Vented beverage can and can end

Abstract

A beverage can end has a vent (40) that includes a button (50). The vent is actuated by downward force of a pull tab (70) that is transmitted to the vent score (42) through the button. The center panel (18) includes beads.

Claims

1. A beverage can end comprising: a peripheral curl capable of being joined to a can body by seaming; a wall structure radially inward from the curl; a center panel; a main score defining a main hinge and a main tear panel that is capable of opening upon rupture of the score to form a pour opening; a tab coupled to the center panel by a rivet, the tab having a nose capable of contacting a portion of the main tear panel for rupturing the main score, a body, and a heel formed opposite the nose, the heel being configured for grasping by a user; a raised main bead having a first end located proximate the heel side of the tab and extending around the main tear panel to a second end; a vent including: a vent score defining a vent tear panel and a vent hinge located approximately between opposing ends of the vent score; and an upwardly protruding button located on the vent tear panel; and a recessed vent bead located about the vent score, the main bead and the vent bead being continuous such that the main bead and the vent bead join at a transition in which the raised main bead yields to the recessed bead; whereby actuation of the tab by lifting the heel is capable of rupturing the main score and actuation of the tab by pressing down on the tab is capable of rupturing the vent score.

2. The beverage can end of claim 1 wherein the transition is located approximately opposite from main bead first end.

3. The beverage can end of claim 1 wherein the vent button is located outboard of the tab while the tab is positioned to actuate the main score and the vent panel bead is located proximate a peripheral edge of the center panel distal from the rivet, whereby the vent is located to enhance venting.

4. The beverage can end of claim 1 wherein the vent score is located on the button or having a distance D3 or D13 from the button sidewall, measured at a point at which the vent score is closest to the button sidewall, of no more than 0.020 inches such that downward force transmitted from the tab heel to the button ruptures the vent score, whereby actuation of the tab by lifting the heel is capable of rupturing the main score and actuation of the tab by pressing down on the tab is capable of rupturing the vent score.

5. The beverage can end of claim 4 wherein the distance D3 or D13 is between 0.000 inches and 0.006 inches.

6. The beverage can end of claim 4 wherein the vent hinge is oriented such that the score rupture propagates about the vent tear panel in two directions to the vent hinge.

7. The beverage can end of claim 4 wherein the vent score is located between approximately 0.060 inches and approximately 0.105 inches from the centerline of the button.

8. The beverage can end of claim 4 wherein a radius of the curved transition is between approximately 0.005 inches and approximately 0.020 inches.

9. The beverage can end of claim 4 wherein a radius of the curved transition is between approximately 0.0075 inches and approximately 0.0115 inches.

10. The beverage can end of claim 4 wherein a radius of the curved transition is approximately 0.0095 inches.

11. The beverage can end of claim 4 wherein the button has a diameter of between approximately 0.10 inches and approximately 0.18 inches.

12. The beverage can end of claim 4 wherein the button has a diameter of between approximately 0.115 inches and approximately 0.15 inches.

13. The beverage can end of claim 4 wherein the button has a diameter of approximately 0.130 inches.

14. The beverage can end of claim 4 wherein the vent hinge is opposite the rivet.

15. The beverage can end of claim 4 wherein the tab has a contact element that is configured to contact the button and wherein the tab contact element is a downwardly protruding bead.

16. The beverage can end of claim 1 wherein the vent defines: a dimension X from a button center to lateral ends of the vent score along a vent centerline CL, a dimension Y from the button center to the vent hinge, and a dimension Z from the button center to a proximal point of the vent score that is the point on the vent score that is closest to the button, dimension X is greater than Z and less than 5Z and dimension Y is greater than 0.5Z and less than 3Z.

