TRANSIT SEALING PLUG

Abstract

The current invention discloses a transit seal plug, the seal plug to be releasably secured to a dispensing cap. The sealing member includes first and second annular sealing faces, and further also includes a gripping member which extends away from a first side of the sealing member to engage walls of a conduit. A pull tab extends from the opposite side of the sealing member, to facilitate removal of the seal plug from a dispensing cap.

Claims

1. A transit seal plug, the seal plug to be releasably secured to a dispensing cap; a sealing member having first and second annular sealing faces; a gripping member extending away from a first side of the sealing member to engage walls of a conduit; a pull tab extending from the opposite side of the sealing member, to facilitate removal of the seal plug from a dispensing cap.

2. A transit seal plug according to claim 1, wherein the centre of the sealing member is frusto-conical in shape, in a conformation extending away from the gripping member, forming a dish-like structure to enable the sealing portion to conform with the underside face.

3. A transit seal plug according to claim 2, wherein the gripping member is housed within the frusto-conical structure.

4. A transit seal plug according to claim 1, wherein the gripping member has a plurality of arms.

5. A transit seal plug according to claim 4, wherein the gripping member is cylindrical in shape.

6. A transit seal plug according to claim 5, wherein the gripping member is hollow to reduce weight.

7. A transit seal plug according to claim 1, wherein the pull tab is rectangular in shape.

8. A transit seal plug according to claim 7, wherein the pull tab has a roughened surface.

9. A transit seal plug according to claim 8, wherein the pull tab has a profiled surface.

10. A transit seal plug according to claim 1, wherein the seal plug is formed of plastics material.

11. A transit seal plug according to claim 10, wherein the plastics material is selected from polypropylene (PP), polyethylene, a low density polyethylene (LDPE), medium density polyethylene (MDPE), a polyethyleneterephthalate (PETE), a polyhydroxyalkanoate (PHA), polylactic acid (PLA).

12. A transit seal plug according to claim 10, wherein the plastics material is a recycled grade.

13. A container comprising a container body, a dispensing cap having a dispensing conduit, and secured thereto and interposed therebetween in sealing arrangement, a seal plug the seal plug comprising a sealing member having first and second annular faces; a gripping member extending away from a first side of the sealing member to engage walls of the dispensing conduit a pull tab extending from the opposite side of the sealing member, to facilitate removal of the seal plug from the dispensing cap.

14. A dispensing cap/seal plug assembly, the assembly comprising a dispensing cap having a dispensing conduit, and a seal plug including a sealing member having first and second annular sealing faces; a gripping member extending away from a first side of the sealing member to engage walls of the dispensing conduit, a pull tab extending from the opposite side of the sealing member, to facilitate removal of the seal plug from the dispensing cap.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0016] The invention is now described with reference to the accompanying drawings which show, by way of example only, three embodiments of a transit seal plug. In the drawings:

[0017] FIG. 1 is a side view of a first embodiment of transit seal plug;

[0018] FIG. 2 is top view of the transit plug of FIG. 1;

[0019] FIG. 3 is a cross-sectional view of a container closure including the first embodiment of transit seal plug;

[0020] FIG. 4 is a cross-sectional view of a container closure including a second embodiment of transit seal plug;

[0021] FIG. 5 is a cross-sectional view of a container closure including a third embodiment of transit seal plug; and

[0022] FIG. 6 shows three component parts of a container incorporating the first embodiment of transit seal plug.

DETAILED DESCRIPTION OF INVENTION

[0023] Prior art containers for fluids for many liquid products used in the household, personal hygiene or the like are typically formed of resilient plastics materials. They are further designed to have a dispensing means which can be readily opened and closed as required. As such they are susceptible to unwanted leakage of product. The risks of this can be minimised in the house and also when carried, for example in a sports bag by careful storage. Also, during bulk transportation which is usually well-controlled, the leakage of product is normally avoided.

[0024] However, where product is individually despatched to a user, via a postal courier service, then the risk of the container becoming orientated in the wrong position and/or being subject to a compressive force, tending to urge the liquid in the container to open the container, is increased. Spillages are not uncommon under such circumstances. The individual despatch of product is increasingly used, and has recently undergone a surge due to people subject to lockdown conditions, due to a pandemic, not physically purchasing goods at a store but instead purchasing on-line. Means of preventing this leakage happening are known in the art. For example, milk containers and sauce bottles usually include a plastic or foil disc across the neck of the bottle which is removed before use by the consumer. Such foils however are single-use, and need to be disposed of following removal. Moreover, the foils are bonded to the container neck to achieve the necessary seal. This requires specialist equipment which needs to be purchased and maintained, and needs also to be incorporated into the filling company's production line. This adds to the costs and also decreases the output speed of the production line.

[0025] Also, plastic bottles often have a removable tab on the outside of the closure mechanism which tab is removed prior to the first use.

[0026] The approach disclosed herein seeks a more sturdy solution which is also compatible with conventional closure designs, so avoiding the requirement to invest in expensive new tooling. Moreover, the invention described is reusable, and can be supplied ready fitted so not reducing the speed of the filling step or increasing the cost thereof.

[0027] In its broadest aspect the invention provides a removable insert which in use is located between the neck of a container body and an outlet provided by an attached cap. The insert provided engages with the cap and is provided to a filling company already incorporated therein, and suitable simply to be attached to the filled container body. The first time a user wishes to use the product in the container, the dispensing cap is removed from the container body and the insert separated therefrom. The cap is replaced onto the container body and the insert disposed of, or alternatively stored for later replacement into the dispensing cap if desired.

