KR200149410Y1 - Tamper evident top tap innerseal - Google Patents

Abstract

The present invention is directed to a multilayer inner enclosure having grip tabs extending across the inner enclosure. The force applied to the grip tab is concentrated at the base of the grip tab to promote complete failure of the inner enclosure. In use, a significant portion of the original inner enclosure remains attached to the container to indicate the opening and to avoid the mistake of resealing the container.

Description

Inner seal showing opening trace with upper tab

1 is an enlarged cross-sectional view of an inner seal.

2 is an enlarged cross-sectional view of the inner seal attached to the container.

3A is an enlarged cross sectional view of the inner seal showing an example of how the inner seal breaks during removal;

3B is an enlarged cross sectional view of the inner seal showing another example where the inner seal breaks during removal.

4A is a schematic diagram illustrating a process of making an inner seal web.

4b is a detail view of the liner web.

4c is a detailed view of the tabbed web.

4d is a detail view of the suture web.

5 is a schematic diagram illustrating a process of cutting an inner seal from a web.

6 and 7 are schematic diagrams showing a process of adhering an inner seal to a container.

8 is a schematic showing the removal of an induction sealed inner seal.

9 is a schematic showing another way of removal of the induction-sealed inner seal.

* Explanation of symbols for main parts of the drawings

10, 10 ', 10: inner seal 14: substrate

18: reinforcement layer

The present invention relates to a heat sealed inner seal used for secondary sealing of a container.

The plastic container market is spreading a number of products that form the primary closure of containers, including threaded caps, snap caps, and the like. In many cases, it is desirable to provide a secondary closure to the container in the form of an inner seal. Typically, the inner seal provides an open trace and acts as a vapor barrier to protect the product inside the container.

One class of inner seals relies on a heat sealable polymer layer bonded to the rim of a plastic container. This inner seal is disposed on the rim of the container and passes through a radio frequency field, which heat seals the inner seal in the container. After opening the primary stopper, the user can inspect the integrity of the inner seal and return it if there is any evidence of the opening on the inner seal. Typically, a user perforates the inner seal or cuts or breaks the material of the inner seal to access the product in the container.

Examples of internal seals and related technologies include the following.

U.S. Patent No. 4,684,554 to WuYang teaches a heat sealable adhesive to seal the inner seal to the container such that at least 50% of the inner seal material remains at the edge of the container when the cap is rotated off.

U.S. Patent No. 4,666,052 to Wooyang discloses a cap assembly in which an open trace is shown with a transparent or translucent cap and an inner seal. When the cap is twisted open, the inner seal film is torn off and the opening can be seen through the cap.

US Pat. No. 4,961,986 to Galda discloses an inner seal with a tab that can remove the inner seal as a unit. Such an inner seal can be easily removed, but not necessarily showing signs of opening.

US Pat. No. 5,004,111 to McCarthy discloses an inner seal with a tab to remove the inner seal by rupturing the heat seal layer such that a substantial portion of the heat seal layer remains on the rim of the container. When the heat seal layer ruptures, the inner seal can be easily removed, but does not remain distinct in the rim of the container, which is a trace of the heat seal layer.

The present invention provides an inner seal that exhibits an opening trace and is easy to open. Structurally, the inner seal has a grip tab, which allows the user to grab a grip tab and remove a portion of the inner seal. When the user applies the force of the inner seal, the inner seal breaks at the base of the grip tab so that a portion of the original inner seal can be removed from the container with the grip tab. The inner seal is designed to break completely near the base of the grip tab during removal, leaving behind the adhesive site of the original inner seal structure bonded to the rim of the container. This method of failure provides signs of opening and wastes efforts to reattach the original inner seal. In addition, when the inner seal is removed, there may be a visually visible portion of the inner seal material attached to the rim of the container, indicating that the original inner seal had been removed.

Typically, a typical inner seal is cut from a multilayer inner seal web to be generally flat and shaped to match the rim of the container. For example, if the rim of the container is circular, the inner seal can completely cover the opening delimited by the rim and have a circular shape with an edge portion that is consistent with the rim. However, other forms of inner seals are also contemplated within the scope of the present invention.

The inner seal is typically loaded into the cap with a pulp cardboard cap liner. When the cap is placed in the container, the inner seal is positioned close to the rim of the container. The inner seal can then be attached to the container by an induction heating process.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In each drawing, the same reference numerals indicate the same parts.

