US3558036A - Closure for containers - Google Patents

Abstract

A closure for a container comprising metallic foil and paper which are bonded together to form the closure. The closure is formed in a punch press to form a number of ridges in the foil which are forced into the mating surface of dampened paper. After the paper dries and shrinks, the ridges are intimately interlocked into the fibers of the paper.

Description

United States Patent Inventor John M. DeVoe Nashville, Tenn. Appl. No. 785,429 Filed Oct. 25, 1968 Division of Ser. No. 601,136, Dec. 12, 1966, Patent No. 3,408,902. Patented Jan. 26, 1971 Assignee United States Tobacco Company New York, N.Y. a corporation of New Jersey CLOSURE FOR CONTAINERS 3 Claims, 8 Drawing Figs.

US. Cl 229/43, 229/ 3.5 Int. Cl B65d 43/00,. B65d 5/64 Field of Search 229/43, 3 .SMF

[56] References Cited UNITED STATES PATENTS 3,297,225 1/1967 Bransten 229/3.5(M.F.) 3,406,891 10/1968 Buchner 229/3.5(M.F.) FOREIGN PATENTS 394,222 6/1933 Great Britain 229/3.5M.F.

Primary Examiner-David M. Bockenek Att0rney-Curtis, Morris & Safford ABSTRACT: A closure for a container comprising metallic foil and paper which are bonded together to form the closure.- The closure is formed in a punch press to form a number of ridges in the foil which are forced into the mating surface of dampened paper. After the paper dries and shrinks, the ridges are intimately interlocked into the fibers of the paper.

PATENTEU JAN26 1971 3; 558,036

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ATTORNEYS 711m MW CLOSURE FOR CONTAINERS This application is a division of application Ser. No. 60l,l36 filed Dec. 12, I966, now US. Pat. No. 3,408,902.

This invention relates to closures for containers and more particularly to fluid-tight or moistureproof closures formed of layers of paper and metal foil.

Moistureproof or vaporproof containers have been made by producing cardboard or paperboard containers and lining them with metal foil. In some of the prior containers the foil lining has been attached to the cardboard by gluing, but that has not proven to be a satisfactory way of producing the closures for such containers. A closure in which the layers are glued together is not sturdy, and it tends to lose its shape, which weakens the closed container, and it also causes the closure to fit less snugly against the container walls then is desired. A tight fit between the closure and the container is particularly important in a moistureproof container, and the lid should continue to hug the container tightly even after it has been removed from the container and replaced on it several times. a An object of this invention is to provide a container closure that is strong and sturdy, and which fits tightly on the container. A further object is to provide a container closure that will retain its desirable characteristics after repeated removal from the container and replacement thereon. A further object of the invention is to provide a simple and inexpensive method of making such closures. These and other objects will be in part obvious and in part pointed out below.

Stated in somewhat simplified form, this invention comprises forming container lids from paper and foil layers, e.g., in a punch press, while the paper is damp, and in such a way that a number of small, sharp ridges or barbed fins are created in the foil against the paper and are forced into the surface of the paper, after which the paper is shrunk. The ridges or fins are intimately interlocked into and are gripped by the fibers of the paper so that the lid is sturdy and compact. Hence, an integral lid is formed of the layers of paper and foil without the use of adhesive. 7

IN THE DRAWINGS FIG. 1 is a perspective view, with a portion cut away, of a container with closures made in accordance with the present invention;

FIG. 2 is a cross-sectional view of a portion of the container shown in FIG. 1, taken along line 2-2;

FIG. 3 is a cross-sectional view of a punch press for producing the closure shown in FIG. 1;

FIG. 4 is a plan view of the die portion of the punch press shown in FIG. 3, taken along line 44 in FIG. 3; and,

FIGS. 5 and 6 are similar to FIG. 3, except that they show the punch press in different stages of its cycle, and they are schematic in that they show a single sheet of the paper and foil.

FIGS. 7 and 8 are detailed sectional views of the completed closure.

Referring to FIG. 1 of the drawings, a cylindrical container 2 comprises a sidewall 4 and end closures 6 and 8. End closure 6 (see also FIG. 2) is in two layers, a paper layer 10 and a metal foil layer 12. Sidewall 4 is of similar construction, com prising both a paper layer 14 and a foil layer 16. Each of the layers of closure 6 is a single circular piece or disc which has been shaped to form a shallow cylinder with a flat, disclike end wall 18 and a cylindrical sidewall formed by portions 19 and 21, respectively, of the paper and foil layers. The internal diameter of sidewall 20 is such that it fits snugly against the sidewall4 of the container. The portion of the sidewall 20 that has been cut away to expose the cylindrical portion 21 of the foil layer 12 is enlarged in FIG. 8, and shows a great many small ridges 22 in portion 21. These ridges project into and interengage with the paper layer portion 19, creating a strong bond between the two layers and forming an integral mechanically-laminated wall.

FIGS. 3 through 6 show the portions of a standard punch press that have been adapted to produce closure 6 in accordance with the present invention. The punch press 24 includes a fixed die assembly 26 and a movable punch assembly 28 which moves vertically to engage the die 26 as shown in FIGS. 5 and 6.

