KR20040089113A - 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. 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 planes 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 ( Between 8,64,72 and lies adjacent to the inner 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}

In the transport container industry, it is most common to manufacture drums, pails, and the like having one or more dispensing and / or filling openings. These openings have internal helical screw screws that incorporate unthreaded gaskets. An externally threaded closure plug having an annular sealing gasket is screwed 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. Important in this relationship is on the one hand between the plug and its gasket and on the other hand on the integration of the container opening screw into the opening gasket sealing area. This relationship applies the twist required to seal the closure to the actual container opening, which causes the closure gasket to be forced into the run-out of the thread inside the opening. It is common for the wedge action of such a gasket against the opening screw to grip the plug gasket in close contact when the plug continues to turn out. By continuing to pull out, a thin state follows. Most notably, as the plug proceeds out of the opening, the gasket can be held on the internal opening screw, so that the gasket is peeled off at the gasket seating position on the plug. As the gasket is pinched between mating screws, 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 the tendency of the gasket to wrap out of the gasket sheet during torsion of the plug. This problem occurs when the plug gasket movement around the unthreaded gasket sheet of the opening is impeded to cause the gasket to corrugate and form a loop that protrudes from the edge of the opening. One way to create this obstacle is when the plug goes into the diameter opening and again catches on the opening screw projection. The resulting “looping” state creates the most reliable leak path and probably adds serious damage to the gasket. Of course, the commonality between “gripping” and “ringing” is the ability to keep the gasket in place on the gasket sheet to which it belongs so as to prevent it from being attracted to each other by screwing together.

It has conventionally been justified the need for any reliable mechanical holding means to hold the plug gasket in place. For example, Stolzman, US Pat. No. 5,211,304, discloses a closure structure in which a gasket is held fixed on the underside of the closure rim in a mechanical interlocking arrangement. However, this arrangement places a radially outward gasket on the cap screw, and has no relationship to any other kind of "grip" or "ring" problem. Another prior art was recognized in US Pat. No. 2,906,429 to Marchyn, who recognized the problem of "ringing" but failed to provide a completely satisfactory solution. In this patent, the plug has a special screw form in which the screw borders the gasket sheet. In particular, the closure has a shrinking screw that runs around the lower edge of the gasket sheet and acts as a partial barrier just above the conventional closure screw. However, this modified screw configuration was insufficient to provide adequate protection against the “gripping” phenomenon, as will be clearly seen next.

The present invention relates to an improved container closure closure, and more particularly to a screw closure having unique gasket features.

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 combination 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 unscrewed 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 unscrewed position;

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

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 is formed from a cylindrical sidewall having a circumferentially extended rim with a helical screw screw, and a gasket sheet just below the closure rim, with the radially outwardly extending gasket retaining lip being continuous. It is sandwiched between a stopper gasket seat and sidewall screws.

According to one embodiment of the invention, the gasket retaining lip is in axial alignment with the screw screw root diameter.

According to another embodiment of the present invention, the gasket retaining lip has a radial extension smaller than the outer radial extension of the floor of the sidewall screw and an internal root diameter smaller than the screw root diameter.

According to a variant of this yet another embodiment, the gasket sheet spreads radially outward and upward to coincide with the rim.

According to a variant of this still further embodiment, the gasket sheet is provided with a peripheral groove in the gasket retaining lip.

According to a further aspect of the invention, the sealing gasket is located on the gasket sheet. The sealing gasket is elastic and spreads over the stopper to embrace the gasket sheet. With the closure plug according to this another embodiment, the shape of the seating gasket in which the sealing gasket is opened is estimated.

In addition, according to the invention, the closure plug is combined with a container wall opening having a threaded portion and an unthreaded portion therein, a sealing gasket compressed between the unthreaded opening portion and a plug gasket sheet and placed close to the inner thread. And a continuous circumferential radially outwardly extending gasket retaining lip is interposed between the gasket seat and the sidewall screws to prevent mutual engagement of the sealing gasket with the internal threaded opening portion, thereby sealing and plugging as an unobstructed unit. Non-intrusive screw disengagement of the gasket stopper is performed.

The closure closure according to the invention provides a long search after solving the above-mentioned "gripping" and "ringing" problems in a simple direct manner.