1 is a cross-sectional view of a conventional inner seal 10. The inner seal shown is circular, but may be other shapes. As shown in cross section, the circular inner seal 10 will have four layers 24 over about half of its area and five layers 26 over the remaining area. The bottom adhesive layer 12 is provided over the radially front face of the inner seal 10 and is used to bond the inner seal 10 to the container 22. Representative materials used in such bottom adhesive layer 12 are heat sealable polymer materials such as polyethylene, polypropylene or ethylene vinyl acetate. In general, the optimal bottom adhesive layer material depends on the components of the container 22.

The base layer 14 is also provided throughout the radial direction of the inner seal 10, which plays several roles. In the case of using the metal as the base layer 14, if the base layer 14 itself is heated by the eddy current induced in the base layer 14 during the heating of the base layer by an induction heating sealing process, the bottom adhesive layer 12 and the container are thereby heated. The heat seal can be glued between the rim. Induction heating methods are preferred here, but the inner seal can be sealed using either direct contact or heat transfer by heat source. Of course, other organic materials or inorganic materials can be used as the material of the base layer 14. For example, polypyrrole may be used and heated using a microwave radiant heat source, and polyvinylidene chloride may be heat sealed by direct heating, but in this case, it is preferable to perform oxygen blocking. In addition, the base layer 14 also forms an impervious layer. Aluminum is preferred from the metal worms 14, but other metal materials may be used.

The base layer 14 and the bottom adhesive layer 12 are supplied in a single unit during the manufacturing process, which unit will be referred to as a sealing web 37. If the intermediate adhesive layer 16 is present throughout the inner seal 10, the intermediate adhesive layer 16 adheres the upper reinforcement layer 18 to the base layer 14, and also the tab liner layer 20 to the upper reinforcement layer 18. It is used to adhere to). The intermediate adhesive layer 16 is usually formed of ethylene vinyl acetate (EVA), but other polymer materials may be used. The tab liner layer 20 is provided only on a portion of the inner seal 10. The tab liner layer 20 is a non-adhesive layer that is strongly bonded to the intermediate adhesive layer 16 but not to the base layer 14. By the presence of this tab liner layer 20, the tab base 33 is formed as shown in the figure. In the illustrated embodiment, the tab base 33 acts as a hinge when the user grabs the tab and lifts it upwards. Upper reinforcement layer 18 extends throughout inner seal 10 to reinforce grip tab 32 while providing durability to a portion of inner seal 10 around the grip tab 32. The upper reinforcement layer 18 is preferably made of polyester, but other materials may be used. In manufacturing, the upper reinforcing layer 18 and the intermediate adhesive layer 16 are supplied as a composite assembly referred to herein as a tabbbing web 39.

2 shows the inner seal 10 heat sealed to the rim 21 of the vessel 22. As shown in FIG. 2, the user grasps the three-layer grip tab 32 and lifts it upwards to remove the inner seal 10. As shown in FIG. The force exerted by the user on the grip tab 32 is concentrated along the tab base 33.

FIG. 3A shows the inner seal 10 broken by the force applied to the grip tab 32. In this figure, the inner seal 10 is broken to form an adhesive portion 28 and a removal portion 30. Although the adhesive portion 28 remains adhered to the container 22, the removal portion 30 may be destroyed. It is preferable that secondary breaks are formed inside the base layer 14 to leave the bottom layer fragments 31 adhered to the rim 21 of the container 22.

FIG. 3B shows another broken state of the inner seal 10 'broken by the force applied to the grip tab 32'. In FIG. 3B, the inner seal 10 'is broken to form an adhesive portion 28' and a removal portion 30 '. The adhesive portion 28 'remains attached to the container 22' while the removal portion 30 'can be destroyed. It is preferable that secondary breaks are formed near the rim 21 'to leave the debris portion 31' adhered to the rim 21 'of the container 22' opposite the adhesive portion 28 '.

FIG. 3B shows another fracture state of the inner seal 10 'broken by the force applied to the grip tab 32'. In FIG. 3B, the inner seal 10 'is broken to form an adhesive portion 28' and a removal portion 30 '. The adhesive portion 28 'remains attached to the container 22' while the removal portion 30 'can be destroyed. It is preferable that a secondary fracture portion is formed near the rim 21 'to leave the debris portion 31' adhered to the rim 21 'of the container 22' opposite the adhesive portion 28 '. In general, secondary breakage may occur in any of the layers 12, 14, 16, 18. In use, the user inserts a finger to remove the adhesive portion 28 from the rim 21 to remove the remaining portion of the inner seal.

