm).
As shown in
The flat plate 5a is formed in a plate shape, the edge surface 5d of the outer edge 5c is formed vertical to the lower surface 2a (in the direction along the central axis C1 of the cap 1).
The inter-seal projection 12 is a protrusion that contacts the inner-edge side of the opening end 21A and has a portion of the outer face 12c which contacts at least the opening end 21A, and the portion is formed in a shape of an inclined surface that is inclined so as to rise up according to the direction in which the diameter thereof gradually increases.
The inter-seal projection 12 shown as an example in the drawing has a substantially trapezoidal cross-sectional shape in which the width thereof is gradually less in the protruding direction.
The inter-seal projection 12 includes: a linearly-inclined inner surface 12a that lowers according to the direction in which the diameter thereof gradually increases; a lower surface 12b that is from the outer edge of the inner surface 12a and is formed parallel to the lower surface 2a; and the outer face 12c that is linearly inclined so as to rise up according to the direction in which the diameter thereof gradually increases.
It is preferable that the internal diameter of the lower surface 12b be smaller than the internal diameter of the mouth 21 (the internal diameter of the upper edge of the inner surface 21a) and that the outer diameter of the lower surface 12b be larger than the internal diameter of the mouth 21.
Particularly, the inner surface 12a is an inclined surface in the inter-seal projection 12 shown as an example in the drawing; however, the inner surface 12a may be a surface perpendicular to the lower surface 2a (the surface in the direction along the central axis C1 of the cap 1).
As shown in
If the inclination angle of the outer face 12c is excessively small, degrees of the effect of preventing the mouth 21 from being deformed and the sealing performance become low. If the inclination angle is excessively large, ease in the tightening of the cap 1 is affected. However, as a result of setting the inclination angle α1 in the above range, it is possible to obtain the effect of preventing the mouth 21 from being deformed and realize a reliable sealing performance of the cap 1 without degradation in the ease of tightening.
The width W1 of the outer face 12c in the radial direction thereof is preferably 0.5 to 2 mm.
If the width of the outer face 12c is excessively small, the ease of tightening is affected. If the width is excessively large, degrees of the effect of preventing the mouth 21 from being deformed and the sealing performance become low. However, as a result of setting the width W1 in the above range, it is possible to obtain the effect of preventing the mouth 21 from being deformed and realize a reliable sealing performance of the cap 1 without degradation in the ease of tightening.
The height H1 of the inter-seal projection 12 (height from the intermediate contact portion 14) is preferably 0.2 to 2 mm.
If the inter-seal projection 12 is excessively low, degrees of the effect of preventing the mouth 21 from being deformed and the sealing performance become low. If the inter-seal projection is excessively high, ease in the tightening of the cap 1 is affected. However, as a result of setting the height H1 in the above range, it is possible to obtain the effect of preventing the mouth 21 from being deformed and realize a reliable sealing performance of the cap 1 without degradation in the ease of tightening.
As shown in
Particularly, in a state where the inter-seal projection 12 is compressively deformed in the thickness direction thereof, the outer face 12c is in contact with the inner-edge curved portion 21d and a region of part of the opening edge surface 21b.
The outer face 12c comes into contact with the inner-edge curved portion 21d and a region of part of the opening edge surface 21b in a state of being pressed by an elastic repulsion force.
The pressing force generated from the outer face 12c includes a direction component in which the diameter gradually increases in the downward direction (diagonally downward right direction in
As shown in
The outer-seal projection 13 shown as an example in the drawing is formed at a distance from the inter-seal projection 12 with the intermediate contact portion 14 interposed therebetween.
The intermediate contact portion 14 is a circular ring-shaped region that is formed so as to have a predetermined width and is formed thicker than the flat plate 5a.
The intermediate contact portion 14 can be formed along the lower surface 2a.
It is preferable that the intermediate contact portion 14 be formed in contact with the region including a center position 21b1 of the opening edge surface 21b.
The width W2 of the intermediate contact portion 14 is preferably 0.1 to 1 mm.
If the width of the intermediate contact portion 14 is excessively small, the sealing performance becomes low. If the width is excessively large, there is a possibility that the effect of preventing the mouth 21 from being deformed is affected. However, as a result of setting the width W2 in the above range, a pressing force from the intermediate contact portion 14 to the opening edge surface 21b becomes sufficient to provide an excellent sealing performance to the cap 1, and it is possible to increase a degree of the effect of preventing the mouth 21 from being deformed.