In an example, the closure plug is formed with disks such as cylindrical screw sidewalls and bottom walls. 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 screw. An elastic sealing gasket extends over the gasket sheet occupying the vertical space between the plug rim and the retaining lip. The stopper described above is screwed into a container wall having a gasket sealing area facing inwardly with the inner screw screw. The conventional important relationship existing between the plug gasket and the container screw opening is now very insignificant. As the stopper retracts from the container screw opening, the gasket is held firmly in place on the stopper gasket sheet by the gasket retaining lip. The resulting clean separation of the closure gasket from the container opening constitutes a significant improvement over the prior art.

According to a principal principle feature of the present invention, there is provided an improved threaded closure closure for industrial size containers.

An additional feature is to provide a new and improved gasket seat configuration.

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

Additional and more detailed features will be in part apparent and in part become apparent from the detailed description of the invention taken in conjunction with the accompanying drawings.

The closure plug according to the first embodiment of the invention is shown in FIGS. 1 to 4, indicated by reference numeral 1, and 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 external helical screw screw 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 stopper screw root diameter. This relationship is advantageous in ensuring a sufficient gasket volume between the closure of the container and the opening of the container that joins the closure path. The closure side wall 3 is formed with a retaining lip 9 in the circumferential direction at the upper end of the screw 7, the upper end of the screw extending radially outward with the screw projection and axial alignment. As clearly shown in FIG. 1, the closure screw protrudes upwardly and uniformly contiguous annular surface lying in a plane parallel to the bottom surface 4a of the closure rim 4 and directly above the screw termination point 10. End at point 10 in lip 9 leaving (11). An elastic annular sealing gasket 12 having a substantially square cross-sectional shape is spread over the stopper to embrace the gasket sheet 8. Thus, the gasket is clamped snugly between the lower face 4a of the closure rim 4 and the upper face 11 of the retaining lip 9, quite differently from the removal of the gasket 12 from the gasket sheet 8. Make.

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 terminating in a radially outwardly corrugated 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 bushing pleat 24. The bushing gasket 27 is compressed between the bushing 21 and the peripheral surfaces of the container wall 20. An internal helical screw screw 28 is formed in the bushing wall extending from the base 22 to the threaded protrusion point 29 at the beginning of the bead 24. The upwardly extending unthreaded bead portion just above the protruding point 29 forms a smooth gasket sealing region 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 helical screw projection and the 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 screw 28 at any point. With the screw disengagement of the plug as shown in FIG. 4, the gasket retaining lip 9 lifts the plug gasket 12 very clearly from the bushing screw 28 and from the gasket sealing region 30. This is due to this clear separation of the plug gasket from the surrounding bushing surfaces, which has so far eliminated common gasket “gripping” and gasket “ringing” problems.

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 stopper gasket 42 is seated on the gasket sheet 43 formed at the root diameter of the stopper screw, but the stopper screw 44 is simple as indicated by reference numeral 45 as it approaches the gasket seat 43. Is reduced. Under this conventional technique, which can be seen by the retraction of the stopper, the gasket 42 has little axial support supplied by the reduced screw 45. As a result, the gasket is easily caught between the interlocking closing screws and peels off the gasket sheet, creating a serious impediment to normal closure functionality.

Second and third embodiments of the present invention are shown in FIGS. 6-7 and 8-9 and are variations of the first embodiment described with reference to FIGS. 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 an included angle of 55 °, a radial extension D1 smaller than the outer radial extension D2 of the protrusion of the screw 7 and a plug rim 4 The roll is machined so as to lie in a plane parallel to the lower surface 4a of the. The upper flank flesh 62 of the retaining lip 61 forms a continuous peripheral upward and outward facing surface just above the screw screw 7. The diameter D3 of the inner root 63 of the lip 61 is smaller than the screw root diameter D4. The gasket sheet 64 is spread radially outwardly 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. spreads over the gasket sheet 64 and assumes the same open shape as shown in FIG.

The effect of the changed geometry in this embodiment is that the lip 61 essentially has the same radial extension D1-D3 as the lip 9 in the first embodiment, thus lifting the gasket of the first embodiment, Semi-gripping, semi-cyclizing properties are retained. The reduced lip diameter may allow the closure plug to fit into a larger range of container openings. The spread gasket sheet 64 has two advantages. Firstly, an increased volume for the sealing gasket 12 is provided in the area between the closing plug lip 61 and the gasket sealing area 30 of the container closing bushing 21, and secondly, the unfolded gasket 12. The corner truncated conical shape, estimated by P, is screwed into the bushing 21, thereby providing an increased contact area between the closure plug lip 61 and the gasket sealing area 30. The sealing gasket is encased in the volume between the bushing sealing area 30 and the stopper sheet 64, and the tip of the gasket is initially compressed low (or unevenly). Therefore, advantageously, the initial contact band between the gasket and the closing bushing is somewhat up to the side of the gasket. This is clearly seen in FIGS. 8 and 9 where the stopper screw, rim and lip 61 have a geometric shape similar to the embodiment shown in FIGS. 6 and 7, but the stopper is formed of a suitable plastic material. The effect of increased area contact and low gasket tip compression further mitigates gasket cyclization during plugging.