17. A beverage can end comprising: a peripheral curl capable of being joined to a can body by seaming; a wall structure radially inward from the curl; a center panel; a main score defining a main hinge and a main tear panel that is capable of opening upon rupture of the score to form a pour opening; a tab coupled to the center panel by a rivet, the tab having a nose capable of contacting a portion of the main tear panel for rupturing the main score, a body, and a heel formed opposite the nose, the heel being configured for grasping by a user, the tab being elongate along a main centerline CL; a raised main bead having a first end located proximate the heel side of the tab and extending around the main tear panel to a second end, the main bead being asymmetric about the main centerline CL; a vent including: a vent score defining a vent tear panel and a vent hinge located approximately between opposing ends of the vent score; and an upwardly protruding button located on the vent tear panel; and a raised or recessed vent bead located about the vent score, the vent bead being spaced apart from the main bead; whereby actuation of the tab by lifting the heel is capable of rupturing the main score and actuation of the tab by pressing down on the tab is capable of rupturing the vent score.

18. The beverage can end of claim 17 wherein the vent button is located outboard of the tab while the tab is positioned to actuate the main score and the vent panel bead is located proximate a peripheral edge of the center panel distal from the rivet, whereby the vent is located to enhance venting.

19. The beverage can end of claim 17 wherein the vent score is located on the button or having a distance D3 or D13 from the button sidewall, measured at a point at which the vent score is closest to the button sidewall, of no more than 0.020 inches such that downward force transmitted from the tab heel to the button ruptures the vent score, whereby actuation of the tab by lifting the heel is capable of rupturing the main score and actuation of the tab by pressing down on the tab is capable of rupturing the vent score.

20. The beverage can end of claim 19 wherein the distance D3 or D13 is between 0.000 inches and 0.006 inches.

21. The beverage can end of claim 19 wherein the vent hinge is oriented such that the score rupture propagates about the vent tear panel in two directions to the vent hinge.

22. The beverage can end of claim 19 wherein the vent hinge is opposite the rivet.

23. The beverage can end of claim 19 wherein the tab has a contact element that is configured to contact the button and wherein the tab contact element is a downwardly protruding bead.

24. The beverage can end of claim 17 wherein the vent defines: a dimension X from a button center to lateral ends of the vent score along a vent centerline CL, a dimension Y from the button center to the vent hinge, and a dimension Z from the button center to a proximal point of the vent score that is the point on the vent score that is closest to the button, dimension X is greater than Z and less than 5Z and dimension Y is greater than 0.5Z and less than 3Z.

25. A beverage can end comprising: a peripheral curl capable of being joined to a can body by seaming; a wall structure radially inward from the curl; a center panel; a main score defining a main hinge and a main tear panel that is capable of opening upon rupture of the score to form a pour opening; a tab coupled to the center panel by a rivet, the tab having a nose capable of contacting a portion of the main tear panel for rupturing the main score, a body, and a heel formed opposite the nose, the heel being configured for grasping by a user; a raised main bead having a first end located proximate the heel side of the tab and extending around the main tear panel to a second end; a vent including: a vent score defining a vent tear panel and a vent hinge located approximately between opposing ends of the vent score; and an upwardly protruding button located on the vent tear panel; and a raised or recessed vent bead that encircles the vent score and is spaced apart from the main bead; whereby actuation of the tab by lifting the heel is capable of rupturing the main score and actuation of the tab by pressing down on the tab is capable of rupturing the vent score.

26. The beverage can end of claim 25 wherein the vent button is located outboard of the tab while the tab is positioned to actuate the main score and the vent panel bead is located proximate a peripheral edge of the center panel distal from the rivet, whereby the vent is located to enhance venting.

27. The beverage can end of claim 25 wherein the vent score is located on the button or having a distance D3 or D13 from the button sidewall, measured at a point at which the vent score is closest to the button sidewall, of no more than 0.020 inches such that downward force transmitted from the tab heel to the button ruptures the vent score, whereby actuation of the tab by lifting the heel is capable of rupturing the main score and actuation of the tab by pressing down on the tab is capable of rupturing the vent score.