4A shows a process for manufacturing the inner seal web 54 from the sealing web 37, the tab web 39 and the tab liner web 35. Preferred sealing webs for this process are products of the Safe-Gard ^™ trademark series and include the products SG-100, SG-101, SG-102 and SG-104A (3M, Maplewood, Minn.). SG-100 is used in this example, which is a 1.5 mil polyethylene heat seal layer, followed by 1.0 mil aluminum foil. Paper is preferred as the tab liner web 35, but may be replaced with other non-sticky layers such as polyester unplasticized polyvinyl chloride, polypropylene or silicone treated paper. Preferred tabbed web 39 is Scotchpak A heat-sealing polyester film of trade name Bunpo 470 (manufactured by 3M Corporation, Maplewood, Minn.). This material comprises a polyester layer as top reinforcement layer 18 bonded to a heat sealable copolymer, which is an intermediate adhesive layer 16.

The tabbed web 39 shown in detail in FIG. 4C is fed from the supply roll 38 of the tabbed web to the nip 47 formed by the hot can 44 and the cold roll 46. The interlayer, which is the tab liner web 35 shown in detail in FIG. 4B, is fed through the nip 47 from the tab liner feed roll 32. Both webs pass through the nip 47 to form an inner seal web 54. As a variant, the tabbed web 39 may be passed through to a processing station 40, which may be a corona discharge station. It may also be possible to perform flame treatment instead of corona discharge. In a similar manner, the aluminum web of the sealing web 37 is cleaned by feeding the sealing web 37 shown in detail in FIG. 4D from the sealing web feed roll 34 and passing through the corona treatment station 42. . These three webs pass through a nip 47 formed between the hot can 44 and the cold roll 46. The hot can 44 operates at temperatures above ambient temperature and the cold roll 46 operates at temperatures below ambient temperature. The illustrated high temperature can 44 has a separate heating oil reservoir for storing oil circulating through the can 44. It is anticipated that changes in the two types of products, the cross-web of the web and the down-web of the web, can be reduced by using temperature controlled and electrically heated rolls instead of the hot cans 44. .

After the inner seal web 54 is formed in the nip 47, it is sequentially cooled while passing through the first cooling roll 48 and the second cooling roll 50. The temperature of the cooling rolls depends in part on the humidity and the ambient temperature. The purpose of sequential cooling is to prevent condensation from occurring on the inner seal web and to prevent shrinkage or wrinkles in the inner seal web by gradually cooling the inner seal.

Treatment stations 40 and 42 form carboxyl and carbonyl groups in the polymer web, which are believed to clean the surface of the aluminum layer. It is also believed that this step enhances the adhesion between the tab web and the sealing web.

5 shows a portion of the generated inner seal web 54. The inner seal 10 is manufactured by cutting the inner seal web 54 shown in the figures to the desired dimensions and shapes. In this case, the dimension of the five-layer part on the grip tab side of an inner seal is adjusted by adding or subtracting a cutting position. Typically, the inner seal 10 is engaged with a cap liner 11 made of paper pulp cardboard or the like, which is placed in a cap 23 of appropriate size. The cap 23 and the cap liner 11 are located on the inner seal 10 for a separate heat sealing process.

6 shows a state where the cap 23 is disposed on the rim 21 of the container 22. The inner seal, shown in phantom, is pressed against the rim 21 by the cap liner 11 when the cap 23 is positioned on the container 22.

7 shows the assembly of the vessel 22 through the induction heater 53.

8 shows a state in which the inner seal 10 is peeled off from the container 22, in which the adhesive portion 28 remains adhered to the rim 21 of the container 22. In FIG. The removal part 30 shown in the figure includes a grip tab 32.

9 is a view showing another peeling state when the inner seal 10 is peeled from the container 22, in which the adhesive portion 28 is still attached to the rim 21 of the container 22. FIG. . The removal part 30 shown in the figure includes a grip tab 32. In this figure, a secondary break occurs in the intermediate adhesive layer 16 and leaves the fragment 31 on the rim 21.

EXAMPLE

In this example, a plurality of inner seal webs were produced in accordance with previously given process parameters. The hot can 44 has a diameter of 24 inches (about 60.96 cm) and a width of 16 inches (40.64 cm) and the process conditions are as described below. The inner seal was cut out of a 28 mm diameter circular shape from the web and applied to a polyethylene bottle with a snap cap of 28 mm. In this way, the inner seal was mounted via the cap to the rim of the container, and a backing material formed of pulp was inserted into the cap. The capped bottle was then used by Enercon 2KW low frequency induction sealer (Model LM-2752, manufactured by Enercon Industries Corporation, Milwaukee, WI). Passed an induction tunnel where energy was applied. Induction sealers were operated at 85% of maximum power. The bottle was moved through an induction sealer at a speed of 50 fpm.