The thickness T1 of the intermediate contact portion 14 is preferably 0.2 to 2 mm.
If the thickness of the intermediate contact portion 14 is excessively thin, there is a concern that the sealing performance becomes low or the deformation of the mouth 21 is likely to occur. If the thickness is excessively thick, there is a possibility that the effect of preventing the mouth 21 from being deformed is affected. However, as a result of setting the thickness T1 in the above range, a pressing force from the intermediate contact portion 14 to the opening edge surface 21b becomes sufficient to provide an excellent sealing performance to the cap 1, and it is possible to increase a degree of the effect of preventing the mouth 21 from being deformed.
As shown in
The intermediate contact portion 14 is in contact with the opening edge surface 21b in a state of being pressed by an elastic repulsion force in the downward direction.
In other cases, the liner 5 may have a configuration in which the intermediate contact portion 14 is not provided, that is, a configuration in which the outer-seal projection 13 is formed close to the outside of the inter-seal projection 12.
The outer-seal projection 13 is a protrusion that contacts the outer-edge side of the opening end 21A and has a portion of the inner surface 13a which contacts at least the opening end 21A, the portion is formed in a shape of an inclined surface that lowers according to the direction in which the diameter thereof gradually increases.
The outer-seal projection 13 shown as an example in the drawing has a substantially trapezoidal cross-sectional shape in which the width thereof is gradually less in the protruding direction.
The outer-seal projection 13 includes: a linearly-inclined inner surface 13a that lowers according to the direction in which the diameter thereof gradually increases; a lower surface 13b that is from the outer edge of the inner surface 13a and is formed parallel to the lower surface 2a; and an outer face 13c that is vertical to the lower surface 2a.
As shown in
If the inclination angle of the inner surface 13a is excessively small, degrees of the effect of preventing the mouth 21 from being deformed and the sealing performance become low. If the inclination angle is excessively large, ease in the tightening of the cap 1 is affected. However, as a result of setting the inclination angle α2 in the above range, it is possible to obtain the effect of preventing the mouth 21 from being deformed and realize a reliable sealing performance of the cap 1 without degradation in the ease of tightening.
The width W3 of the inner surface 13a in the radial direction is preferably 0.5 to 2 mm.
If the width of the inner surface 13a is excessively small, the ease of tightening is affected. If the width is excessively large, degrees of the effect of preventing the mouth 21 from being deformed and the sealing performance become low. However, as a result of setting the width W2 in the above range, it is possible to obtain the effect of preventing the mouth 21 from being deformed and realize a reliable sealing performance of the cap 1 without degradation in the ease of tightening.
As shown in
Particularly, in a state where the outer-seal projection 13 is compressively deformed in the thickness direction thereof, the inner surface 13a is in contact with the outer-edge curved portion 21e and a region of part of the opening edge surface 21b.
The inner surface 13a comes into contact with the outer-edge curved portion 21e and a region of part of the opening edge surface 21b in a state of being pressed by an elastic repulsion force.
The pressing force generated from the inner surface 13a includes a direction component in which the diameter gradually decreases in the downward direction (diagonally downward left direction in
The width W4 of the lower surface 13b in the radial direction thereof is preferably 0.1 to 0.5 mm.
If the width of the lower surface 13b is excessively small or excessively large, the effect of preventing the mouth 21 from being deformed and the sealing performance are affected; however, as a result of setting the width W3 in the above range, it is possible to obtain the effect of preventing the mouth 21 from being deformed and realize a reliable sealing performance of the cap 1.
In an example in the drawing, the outer face 13c of the outer-seal projection 13 is formed vertical to the lower surface 2a (in the direction along the central axis C1 of the cap 1).
It is preferable that the outer face 13c be formed on the same plane as the edge surface 5d of the outer edge 5c of the flat plate 5a.
In other cases, the outer face 13c may be an inclined surface that is inclined so as to rise up or lower according to the direction in which the diameter thereof gradually increases.
The height H2 of the outer-seal projection 13 (height from the intermediate contact portion 14) is preferably 0.2 to 2 mm.
If the outer-seal projection 13 is excessively low, degrees of the effect of preventing the mouth 21 from being deformed and the sealing performance become low. If the outer-seal projection is excessively high, ease in the tightening of the cap 1 is affected. However, as a result of setting the height H2 in the above range, it is possible to obtain the effect of preventing the mouth 21 from being deformed and realize a reliable sealing performance of the cap 1 without degradation in the ease of tightening.