28. The beverage can end of claim 27 wherein the distance D3 or D13 is between 0.000 inches and 0.006 inches.

29. The beverage can end of claim 27 wherein the vent hinge is oriented such that the score rupture propagates about the vent tear panel in two directions to the vent hinge.

30. The beverage can end of claim 27 wherein the vent hinge is opposite the rivet.

31. The beverage can end of claim 27 wherein the tab has a contact element that is configured to contact the button and wherein the tab contact element is a downwardly protruding bead.

32. The beverage can end of claim 25 wherein the vent defines: a dimension X from a button center to lateral ends of the vent score along a vent centerline CL, a dimension Y from the button center to the vent hinge, and a dimension Z from the button center to a proximal point of the vent score that is the point on the vent score that is closest to the button, dimension X is greater than Z and less than 5Z and dimension Y is greater than 0.5Z and less than 3Z.

33. The beverage can end of claim 17 wherein the first end of the main bead is spaced apart from the second end of the main bead.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a top view of a can end according to a first embodiment of the present invention;

(2) FIG. 2 is an underside view of the can end of FIG. 1;

(3) FIG. 3 is a perspective view of the can end of FIG. 1;

(4) FIG. 4 is a top perspective view of the can end of FIG. 1 showing the tab actuated to open the pour opening;

(5) FIG. 5 is an underside perspective view of the can end of FIG. 1 shown the vent opening actuated to its open position and having the main tear panel removed for clarity;

(6) FIG. 6 is a can body and can end combination showing the tab over the vent opening with the vent in its unactuated, unvented state;

(7) FIG. 7 is an enlarged schematic view of a portion of the button on the vent;

(8) FIG. 8 is a perspective view of a tooling insert used to form the vent score portion of the end shown in FIG. 2;

(9) FIG. 9 is an enlarged plan view of a portion of a vent portion of the end shown in FIG. 2;

(10) FIG. 10 is an enlarged plan view of a second embodiment of a portion of a vent portion of an end;

(11) FIG. 11 is an enlarged plan view of a third embodiment of a portion of a vent portion of an end;

(12) FIG. 12 is an enlarged plan view of a fourth embodiment of a portion of a vent portion of an end;

(13) FIG. 13A is an enlarged, cross sectional view of a portion of the tab and vent according to a first embodiment can end with the tab rotated over the vent before downward actuation of the tab;

(14) FIG. 13B is a cross sectional view of the embodiment of FIG. 13A showing the tab deflected downwardly and vent score ruptured;

(15) FIG. 13C is a cross sectional view of the embodiment of FIG. 13A showing the tab in its fully actuated position and the vent tear panel fully open;

(16) FIG. 14A is a top view of an embodiment of a can end having a center panel that includes a bead; and

(17) FIG. 14B is a top view of another embodiment of a can end having a center panel that includes a bead.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

(18) Referring to FIGS. 1 through 6 to illustrate a first embodiment, a beverage can end 10 formed of an aluminum alloy (preferably a 5000 series alloy) has a shell that includes a peripheral curl 12, a wall structure 14, an annular bead 16, and a center panel 18. Can end 10 also includes a vent 40 formed on the center panel and a tab 70 affixed to the shell by a rivet. FIGS. 1 through 5 show can end 10 in its unseamed state. FIG. 6 shows a can end and can body combination holding a carbonated beverage.

(19) Curl 12 is configured to be seamed to a flange of an aluminum can body 8, preferably by a conventional double seam. The can body and can end combination, joined by a double seam, is shown in FIG. 6. Wall structure 14 extends from curl 12 and preferably is of a type found on conventional, lightweight ends. In this regard, wall structure 14 is inclined as shown in the figures, and also may encompass curved portions, kicks, kinks, double angles, and like structure known in the field. Countersink bead 16 is located at the base of wall structure 14. Center panel 18 extends from countersink bead 16. The present invention also encompasses a panel wall or chamfer (not shown in the figures) that merges with inner wall of bead 16 and center panel 18.