Referring to FIG. 3, the die assembly 26 includes a shaft 30 upon which components of the die assembly are mounted. Attached in a stationary manner to shaft 30 are: a die shoe 32; a center post 34; a circular pad 36; and, a peripheral cutting ring 40. Pad 36 presents a flat upper surface except that it has a raised rim portion which presents an elevated peripheral edge surface 37. Edge surface 37 is an inverted frustoconical surface so that it slopes toward the center of pad 36. Circular pad 36 is surrounded snugly by a draw ring 38 which has frustoconical top surface 39, and (see also FIG. 4) is mounted resiliently in a manner later to be described. Draw ring 38 is surrounded snugly by cutting ring 40, the inner edge of the top of which is a cutting edge 42.

Draw ring 38 is adapted to slide vertically inside cutting ring 40 along the outside of pad 36 and central post 34 with its upward motion limited, however, by the engagement of a flange 44 on the draw ring with a horizontal edge surface 45 of ring 40. Draw ring 38 is supported by a plurality of rods 48, the upper ends of which are fixed to the draw ring, and each of which is rigidly attached at its lower end to a ring 49 that slides on shaft 30. A heavy compression spring 50 presses upward on ring 49 urging draw ring 38 toward the position shown. Spring 50 rests upon a disc 51, which is supported adjustably on shaft 30.

The punch assembly 28 of the punch press is located above the die portion 26 and moves downwardly and engages the die assembly in the course of each closure-forming cycle of the machine. Punch assembly 28 comprises: a punch head a punch holder 52 which is mounted in a fixed manner on head 55; and, a punch 54 which has a top flange 57 by which it is rigidly affixed to holder 52 by a clamp ring 56. Punch 54 is a circular ring which is similar to draw ring 38 and has the same general outer and inner radii except for the flanges 44 and 57. Punch 54 is positioned above the draw ring and has a bottom frustoconical surface 53 which is identical with surface 39 of the draw ring and forms a cutting edge which mates with cutting edge 42 of the stationary cutting ring 40. As the punch assembly moves downwardly to engage the die assembly, punch 54 enters the space between pad 36 and cutting ring 40, and surface 53 engages surface 39 so that the continued movement pushes draw ring 38 down, overcoming the upward force .of spring 50. Also, as will be explained below, the cutting edges interengage to cut a disc portion which is formed into a closure 6.

Slidably mounted within punch ring 54 and normally resting against punch holder 52 is a punch pad 58, which is of substantially the same radius as pad 36. Punch pad 58 has a bottom surface which is flat except that the edge is somewhat beveled to form a frustoconical edge surface 60 that is adapted to mate with the raised edge surface 37 of pad 36. Punch pad 58 is rigidly mounted on a shaft which is surrounded by a compression spring 62 by which the shaft and the punch pad are normally held in the position shown in FIG. 3. Punch pad 58 contains a plurality of air vents 64 which are normally closed by valves 63 which are urged to closed position by springs 65. However, the vents are opened when the projecting noses of valve 63 are pressed upwardly.

The sheets of paper 66 and foil 68 from which the closures are produced are drawn through the punch press from left to right with foil sheet 68 passing just above the upper surface of die assembly 26 and with the paper sheet 66 directly above the foil sheet. The paper and foil sheets are guided in this movement by a metal plate 70 located a short distance above the upper surface of the die assembly 26 and forming a narrow horizontal slot 72, through which the paper and foil sheets pass. A circular hole 74 in plate 70 is of a size to permit the punch 54 to pass through it.

In the illustrative embodiment, the foil is a thin steel foil, and the paper is kraft lined can bottom stock" of .03 inch thickness. Prior to fabrication the paper is softened by soaking it with a light soap solution. In practice; each day the paper which is to be used the following day is wetted on a rewinder onto rolls which are stored over night in closed containers. Hence, the paper is relatively soft, although it retains sufficient strength to permit fabrication at a commercially satisfactory rate.

The paper and foil sheets advance step-by-step with each step being for a set distance during the sheet feeding portion of each cycle when the punch assembly is in the position shown in FIG. 3, and remaining stationary when the punch is engaging the die as shown in FIGS. 5 and 6.

The operation of the punch press is illustrated in FIGS. 5 and 6 and is as follows: As the punch head moves downwardly, punch ring 54 forces the paper and foil sheets downwardly to cutting ring 40 and thence as the punch moves past the cutting edge 42 of ring 40 the punch cooperates with the cutting edge to cut both sheets to produce a circular piece or disc from each of the sheets. The two discs thus formed are unattached at this time and by the further cooperative action of the punch and die assembly they are formed into a container closure. As the punch assembly continues to move downwardly, the peripheral portion of each of these discs is trapped between the upper surface 39 of draw ring 38 and the lower surface 53 of punch ring 54. However, as the punch continues its downwardly motion, forcing the draw ring down before it, the peripheral portions of the paper and foil discs slip between the punch and draw rings and are reformed to a cylindrical form so that they assume a vertical position between the inner surface of punch ring 54 and side wall of pad 36. The forming of the sidewalls of the closure in this manner produces the foil ridges 22 and they are embedded in the surface of the paper, the space between pad 36 and punch ring 54 being only large enough to accommodate the layers in this manner.

