KR100968553B1 - Closure plug - Google Patents

Abstract

The present invention relates to outer threaded closure closures 1, 60 for tightly closing the threaded opening 23 inwardly in transport and storage containers such as drums, pails and the like. The stopper is formed as a cup with a bottom wall 2 and a threaded cylindrical side wall 23 ending in a rim 4 extending in the circumferential direction. The gasket seats 8, 64 defined by the lower surface 4a of the closure rim are just below the rim of the closure, and the closure sidewalls and annular gasket retaining lips 9, 61 are plane parallel to the lower surface of the closure rim. Is placed on. In use, the stopper is screwed into and unscrewed from the container wall opening having the threaded portion 28 and the unthreaded portion 30, and the sealing gasket 12 is connected to the unthreaded opening portion and the plug gasket sheet ( 8, 64, 72) and lie adjacent to the internal thread. The gasket sheet acts to prevent mutual engagement of the sealing gasket 12 and the opening portion 28 cut out therein.

Description

Closure plug {Closure plug}

The present invention relates to an improved container closure closure, and more particularly to a threaded closure having a unique gasket retention feature.

In the transport container industry, it is common to manufacture drums, pails and the like having one or more dispensing and / or filling openings. These openings have an internal helical thread that merges into an unthreaded gasket. An externally threaded closure plug having an annular sealing gasket is threaded into the opening. By tightly closing the stopper, the stopper gasket is pulled down against the unthreaded gasket sealing area to provide effective sealing of the container. Although millions of drums and other containers have been sealed in this form, problems that the present invention addresses sometimes arise. This problem was related to the sealing of the container openings as well as the removal of the plug from the openings. What is important in this relationship is on the one hand between the plug and its gasket and on the other hand incorporating the container opening screw into the opening gasket seat area. This relationship applies the torsion necessary to seal the closure to the actual container opening, where the closure gasket is forced into the end of the thread inside the opening. As the stopper continues to turn out, it is common for the wedge action of such a gasket on the opening thread to grip the stopper gasket in close contact. The thinning state is accompanied by continuing the turning off action. Most notably, as the plug proceeds out of the opening, the gasket can be held in an internal opening thread, so that the gasket is peeled off at the gasket seating position on the plug. As the gasket is pinched between mating threads, the continuous rotation of the plug becomes extremely difficult. Moreover, the gasket itself is significantly damaged by this break, which further reduces the usability of the plug.

Another negative aspect of this gasket gripping condition is that the gasket tends to ring out of the gasket sheet while the plug is twisted. This problem occurs when the stopper gasket movement around the unthreaded gasket sheet of the opening is hindered, thus forming a pleat in the gasket which protrudes from the edge of the opening. One cause of such a failure is when the stopper enters the opening and the stopper gasket is caught again at the end of the opening thread. The resulting “looping” state will most certainly create a leak path and will cause serious damage to the gasket. Of course, the commonality between “gripping” and “ringing” is to keep the gasket in place on the gasket seat to which the gasket belongs so that the threads are prevented from being pulled together when joined.

It has conventionally been recognized the need for some reliable mechanical holding means for holding the stopper gasket in place. Marchyn's US Pat. No. 2,906,429 recognized the problem of "ringing" but failed to provide a completely satisfactory solution. In this patent, the closure has a special thread form where the threads form a boundary with the gasket sheet. In particular, the closure has a decreasing thread that runs around the lower edge of the gasket sheet and acts as a partial barrier just above the normal closure thread. However, this modified screw configuration did not adequately cope with the “gripping” phenomenon, as will be clearly seen next.
U.S. Patent No. 4,768,677 to Kitsukawa discloses a closure closure, wherein the gasket retaining lip has a uniformly continuous and upwardly annular surface, and the constant radial extension is axially outward of the projection of the helical sidewall thread. Smaller than expansion and cylindrical gasket seats.

It is an object of the present invention to provide a closure closure which overcomes the problems of gasket sealing and cyclization. It is a further object of one embodiment of the present invention to provide a closure plug that fits the range of container openings.

According to the invention, the closure plug comprises a cylindrical sidewall with an external helical thread, a circumferentially extending stopper rim, an annular stopper gasket sheet directly below the stopper rim, and a continuous radial circumference under the stopper gasket sheet. And a gasket retaining lip extending outward, wherein the gasket sheet is radially outwardly and upwardly aligned with the closure rim.