The outer-seal projection 13 shown as an example in the drawing is formed lower than the inter-seal projection 12.
In other cases, the outer-seal projection 13 may have the same height as that of the inter-seal projection 12 or may be formed higher than the inter-seal projection 12.
The outer edge 13d of the outer-seal projection 13 shown as an example in the drawing reaches the outer edge 5c of the flat plate 5a.
That is, the outer-seal projection 13 is formed at the outermost position of the liner 5, and the outer diameter of the outer-seal projection 13 is equal to the outer diameter of the flat plate 5a.
As a result of forming the outer-seal projection 13 at the outermost position of the liner 5, the outer-seal projection 13 is easily deformed outward.
In other cases, the outer-seal projection 13 may be formed closer to the inside than the outer edge 5c of the flat plate 5a.
The outer diameter of the liner 5 (the outer diameter of the flat plate 5a and the outer diameter of the outer-seal projection 13, the outer diameter D1 in
Consequently, the outer edges 5c and 13d of the liner 5 does not reach the cylinder 3.
In particular, the outer edges 5c and 13d of the flat plate 5a and the outer-seal projection 13 are formed to be spaced apart from the cylinder 3 in the internal side and are formed to ensure a space between the cylinder 3 and the outer edges.
The space between the outer edges 5c and 13d of the liner and the cylinder 3 is referred to as the outer space 15.
The distance between the outer edges 5c and 13d to the cylinder 3 may be, for example, 0.1 to 2 mm.
The outer diameter D1 of the liner 5 is preferably smaller than the internal diameter (internal diameter D3) of the main portion 2b of the top plate 2.
The outer diameter D1 of the outer-seal projection 13 is smaller than the outer diameter (the outer diameter at the upper edge of the outer face 21c, the outer diameter D4 in
The liner 5 is made of a resin softer than the cap body 4, and for example, a resin composition containing polypropylene resins or polyethylene resins and thermoplastic elastomer can be used.
The surface hardness (durometer D, in conformity to JIS K 7215) of the liner 5 is preferably 20 to 65.
Locking protuberances 11 are formed on an inner peripheral face of the TE ring portion 9 and serve as locking protrusions that are to be engaged with an engagement step portion 23 of the container 20 and prevent movement of the TE ring portion 9 during disconnecting.
The locking protuberances 11 are formed to protrude inward from the inner peripheral face of the TE ring portion 9.
The cap 1 can be made of a synthetic resin material such as polypropylene or high density polyethylene.
Particularly, in the case of using polypropylene, a high degree of transparency can be imparted to the cap body 4 and is, therefore, preferable.
When the cap 1 attached to the mouth 21 rotates in a disconnecting direction, the cap 1 moves upward in accordance with rotation.
In a state where the locking protuberances 11 reaches a lower end of an engagement step portion (not shown in the figure) of the container 20, when the cap 1 further rotates in the disconnecting direction, the main portion 8 moves upward in accordance with rotation; in contrast to this, since the locking protuberances 11 is engaged with the engagement step portion, upward movement of the TE ring portion 9 is prevented.
As a result, a tension acts on the bridge 7 that couples the main portion 8 to the TE ring portion 9, the bridge 7 is fractured, and the TE ring portion 9 is separated off from the main portion 8.
For this reason, the cap 1 is clearly disconnected.
For rinsing the outer face of the mouth 21 attached to the cap 1, a cleaning water is provided on the outer face of the cap 1.
The cleaning water is introduced into the inside of the cap 1 through the cleaning-water introduction hole 16, flows downward through the outer face 21c, and flows out from the cap 1. In this way, the mouth 21 is cleaned.
As described above, since the outer edges 5c and 13d of the liner 5 do not reach the cylinder 3, the cleaning water also flows into a space (outer space 15) between the outer edges 5c and 13d and the cylinder 3.
Accordingly, the outer face 21c of the opening end 21A and the position close to the opening edge surface 21b can be cleaned.
In the cap 1, since the outer edge 5c of the liner 5 is formed separated from the cylinder 3 in the internal side, the outer-seal projection 13 is formed at the position apart from the cylinder 3 in the internal direction, and the space (the outer space 15) is ensured in the outside of the outer-seal projection 13.