The inverted frustoconical edge portion of pad 36 (FIG. 6) cooperates with the peripheral surface of pad 58 to form the foil into a firm corner which acts as a rigid rim interconnecting the disclike foil endwall with the cylindrical foil sidewall. The inner surface of the foil is extremely smooth, with only small lines which are formed by the producing of the external ridges 22. The forming involves bending the blanks around the raised periphery of pad 36 (see FIG. 5) as the punch ring pushes the peripheral portions of the blanks downwardly. The peripheral portions are held in somewhat frustoconical shape by the clamping action between the punch ring and the draw ring 38, and are gradually drawn into the cylindrical shape. The drag" caused by the action of the punch ring upon the blanks produces a peripheral tension upon the central disc portions of the blanks so that they are held somewhat taut. At the end of the downward movement of the punch ring, pad 58 cooperates in producing the final smooth comer. It should be noted that FIGS. 5 and 6 are somewhat schematic with respect to dimensions and the relative positioning of the parts.

As pad 58 approaches pad 36, the trapped air lifts valves 63 and the air escapes through vents 64. When the punch head reaches the bottom of its stroke, the pads press the paper and foil layers together. As the punch head begins its upward motion, the completed closure is pushed from its position on pad 36 by the draw ring 38 which moves upwardly with the punch head and which engages the bottom edge of the cylindrical closure wall and pushes the closure upwardly. Thus, the

completed closure remains within the punch ring 54 beneath the punch pad 58 after the disengagement of the die and punch portions of the press.

When the punch ring 54 moves upwardly towards the position of FIG. 3, punch pad 58 is pushed downwardly against the action of spring 62 to eject the closure from the punch ring. This is caused by a knocker" (not shown) driving the central supporting shaft 59 downwardly against the action of its spring 61. The sheets 66 and 68 of the paper and foil are then advanced another step frorn their supply rolls, and the punching and forming operation IS repeate While only one die assembly is shown in the drawings, it is understood that several such assemblies are mounted together on shaft 59, and are operated simultaneously.

Subsequent to the forming of the closure as discussed above, the paper is dried so that it shrinks around the foil liner. The shrinking urges the paper fibers in around the ridges '22, and the paper is hardened so that the closure is an integral sturdy structure. The shrinking of the paper draws it tightly around the comer edge of: the foil liner in a smooth corner from the flattop surface.

As has been pointed out above, sheet 68 in the illustrative embodiment is thin steel foil. In one particular example, the steel is tin-plated steel foil of .02 inch thickness. The working of the metal foil produces work hardening so that it has superior characteristics. Tests indicate that container closures made with such foil and the paper sheet referred to above are superior to metal lids from various standpoints, including resistance to shock. Also, such closures are superior from the standpoint of being thoroughly satisfactory over extended periods of use during which a closure may be removed from its container and replaced many times. The thin steel cylindrical wall and .the rigid corner have resiliency and tend to retain the original shape. The paper provides impact protection and causes the closure to hug the container wall.

It has been found that hard aluminum foil also gives very satisfactory results in place of the steel foil. The invention contemplates that various types of paper board may be used provided they are not water repellent or water proof. The illustrative embodiment of the invention is a closure for small containers which may be used for snuff. However, it is contemplated that the invention includes the production of other components.

I claim:

1. A closure for a container comprising, an endwall portion and a peripheral sidewall portion, said endwall portion comprising coextensive layers of metal foil and paper and said sidewall portion comprising coextensive layers of metal foil and paper which are integral peripheral extensions of the firstmentioned layers of metal foil and paper forming said end wall portion, said peripheral extension of said metal foil including a plurality of ridges on one surface thereof, said peripheral extension of said paper being in contact with said one surface of said metal foil, and said ridges on said one surface being intimately interlocked and gripped by the fibers of the paper adjacent thereto thereby to bond said metal foil and paper together.

2. A container closure as described in claim 1 wherein said endwall portion is flat and said sidewall portion is cylindrical.

3. A container closure as described in claim 1 wherein said metal foil is tin-plated steel foil and said paper is kraft-coated paper.

Claims (3)

1. A closure for a container comprising, an endwall portion and a peripheral sidewall portion, said endwall portion comprising coextensive layers of metal foil and paper and said sidewall portion comprising coextensive layers of metal foil and paper which are integral peripheral extensions of the first-mentioned layers of metal foil and paper forming said end wall portion, said peripheral extension of said metal foil including a plurality of ridges on one surface thereof, said peripheral extension of said paper being in contact with said one surface of said metal foil, and said ridges on said one surface being intimately interlocked and gripped by the fibers of the pAper adjacent thereto thereby to bond said metal foil and paper together.

2. A container closure as described in claim 1 wherein said endwall portion is flat and said sidewall portion is cylindrical.

3. A container closure as described in claim 1 wherein said metal foil is tin-plated steel foil and said paper is kraft-coated paper.

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