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

Using a standard gasket, it is possible for the lip 61 to directly contact the closing bushing wall 23 into the area of the bushing screw projection 29 when the stopper 6 is twisted entirely into the groove. Oversized gaskets can be used to prevent metal to metal contact if desired.

Fig. 10 shows a fourth embodiment of the present invention, in which the metal plug 66 has a lip 68 of the same geometry as the lip 61 of the second embodiment. There is a difference that the peripheral groove 70 is rolled into the gasket sheet 72 at the root of the lip 68 so as to leave the rest of the cylindrical gasket sheet 72. This geometry provides the same radial extension for the lips 9 and 61 and the lips 68 of the first to third embodiments, the groove 70 providing an increased volume for the gasket 12. do.

Various variations or modifications of the gasket retention plug of the present invention may be made. 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)

In the closed stopper formed with a cylindrical side wall 3 having an outer helical screw screw 7, a circumferentially extending rim 4 and an annular gasket sheet 43 directly below the plug rim, in a continuous radial circumferential direction. Closing stopper, characterized in that the outwardly extending gasket retaining lips 9, 61, 68 are fitted between the stopper gasket sheet 8, 64, 72 and the side wall screws 7. 2. Closure stopper according to claim 1, characterized in that the gasket retaining lips (9, 61, 68) lie in a plane parallel to the bottom face (4a) of the closure rim (4). Closing plug according to claim 1, characterized in that the gasket retaining lips (9) are in substantial axial alignment with the screw thread root diameter. 4. The side wall screw (7) according to any one of claims 1 to 3, protrudes and terminates at a point within the retaining lip (9); Closure stopper, characterized by leaving a uniform annular surface 11 facing upwards directly above the screw end. The gasket retaining lips 61, 68 according to claim 1, wherein the gasket retaining lips 61, 68 have a radial extension D1 smaller than the outer radial extension D2 of the floor of the sidewall screw and a smaller than the screw root diameter D4. Closure stopper, characterized in that the inner root (63) having a diameter (D3). 6. The closure plug of claim 5, wherein the gasket sheet (64) is radially outwardly and upwardly aligned with the rim (4). 6. The closure closure of claim 5 wherein the gasket sheet (72) is provided with a peripheral groove (70) at the root (74) of the gasket retaining lip (68). 8. Closure stopper according to any of the preceding claims, wherein the stopper (1,60,66) is formed of a metal or of a synthetic plastic resin molded. 8. Closure stopper according to any of the preceding claims, characterized in that the sealing gasket (12) is located on the gasket sheet (8,64,72). 10. A closure closure according to claim 9, wherein the sealing gasket (12) is elastic and spreads over the stopper (1,60,66) to embrace the gasket sheet (8,64,72). The sealing gasket 12 is in close contact with the radially opening groove formed by the gasket retaining lip 9, the gasket sheet 8, and the stopper rim lower surface 4a. Closure plug, characterized in that limited. The closure closure of claim 6 or 10, wherein the sealing gasket (10) estimates the shape of the open gasket sheet (64). 13. A closure closure according to any of the preceding claims, wherein the sealing gasket (2) is made of E.P.D.M, black nitrile or P.E. Container wall opening, unthreaded opening portion and stopper gasket seat (8, 64, 72) having a closed stopper and an internal threaded portion (28) and an unthreaded portion (30) as claimed in any of claims 9-13. In combinations of sealing gaskets 12 compressed between and positioned close to the inner thread, the continuous circumferential radially outwardly extending gasket retaining lips 9, 61, 68 are provided with the sealing gasket 12 and the interior. By being sandwiched between the stopper gasket sheets 8, 64, 72 and the side wall screws 7 to prevent mutual engagement of the bare opening portions 28 of the screw; A combination characterized in that an unintrusive screw disengagement of the stopper (1,60,66) and the stopper of the sealing gasket (1,60,66) is performed as an unobstructed unit. The combination according to claim 14, wherein the container wall unscrewed portion (30) extends upwardly and radially outwardly from the gasket retaining lips (9, 61, 66).