GB2080436A

GB2080436A - Internally pressurized fluid containers

Info

Publication number: GB2080436A
Application number: GB8113696A
Authority: GB
Original assignee: SEXTON CAN CO Inc
Current assignee: SEXTON CAN CO Inc
Priority date: 1980-07-16
Filing date: 1981-05-05
Publication date: 1982-02-03
Also published as: MX154778A; BR8104471A; IT1142771B; DE3120375C2; JPS5747099A; IT8148513A0; GB2080436B; CA1156569A; JPS6152360B2; DE3120375A1; AR223436A1

Abstract

An internally pressurized fluid container has a dome-shaped inwardly concave closure element 16 circumferentially joined to one end of the tubular container side wall. The closure element is deep drawn of tempered steel, with a circular central area 34 spaced from an annular outer area 24 by an annular intermediate area 26 traversed by radially extending Lüders Lines 30. A tab member is located in the central area 34. The tab member is partially circumscribed by a single weakened circular line 36 of reduced material thickness, with the ends of the line being separated by a connecting area 38 of substantially undisturbed material thickness and strength. An increase in fluid pressure above a prescribed level causes a fracture of the closure element 16 along the weakened line of reduced material thickness. <IMAGE>

Description

SPECIFICATION Internally pressurized fluid containers Pressurized fluid containers are in widespread use for packaging and dispensing a variety of fluid products, including liquids, gases and combinations thereof. Under normal operating conditions, such containers perform entirely satifactorily. However, in the event that the contents of such containers should become over pressurized, either because of improper use, exposure to heat or for any other reason, then a violent rupture may occur. For the last 25 years, those skilled in the art have been attempting to solve this problem by incorporating various types of pressure release devices into the container structures. Examples of some of these previously developed pressure release devices as disclosed in U.S.Patent Nos. 2,795,350 (Lapin); 3,074,602 (Shillady et al); 3,292,826 (Ablanalp); 3,622,051 (Benson); 3,826,412 (Kneusel); 3,831,822 (Zundel); and 4,003,505 (Hardt). However, for a variety of reasons including unreliability, high cost, difficulty of maintaining critical tolerances during manufacture, etc., none of these devices has proved to be acceptable.

The objective of the present invention is to provide an improved pressure release device which operates reliably within a predictable range of pressures, which is simple in design and capable of being mass produced, and which can be integrally incorporated into the container structure at a reasonable cost to the consumer.

In accordance with the present invention there is provided an internally pressurised fluid container comprising a tubular side wall and dome-shaped inwardly concave closure element circumferentially joined to one end of the side wail, the closure element being deep drawn of tempered steel, with a circular central area spaced from an annular outer area by an annular intermediate area traversed by radially extending Lüders Lines and with a portion of the central area being partially circumscribed by a single weakened line of reduced material thickness, the line lying on a circle, with the ends of the line being separated by a connected area of substantially undisturbed material thickness and strength.

With such a construction, the closure element reacts to an increase in container pressure above a prescribed level by initially undergoing at least a partial eversion of the annular outer area. This eversion progresses rapidly in wave form in a generally radial direction across the annular intermediate area and into the circular central area to produce a stress concentration which causes a fracture of the closure element along the weakened line. As the over pressurized contents of the container are exhausted through this fracture, the original partially circumscribed or tab portion of the closure element (which portion is preferably dome-shaped and outwardly convex) remains connected or hinged to the element by the metal between the ends of the weakened line and is deflected outwardly by the pressure within the container.

A preferred embodiment of the invention will now be described with reference to the accompanying drawings wherein: Figure 1 is a bottom perspective view of a container including a closure element in accordance with the present invention; Figure 2 is a bottom plan view on a greatly enlarged scale of the container shown in Figure 1; Figure 3 is a sectional view taken along line 3-3 of Figure 2; Figure 4 is a sectional view on an enlarged scale taken along line 4-4 of Figure 2; Figures 5 and 6 are views similar to Figures 2 and 3 showing the first stages of partial eversion as a result of the container contents being overpressurized; Figures 7 and 8 are again views similar to Figures 2 and 3 showing a further development of the partial eversion;; Figures 9 and 10 are again views similar to Figures 2 and 3 showing fracture of the weakened line surrounding the pressure release tab, with accompanying exhaustion of the overpressurized container contents; and Figures 10 and 11 are views similar to Figures 9 and 10 showing the resulting fracture of the weakened line when the partial eversion occurs between the connecting area of the tab member and the container rim.

Referring initially to Figures 1-4, a container of the type conventionally employed to package and dispense pressurized fluids is shown at 10.

The container has a tubular metal side wall 12 which is stepped at one end as at 14 to accommodate a conventional cap or the like (not shown). A dome-shaped inwardly concave closure element 1 6 is applied to the opposite end of the side wall 12. The closure element may be circumferentially joined to the side wall by any conventional means, preferably the double seam connection indicated at 1 8 in the drawings.

The closure element 1 6 is deep drawn of tempered steel with a circular central area 20 illustratively defined in the drawings by an imaginary dot-dash line 22. The circular central area 20 is spaced from an annular outer area 24 by an annular intermediate area 26, again illustratively defined in the drawings by imaginary dot-dash lines 22 and 28.