According to one embodiment of the invention, the gasket sheet is opened radially outwardly and upwardly directly from the root of the gasket retaining lip.

delete

delete

According to another embodiment of the invention, the gasket sheet is truncated conical.

According to another feature of the invention, an elastic sealing gasket is spread over the gasket sheet and takes the shape of the gasket sheet; The elastic sealing gasket takes the truncated conical shape of the gasket sheet.

Furthermore, according to the invention, the closure plug according to the invention is combined with an opening in a container wall having a bushing, the bushing having a cylindrical wall with an internal helical thread and a smooth gasket sealing area extending outward, said sealing A gasket is radially compressed between the bushing gasket sealing area and the plug gasket sheet and lies adjacent to an internal helical thread of the bushing.

The closure closure according to the present invention provides a solution found after years of research on the above-mentioned "gripping" and "ringing" problems in a simple and direct manner.

As an example, the closure plug is formed of a cylindrical screw side wall and a disc bottom wall. The side wall terminates in a rim extending in the circumferential direction and has an annular gasket sheet just below the rim. The gasket retaining lip fits between the stopper gasket sheet and the sidewall threads. An elastic sealing gasket is spread over the plug gasket sheet occupying the vertical space between the plug rim and the retaining lip. The stopper described above is screwed into the container wall opening with an internal thread and an inward gasket sealing area. The conventional important relationship existing between the plug gasket and the container threaded opening is no longer important. As the stopper is retracted from the threaded container opening, the gasket is held firmly in place on the stopper gasket sheet by the gasket retaining lip. As a result, the clean removal of the plug gasket from the container opening can be said to be a configuration that greatly improves the prior art.

Thus, a major feature of the present invention is to provide an improved threaded closure closure for containers of sizes used in the industry.

delete

A more detailed feature is to provide a closure gasket sheet having a structure that securely holds the closure gasket during screwing and disengaging.

delete

The above and further features of the invention are set forth in the appended claims and are further illustrated in the drawings.                 

1 is a partial cross-sectional view of a closure plug according to one embodiment of the invention.

FIG. 2 is a plan view of the container closure assembly incorporating the closure closure of FIG. 1. FIG.

3 is a partial cross-sectional view of the closure of FIG. 1 screwed to a container opening.

4 is a view similar to FIG. 3 with the plug in a partially unrolled position;

FIG. 5 is a view similar to FIG. 4 illustrating the prior art;

6 is a detailed cross-sectional view of the closure plug according to the second embodiment of the present invention.

FIG. 7 is a view similar to FIG. 6 including a sealing gasket.

8 is a partial cross-sectional view of a closure cap forming a third embodiment of the invention that is screwed into a container opening.

9 is a view similar to FIG. 8 with the plug in a partially unrolled position;

10 is a detailed cross-sectional view of the fourth embodiment of the closure cap according to the present invention.

The closure plug according to the first embodiment of the invention is shown in FIGS. 1 to 4, which is indicated by reference numeral 1 and is surrounded by a cylindrical sidewall 3 terminating in a rim 4 extending in the circumferential direction. It is molded of synthetic resin to have a disk like wall 2. The interior of the closure 1 has a series of wrench engagement projections 5 for imparting screwing and releasing twist to the closure. The closure side wall 3 has a pilot portion 6 extending from the bottom wall 2, an outer helical thread 7, and a gasket seat 8 situated just below the closure rim 4. Here, it is important to note that the gasket sheet 8 lies in a plane aligned axially with the plug screw root diameter. This relationship is advantageous in that a sufficient gasket volume can be ensured between the plug and the container opening surface to be joined to block any leakage path. The cap side wall 3 is formed with a retaining lip 9 in the circumferential direction at the upper end of the thread 7, and the upper end of the thread extends radially outwardly aligned with the thread projection. As clearly shown in FIG. 1, the closure thread extends and terminates at a point 10 in the lip 9 so that a uniformly upward continuous annular surface 11 has a lower surface of the closure rim 4. It lies in a plane parallel to (4a) and is just below the point 10 at which the thread terminates. An elastic annular sealing gasket 12 having a substantially square cross-sectional shape is spread over the stopper to embrace the gasket sheet 8. Therefore, the gasket is clamped snugly between the lower face 4a of the stopper rim 4 and the upper face 11 of the retaining lip 9, making it difficult to remove the gasket 12 from the gasket sheet 8. do.