(20) Center panel 18 is flat, which encompasses variations from a theoretical plane because of manufacturing tolerances and some inherent deviations from a perfect plane, and also structural features, such as deboss panels and beads described herein and the like. The term flat is used to encompass both the unseamed end and the curvature under normal pressurized conditions from holding a carbonated beverage. A rivet 22 is formed in center panel 18 preferably in the center of center panel 18. A main score 26 is formed in center panel 18 in an oblong shape and preferably defines a main tear panel 28, which forms a pour opening upon rupture of the score. Opposing ends of score 26 form a main hinge 30 about which the tear panel pivots during actuation of tab 70. Main score 26 and tear panel 28 preferably are conventional. For example, the tear panel may have an aspect ratio of between 1.3 and 1.7. As shown in the figures, center panel 18 includes a main deboss panel 34that is, a recess in panel 18. The present invention is not limited to ends having a main deboss panel unless specifically required by the claims. Rather, the present invention encompasses ends that do not have a main deboss panel, which ends may have beads formed on the center panel, as is known in the field.

(21) In a first embodiment, vent 40 includes a vent score 42, a vent hinge 46, a vent anti-fracture score 48, and an upwardly protruding button 50. Preferably, vent 40 is located within a vent recess or deboss panel 62, which is formed in main deboss panel 34. Deboss panel 62 has a diameter that preferably is at least 0.5 inches, preferably less than 0.7 inches, and in the embodiment shown approximately 0.63 inches. Deboss panel 62 may stiffen the region around vent 40 to enhance openability. The depth of vent deboss panel 62 may be chosen with the end goal of panel stiffness and minimum slack metal without putting undue stress on vent score 42. In this regard, the size of the vent panel may be chosen according to parameters that will be understood by persons familiar with end forming technology upon consideration of the present disclosure, taking into account the parameters of vent score dimensions and configuration, button size and configuration, relationship to other recesses or beads, depth of recesses, and the like.

(22) Vent deboss panel 62 preferably is located such that button 50 is not beneath tab 70 or is not beneath a downwardly protruding bead, described below, while the tab is in its as-manufactured or shipping configuration or in the position in which is configured to actuate main score 26. In this regard, button 50, especially the center or a contact portion of button 50, may be outboard of the side of tab 70 such that a downward force on tab 70 does not apply a force on button 50 until a user pivots or rotates tab 70 for the purpose of aligning the tab contact surface with button 50. Further, deboss panel 62 preferably is located distally from main score 26 while still being formed in main recess panel 34 (although it is not required that the deboss panel be located in the main recess panel) such that vent 40 can be located at or near the highest feasible point on the end when the can is tilted into a pouring position or when the can is horizontal and the end is vertical. Accordingly and as shown in FIG. 1, an edge or sidewall of vent deboss 62 may be tangential to or in part coextensive with an edge or sidewall of main deboss panel 34. In this configuration, main recess panel 34 is asymmetrical about its longitudinal centerline, which is unlike conventional Stolle-style recess panels. The longitudinal axis of main recess panel 34 is defined as a line through the rivet, approximately through the center of the tear panel, and through the bottom center of the edge of main recess panel.

(23) FIG. 8 is a tooling insert used to form vent score 42 of vent 40. FIG. 9 is an enlarged view of the structure that partly is formed by the tooling insert of FIG. 8. For convenience of illustration and dimensional precision and accuracy, the description of the tooling insert and the corresponding structure are provided together, and it is understood that description of the tool applies to description of the vent structure formed from the tool. A prime designation (') is used to refer to structure on the tool, as distinguished from corresponding structure in an end, as needed.