The annular intermediate area 26 is traversed by radially extending Luders Lines indicated typically at 30. The Lüders Lines are visible as surface markings, or surface roughening, caused by inhomogeneous yielding during the deep drawing operation. The closure element 1 6 is further characterized by a pattern of biaxial crisscrossed strain lines indicated typically at 32 in the annular outer area 24. These lines are also believed to be the result of in homogeneous yielding during the deep drawing operation.

From the standpoint of material thickness, the annular intermediate area 26 is thinner than both the circular central area 20 and the annular outer area 24. The annular outer area 24 is thicker than the circular central area 20. These thickness relationships are again the result of the deep drawing operation.

A tab member 34 is located in the circular central area 20. The tab member is partially circumscribed by a single weakened line 36 of reduced material thickness. The line 36 lies on a circle concentric with the focal point of the Lüders Lines and the center of the closure element 1 6.

The ends 36' of the weakened line 36 are separated by a connecting area 38 of substantially undisturbed material thickness and strength. The tab member 34 is dome-shaped and outwardly convex, with the weakened line 36 consisting of a groove in the concave outer surface.

The closure element 1 6 has a structural integrity which reacts to an increase in fluid pressure above a prescribed level by initially undergoing at least a partial eversion at the annular outer area 24. An example of one such partial eversion is illustrated at 40 in Figures 5 and 6. Based on available experimental data, the initial eversion 40 appears to commence at random locations with respect to the outer rim of the closure element, with a rapid snap-through of a local area from the as-drawn inwardly concave configuration to the somewhat convex shape shown in the drawings. As illustrated in Figures 7 and 8, this area of initial eversion then progresses radially in a wave form as shown at 40' across the annular intermediate area 26 into the circular central area 20.The radially arranged Luders Lines appear to concentrate the inwardly radially spreading partial eversion 40" thereby setting up a high concentration of bending stresses along the weakened line 36 bordering the tab member 34.

This high stress concentration is more than sufficient to initiate a local fracture of the closure element 16 along the weakened line 36 as indicated at 42 in Figures 9 and 10. The over pressurized contents of the can are then vented through the fracture 42. As this occurs, the fracture will progress around the line 36 allowing the venting rate to increase as necessary. The connecting area 38 serves as a hinge about which the tab member 34 is deflected outwardly under the influence of the escaping pressurized contents.

Connecting area 38 has sufficient strength to withstand fracture, thereby maintaining the tab member 34 connected to the remainder of the closure element 1 6 as venting takes place.

As previously indicated, initial localized eversion of the annular outer area occurs in a random manner. Under certain circumstances where this initial eversion occurs between the tab connecting area 38 and the outer rim of the closure element, the eversion will progress inwardly radially as indicated at 40a in Figures 11 and 12, eventually enveloping the tab member 34 before localized fracture occurs as at 42a.

A number of significant advantages result from the above-described combination of features. For example, by locating the tab member 34 centrally with respect to the Lüders Lines radially.traversing the annular intermediate area 26, a fracture ofthe weakened line 36 can be achieved dependably within a predictable pressure range due to the concentration of bending stresses accompanying pressure-actuated eversion. This concentration of bending stresses is sufficiently great to compensate for variations in material strength and thickness at the weakened line 36 as a result of normal tool wear.

The central circular area 20 is relatively unstressed with a lower order of work hardening as compared to annular areas 26 and 24. Thus, the connecting area 38 has the strength and flexibility to maintain a connected relationship between the tab member 34 and the remainder of the closure element 1 6 following fracture at the weakened line 36.

The outwardly convex configuration of the tab member 34 relative to the inwardly concave shape of the remainder of the closure element 1 6 also is advantageous in that it insures that the material on opposite sides of the weakened line 36 is pulled apart under tension rather than being pressed together at the moment of fracture.

Because of its configuration and location, the tab member 34 is particularly suited to mass production techniques, without unduly increasing costs to the consumer.

Claims

1.An internally pressurised fluid container comprising a tubular side wall and a dome-shaped inwardly concave closure element circumferentially joined to one end of the side wall, the closure element being deep drawn of tempered steel, with a circular central area spaced from an annular outer area by an annular intermediate area traversed by radially extending Lüders Lines and with a portion of the central area being partially circumscribed by a single weakened line of reduced material thickness, the line lying on a circle, with the ends ot the line being separated by a connecting area of substantially undisturbed material thickness and strength.

2. A container according to Claim 1 , wherein the circle is concentric with the focal point of the Luders Lines.

3. A container according to Claim 1 or Claim 2, wherein the circle is concentric with the centre of the closure element.

4. A container according to any one of the preceding Claims, in which the partially circumscribed portion of the central area of the element is generally dome-shaped and outwardly convex.

5. A container according to any one of the preceding Claims, wherein the annular intermediate area is thinner than the central circular area and the annular outer area.

6. A containers according to any one of the preceding Claims, wherein the annular outer area is thicker than the central circular area.

7. A container according to Ciaim 1, and substantially as herein described with reference to the accompanying drawings.