For this reason, when a force in the radial-outer direction is applied to the outer-seal projection 13, the outer-seal projection can be easily deformed outward while utilizing the outer space 15.
For example, outward deformation indicated by the dashed-two dotted line shown in
Accordingly, when the cap 1 is attached to the mouth 21, the outer-seal projection 13 is deformed outward and covers at least part of the outer-edge curved portion 21e.
Since the outer diameter of the outer-seal projection 13 is smaller than the outer diameter of the opening end 21A, the outer-seal projection 13 comes into contact with the outer-edge curved portion 21e of the opening end 21A in a state of being pressed by the opening end 21A and thereby being elastically deformed outward, therefore, an elastic repulsion force acts, and the outer-seal projection is always in contact with the outer-edge curved portion 21e by an adequate pressing force.
Accordingly, reliable tight sealing is possible.
Since this elastic repulsion force is an elastic force in the restoring direction to original state from the state where the outer-seal projection 13 is deformed outward, it is difficult for this force to be excessively large as compared with the repulsion force generated from a simple compression state.
Additionally, since the outer-seal projection 13 can be deformed outward, even in a case where the outer diameter of the mouth 21 varies (particularly, in the case where the outer diameter is larger than the designed value), the outer-seal projection 13 is shaped depending on the opening end 21A and comes into contact with the outer-edge curved portion 21e by an adequate push pressure.
Consequently, even in a case where the outer diameter of the mouth 21 varies, reliable tight sealing is possible.
In the deformed state indicated by the dashed-two dotted line shown in
Since the inter-seal projection 12 and the intermediate contact portion 14 of the liner 5 comes into contact with the opening end 21A, a plurality of portions of the liner 5, specifically, three portions of the inter-seal projection 12, the intermediate contact portion 14 and the outer-seal projection 13 mainly press the inner-edge curved portion 21d, the opening edge surface 21b, and the outer-edge curved portion 21e of the opening end 21A in the cap 1, respectively, and therefore reliable tight sealing is possible.
Accordingly, it is possible to increase pressure resistance.
Pressure resistance can be evaluated by, for example, secure seal test (SST).
In the cap 1, since the liner 5 comes into contact with the opening end 21A at a plurality of portions (the three points) in addition to that the outer-seal projection 13 comes into contact with the opening end 21A by an appropriate pressing force due to the deformation thereof, it is possible to make the pressing force at each of the portions lower.
Since an excessive force is not locally applied to the opening end 21A, it is possible to prevent the mouth 21 from being deformed even under a condition of a high temperature in which the mechanical strength of the mouth 21 is degraded.
Since the mouth 21 is less easily deformed, the cap 1 is preferable in the case of using a container 20 that is provided with the mouth 21 made of amorphous having a relatively low strength.
Since an excessive force is not locally applied to the opening end 21A in the cap 1, it is possible to reduce a disconnecting torque, and therefore, it is advantageous in terms of ease of disconnecting.
Moreover, since the pressing force of the liner 5 does not locally increase, it is possible to prevent the generation of broken shards which is due to a crushed part of the liner 5.
Furthermore, since the liner 5 in the cap 1 tightly seals the opening end 21A at a plurality of portions, particularly, three portions of the inter-seal projection 12, the intermediate contact portion 14, and the outer-seal projection 13, the rotation angle of the cap 1 from the closed position to the release of sealing (seal release angle; S.R.A.) can be increased, and an excellent tamper evidence property is provided.
The closing device shown in
In the cap 1 shown in
As an example, the inter-seal projection 12 may have a triangle cross-sectional shape such that the inner surface 12a and the outer face 12c extend toward the protruding end shown in
Moreover, the configuration of the outer-seal projection 13 is not limited to a substantially trapezoidal cross-sectional shape in which the width thereof is gradually less in the protruding direction, a triangle cross-sectional shape may be adopted.
As an example, the outer-seal projection 13 may have a triangle cross-sectional shape such that the inner surface 13a and the outer face 13c extend toward the protruding end shown in
The liner 5 may has a structure tightly sealing the opening end 21A at two portions of the inter-seal projection 12 and the outer-seal projection 13.
Number | Date | Country | Kind |
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2011-285164 | Dec 2011 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2012/082484 | 12/14/2012 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2013/099655 | 7/4/2013 | WO | A |
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Number | Date | Country | |
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20150008223 A1 | Jan 2015 | US |