As shown in Fig. 3, the container opening wall into which the stopper 1 is screwed therein is constituted by the container wall 20, in which the bushing indicated by reference numeral 21 is inserted in a conventional manner. The bushing 21 has a polygonal base 22 extending in the circumferential direction, and a cylindrical wall 23 extending therefrom and terminating in a radially outwardly bead 24. The container wall 20 lies on the polygonal base 22 at the joining relief 25 and has an upright cylindrical neck 26 extending within the bead 24 of the bushing. The bushing gasket 27 is compressed between the bushing 21 and the peripheral surfaces of the container wall 20. An internal helical thread 28 is formed in the bushing wall 23 and extends from the base 22 to the thread end point 29 at the beginning of the bead 24. The upwardly extending unthreaded bead portion just above the thread end point 29 forms a smooth gasket sealing area 30.

The sealing relationship between the stopper 1 and the bushing 21 in the overall torsional state as shown in FIG. 3 results in a stopper gasket 12 that is compressed in close contact between the stopper gasket sheet 8 and the bushing sealing area 30. see. Notably, the gasket 12 is also restrained in the axial direction between the rim lower face 4a and the upper face 11 of the retaining lip 9. Furthermore, it can be seen that the gasket 12 in this close position lies in contact with the bushing thread end point 29. The continuous annular top face of the retaining lip always maintains an axial space from the rim bottom face 4a and prevents the gasket 12 from being caught by the bushing thread 28 at any point. When rotating the plug as shown in FIG. 4, the gasket retaining lip 9 clearly lifts the plug gasket 12 from the bushing thread 28 and above the gasket sealing region 30. This clear separation of the gasket gasket from the surrounding bushing surfaces eliminates the gasket “gripping” and gasket “ringing” problems that have been common to date.

FIG. 5, in contrast, shows a typical prior art state in which the stopper 40 of the prior art is unscrewed from the container wall opening neck 41 internally cut off. Here, the gasket 42 is seated on the gasket sheet 43 formed at the root diameter of the cap thread, but the cap thread 44 is simply reduced as indicated by the reference numeral 45 as it approaches the gasket sheet 43. . Under this prior art, it can be seen that the gasket 42 has little axial support supplied by the reduced thread 45 due to the retraction of the plug. As a result, the gasket is easily caught and peeled off between the interlocking closed threads, causing the gasket sheet to peel off, creating a serious obstacle to normal closure functionality.

Second and third embodiments of the invention are shown in FIGS. 6-7 and 8-9, which are variations of the first embodiment described with reference to FIGS. 1 to 4; Similar parts are given the same reference numerals. As shown in FIGS. 6 and 7, the metal closure stopper 60 in the example is cut and rolled from a drum end steel of 1.15 mm. The gasket retaining lip 61 has a threaded triangular cross section with a 55 ° included angle and a radial extension D1 that is smaller than the outer radial extension D2 of the protrusion of the thread 7, and a plug rim. It is rolled so that it may exist in the plane parallel to the lower surface 4a of (4). The upper flank 62 of the retaining lip 61 is located above the thread 7 and faces upward and outward and forms a continuous outer circumferential surface. The diameter D3 of the inner root 63 of the lip 61 is smaller than the thread root diameter D4. The gasket sheet 64 is spread radially outwardly and upwardly so as to meet the rim 4 at the same point where the gasket sheet 8 meets the rim in the first embodiment. A conventional gasket 12 made of E.P.D.M, black nitrile or P.E. is spread over the gasket sheet 64 and takes the same open shape as shown in FIG.