The internal seals made in the examples were all successful. The inner seal was peeled off by hand, in which case the inner seal ruptured at the tab base, leaving a predetermined portion covered with the rim opening during peeling.

Example 1

High Temperature Can (44) Temperature (℉) 221

Pressure of Nib 47 (PSIG) 20

Speed of the web (feet / minute) 20

Corona Treatment Station (40) (KW) 1.2

Corona Treatment Station (42) (KW) .8

Web Materials for Tabs (39) Scotchpak 470

Web Material for Sealing (37) Safe-Gard ^TM SG-100

Web material for tab liners (35) Paper (20 lb rim basis weight)

Example 2

Hot Can (44) Temperature (℉) 290

Nip (47) Pressure (PSIG) 20

Speed of the web (feet / minute) 80

Corona Treatment Plant (40) (KW) 1.2

Corona Treatment Station (42) (KW) .8

Web Materials for Tabs (39) Scotchpak 470

Web Material for Sealing (37) Safe-Gard ^TM SG-100

Web material for tab liners (35) Paper (20 lb rim basis weight)

Example 3

Hot Can (44) Temperature (℉) 341

Pressure of Nib 47 (PSIG) 20

Speed of the web (inch / second) 80

Corona Treatment Station (40) (KW) 1.2

Corona Treatment Station (42) (KW) 0.8

Web Materials for Tabs (39) Scotchpak 470

Web Material for Sealing (37) Safe-Gard ^TM SG-100

Web material for tab liners (35) Paper (20 lb rim basis weight)

Example 4

Hot Can (44) Temperature (℉) 385

Pressure of Nib 47 (PSIG) 20

Web speed (inch / sec) 50

Corona Treatment Station (40) (KW) Outage

Corona Treatment Station (42) (KW) 0.8

Web Materials for Tabs (39) Scotchpak 470

Web Material for Sealing (37) Safe-Gard ^TM SG-100

Web material for tab liners (35) Paper (20 lb rim basis weight)

Internal seal breakage

As is apparent from the foregoing, the failure of the preferred aluminum base layer 14 results from the occurrence of stress concentration along the grip tab base 33. This stress concentration causes the metal foil to break preferentially. The adhesion between the bottom adhesive layer 12 and the rim 21 of the container 22 should be extremely strong, and also the adhesion between the grip tab 32 and the base layer 14 should be extremely strong. An induction sealing process that seals the inner seal 10 to the rim 21 of the vessel 20 will also improve the adhesive strength between the grip tab 32 and the base layer 14. In order to facilitate the tab base 33 and / or breaking along it, it is preferred that the adhesive strength between the grip tab 32 and the base layer 14 is greater than the strength of the base layer 14. That is, when a force sufficient to break the base layer 14 is applied to the tab base 32, the inner seal is broken along the tab base 33.

When the above conditions are satisfied, the force of the grip tab is applied to the base 14 and is concentrated along the tab base 33. The stress concentration that occurs along the tab base 33 is near the tab base 33, typically at the intersection of the tab base 33 and the rim 21 of the container, the substrate 14 near the grip tab base 33. Promotes breakage. However, if there is a defect in the inner seal 10 due to a defect in the base layer 14, a situation may occur where breakage starts elsewhere in the inner seal. From this point of view, it becomes important that the bottom adhesive layer is not reinforced with a material such as a polyester resin.

The present invention has been described with reference to various embodiments thereof. It will be apparent to those skilled in the art that many modifications may be made to the above-described embodiments without departing from the scope of the present invention. That is, the scope of the present invention is not limited to the structure described herein, but is defined as the structure described in the claims and their equivalents.

Claims (5)

As an inner seal 10 that adheres to the rim 21 of the container 22, (a) a bottom adhesive layer 12 for adhering the inner seal to the container rim; (b) a base layer 14 bonded to the bottom adhesive layer; (c) a grip tab (32) comprising an unbonded portion for holding by a user and a bonded portion bonded to the base, wherein the unbonded portion and the combined portion meet at a confluence extending along a radial string of the container rim; And (d) means for causing the base layer to break adjacent to the confluence toward the container rim and for the joining portion to be progressively peeled off the rim by the breaking force applied to the unjoined portion, thereby And the adhesive portion of the inner seal adhered to the rim remains attached to the rim and the removal portion of the remaining inner seal can be removed from the rim. The inner seal of claim 1, wherein the bottom adhesive layer comprises polyolefin. The inner seal of claim 1, wherein the base layer comprises aluminum foil. The inner seal of claim 1, wherein the bottom adhesive layer is heat sealable and the base layer is applied in a separate heating process. The inner seal of claim 1, wherein the joining portion comprises most of the base area.