[0028] Referring initially to FIGS. 1 and 2 these illustrate an insert in accordance with the current invention. The various elements of the transit plug, generally referenced 10, can be formed of a plastics material such as polypropylene (PP), polyethylene, such as optionally a low density polyethylene (LDPE), medium density polyethylene (MDPE), a polyethyleneterephthalate (PETE), a polyhydroxyalkanoate (PHA), polylactic acid (PLA). These materials can also be conveniently utilised as recycled grades.

[0029] The transit seal plug 10, referred to herein as a transit plug, has 3 main elements. The first is a spigot 11, housed within a frusto-conical recess in, and extending from a main dish-shaped, sealing portion 12. Although the sealing portion can also be planar across its width, the dish shape is preferable in order to allow the sealing portion 12 to conform with the underside face, in doing so minimising the amount of plastic content necessary. The spigot 11, in use, forms an interference fit with the dispensing conduit located within the cap 62 (see FIG. 6) and acts to resist separation of the transit plug 10 and the dispensing cap 62 when such is not desired. The spigot 11 has a 4 arms in a cross-shaped or plus sign cross-section, which enables sufficient frictional engagement with the conduit, but reduces the mass of the spigot and the materials required for its production. Other shapes of spigot can also be utilised such as spigots having other than 4 arms, or arranged in another conformation, cylindrical, or other polyhedra. The spigot can also be either solid or hollow depending on the strength or weight/materials requirement.

[0030] Extending from the opposite side of the sealing portion 12 is a pull tab 13 which a user grips hold of to remove the transit plug 10 from the dispensing cap 62. The pull tab 13 is generally rectangular in the illustrated embodiment, extension in the third dimension being generally far less than in the other two, and can have a roughened surface and/or include surface features to aid a user in gripping the pull tab 13. Pull tabs having different shapes from rectangular can be utilised if desired.

[0031] The sealing portion 12 itself in use seats between the cap 62 and the container body 60 to form a seal therebetween preventing fluid from reaching the conduit in the dispensing cap 62. In the illustrated embodiment, the transit plug has a flange 14, having an upper flange face 15 from which the spigot 11 extends. The upper flange face 15 is generally planar enabling engagement with the dispensing cap 62. The lower flange face 16 also has a planar outer annular portion to engage the upper rim 65 of the neck 63 of the container body 60. Extending downwardly from the lower flange face 16 is a frusto-conical locator 17. The taper of the wall 18 of the locator 17 assists in the transit plug 10 passing without frictional engagement, into engagement with the container body 60. Frictional engagement would possibly cause plastic dust to be produced, which should be avoided due to contamination of the product and ultimately of the environment.

[0032] In use therefore, a transit plug 10 is secured into a dispensing cap 62 by insertion of the spigot 11 into the dispensing conduit within the dispensing cap 62. The frictional engagement between the spigot 11 and the wall of the conduit maintains the dispensing cap 62 and the spigot 11 in coupled separable relationship. The engagement between the spigot 11 and the wall of the conduit also acts to orientate the transit plug correctly. The upper flange face 15 is pressed against the lower edge 64 of the dispensing cap 62 to form a seal.

[0033] A container body 60 is filled with a liquid product and the cap/flange assembly secured thereto, optionally by means of a screw-threaded arrangement. In doing so, the lower flange face 16 is urged against the rim 65 of the container body 60 forming a seal. The seal between the transit plug 10 and the dispensing cap 62 can also be strengthened at the same time due to the force generated by engagement. The fluid is thus more securely sealed within the container and the seals formed between the transit plug 10 and the container body 60 and dispensing cap 62 prevent leakage of the fluid from the container.

[0034] Turning to FIG. 3, this illustrates an assembly including the first embodiment of transit plug shown in FIGS. 1 and 2. The assembly comprises a container body 30 with a disc-top dispensing cap 31 secured by a threaded connection 32 thereto. In order to provide a transit seal therebetween a transit plug 33 is included which can be removed by a user on first use of the product. The lower flange face 34 of the flange 35 of the transit plug 33, sealingly engages the rim 36 of the neck 37 of the container body 30. The upper flange face 38 is sealingly engaged with the circumferentially deployed flexible leaf seal 39. In order to hold the dispensing cap 31 and the transit plug 33 together, the cross-shaped spigot 40 engages the dispensing conduit 41 of the dispensing cap 31. A pull tab 42 is provided to enable a user to separate the transit plug 33 from the dispensing cap 31.

[0035] FIG. 4 illustrates a second embodiment of transit plug 50 for use with a flip-top dispensing cap 51. In this embodiment, engagement of the transit plug 50 with the container body 52 through the flange faces is as described above for the embodiment of FIG. 3, as is the pull tab 53. In this embodiment the transit plug 50 has an upstanding tubular feature 54. This tubular feature 54 defines a cylindrical space, and makes frictional contact on its inside diameter wall with the outside diameter wall of the dispensing cap orifice detail 55. Frictional contact ensures that the transit plug 50 is retained to the cap.

[0036] In FIG. 5, a third embodiment of transit plug 70 for use with a flip-top dispensing cap 71. In this embodiment, engagement of the transit plug 70 with the container body 72 through the flange faces is as described above for the embodiment of FIG. 3, as is the pull tab 73. The dispensing cap 71 includes a tubular section beneath the dispensing conduit detail 74. The transit plug has an upstanding spigot feature 75. The spigot feature 75 forms an interference fit with the dispensing cap tubular section 74 on the inside diameter face. The spigot feature 75 has a cross-shaped or plus sign cross-section, which enables sufficient frictional engagement with the tubular section of the cap 71, but reduces the mass of the spigot 75 and the materials required for its production. Other shapes of spigot can also be utilised such as solid or hollow cylindrical, or other polyhedra.