The effect of the geometry changed in this second embodiment is that the lip 61 essentially has the same radial extension D1-D3 as the lip 9 of the first embodiment, and therefore the gasket lifting of the first embodiment. , Semi-gripping, semi-cyclizable functions are retained. The reduced lip diameter allows the closure plug to fit into a larger range of container openings. The spread gasket sheet 64 has two advantages. First, it provides an increased volume for the sealing gasket 12 in the area between the gasket sealing area 30 and the closing plug lip 61 of the container closing bushing 21, and secondly, the unfolded gasket 12. The truncated cone shape taken by provides an increased contact area between the gasket and the gasket sealing area 30 when the plug is screwed into the bushing 21. The sealing gasket is placed in the volume between the bushing sealing area 30 and the plug seat 64, and the tip of the gasket is initially compressed low (or not compressed at all). Therefore, preferably, the initial contact area between the gasket and the closing bushing is formed up to the side of the gasket. This is clearly shown in FIGS. 8 and 9, where the stopper thread, the rim and the lip 61 have a geometric shape similar to the embodiment shown in FIGS. 6 and 7, and the stopper is formed of a suitable plastic material. . The effect of increased contact area and low gasket tip compression is to further mitigate gasket cyclization while rotating the stopper.

Another advantage of the geometry used for the lip 61 is that the stopper shown in FIGS. 6 and 7 can be formed of a gauge steel thinner than that used for conventional stoppers while still maintaining an equivalent structure. To reinforce the stopper.

Using a standard gasket, when the stopper 60 is fully rotated back, the lip 61 can be in direct contact with the closing bushing wall 23 in the region of the bushing thread end point 29. Large gaskets, if desired, can be used to prevent metal to metal contact.

10 shows a fourth embodiment of the present invention, wherein the metal plug 66 has a lip 68 of the same geometry as the lip 61 of the second embodiment. The outer periphery groove 70 is roll-processed to the gasket sheet 72 at the root of the lip 68 so that the remaining part of the gasket sheet 72 may be cylindrical. This geometry provides a radial extension for the lip 68 that is the same as the lip 9, 61 of the first to third embodiments, and the groove 70 provides an increased volume relative to the gasket 12. to provide.

Various modifications or variations of the gasket retention plug of the present invention may be made within the scope of the appended claims. For example, the closure plug of the first embodiment can be made of metal, and the closure plugs of the second and fourth embodiments can be molded from a synthetic plastic resin.

Claims (15)

A cylindrical sidewall 3 having an outer helical thread 7; A plug rim 4 extending in the circumferential direction; Annular stopper gasket sheets (8, 64) directly below the stopper rim (4); In the closure plug formed with the gasket retaining lips 9, 61 extending continuously from the circumference to the radially outward under the plug gasket sheet (8, 64), Closing plug, characterized in that the gasket sheet (8, 64) is opened radially outward and upward to coincide with the closure rim (4). The method of claim 1, And the gasket sheet (64) is opened radially outward and upward directly from the root (63) of the gasket retaining lips (61). The method of claim 2, Closing stopper, characterized in that the gasket sheet 64 is truncated conical. The method of claim 1, The gasket retaining lip (61) is characterized in that it has a radial extension (D1) smaller than the external radial extension (D2) of the projection of the outer helical thread (7). The method of claim 1, The outer helical thread 7 ends at a point 10 in the retaining lip 9 and a closed stopper, characterized in that an evenly upward annular surface 11 is formed just above the point at which the thread ends. . 6. The method according to any one of claims 1 to 5, Closure stopper, characterized in that the diameter (D3) of the inner root (63) of the gasket retaining lips (61) is smaller than the diameter (D4) of the root of the outer helical thread (7). 6. The method according to any one of claims 1 to 5, The stopper 60 is a closure plug, characterized in that formed of metal or molded synthetic plastic resin. 6. The method according to any one of claims 1 to 5, Closure stopper, characterized in that an elastic sealing gasket (12) is spread over the gasket sheet (8, 64) and takes the shape of the gasket sheet (8, 64). The method of claim 8, The resilient sealing gasket (12) is characterized in that it takes the truncated conical shape of the gasket sheet (64). The method of claim 8, Closing stopper, characterized in that the elastic sealing gasket (12) is made of E.P.D.M, black nitrile, or P.E. A combination of an opening in a container wall 20 having a closure stopper and a bushing 21 according to claim 8, wherein the bushing 21 has an internal helical thread 28 and a flat gasket sealing region 30 extending outward. Having a cylindrical wall 23, the sealing gasket 12 radially compressed between the bushing gasket sealing region 30 and the closure gasket sheet 64 and adjacent to the internal helical thread 28 of the bushing. Placed assembly. delete delete delete delete

Images