(24) As best shown in FIG. 9, vent score 42 includes a longitudinal centerline CL that is parallel to hinge 46. Vent score 42 includes a pair of opposing ends 45a. On each side, score 42 merges from end 45a via a transition 45b to first and second curved portions 45c and 45d, which meet at a side 45e, which preferably is straight. Preferably, the radii of curved transition portions 45c and 45d are approximately 0.083 inches. R1 in FIG. 9 identifies radii 45d.

(25) Button 50 is formed within score 42. For convenience and according to industry custom, dimensions are provided here for the tooling and it is understood that dimensions in the finished end will follow from the tooling dimensions, with some variation for manufacturing deviations, such as spring back or tool wear. For precision in claiming, the dimensions are applied to the end structure and may be measured on the end.

(26) Button 50, as shown schematically in FIG. 7, rises from deboss panel 62 of center panel 18 via a radiused or curved transition 52. If the vent score is formed in the main recess of the center panel or in the unrecessed portion of the center panel, curved transition 52 merges from the main recess or unrecessed portion. Curved transition 52 merges into a button sidewall 54 which extends to yield to a button top 56. Curved transition 52 extends between inboard point 53a that merges into sidewall 54 and outboard point 53b that merges with center panel 18 or, more specifically, deboss panel 62. Preferably, curved transition 52 has a radius R2 (FIG. 7) that is between 0.005 inches and 0.020 inches, more preferably between 0.0075 inches and 0.0115 inches, and most preferably approximately 0.0095 inches.

(27) The inventors have found that choosing the distance between the score and the button sidewall 54 is helpful in some embodiments in enabling the vent opening to controllably and repeatably open. The distance can be measured from the outboard point 53b of radius R2 to the inside wall of score 42, as best shown in FIG. 7 by distance D3. The distance D3 is measured at the point at which the vent score is closest to the button sidewall, referred to as proximal point 57, as explained below. FIG. 9 shows button 50 and illustrates dimension D3 that is measured from point 53b at the circumferential position identified by proximal point 57.

(28) Preferably, dimension D3 is between 0.010 inches (that is, negative 0.010 inches) and 0.020 inches. The negative range means that the inner wall of vent score 42 can be located on or in button curved transition 52 or button sidewallthat is, on the inboard side (that is, to the right as oriented in FIG. 7) of outboard point 53b. Because the range of D3 encompasses zero, the inner wall of vent score 42 may be on the point 53b at which curved transition 52 ends or merges on to center panel 18. And the dimension encompasses a vent score that is located up to 0.020 inches away from the point 53b (that is, outwardly from the button). More preferably, dimension D3 is between 0.006 inches and 0.015 inches, more preferably between 0.003 inches and 0.013 inches, and most preferably between 0.001 or 0.000 inches and 0.006 inches. Measured through the same line as D3, the distance from the centerline of the button to inboard edge of score 42 is between 0.005 and 0.040 inches plus one-half D1, which represents radius R2 plus dimension D3 plus the button radius. For a button diameter of 0.130 inches, the dimension from the centerline of the button to the inboard edge of score 42 is thus between 0.060 and 0.105 inches.

(29) Button 50 preferably has a diameter of between 0.100 inches and 0.180 inches, more preferably, between approximately 0.115 inches and 0.15 inches, and most preferably approximately 0.130 inches. The diameter of button 50 is represented as D1 on FIGS. 7 and 9. For ease of measurement, D1 (and D13 below) is measured on the button 50 at point 53a and the point opposite 53a. Conceptually, curved transition 52 can be considered to be part of button 50 even though curved transition 52 is excluded from the measurement of D1 in the embodiments shown. Button 50 as shown in the figures is circular in top view, but the present invention is not limited to circular buttons. Button 50 is illustrated in the figures having a straight sidewall 54, and the present invention encompasses curved sidewalls and tops and a combination of curves and straight portions forming the button sidewall 54 and button top 56. Thus, the present invention encompasses forming the vent score anywhere on the button sidewall. Use of the term button sidewall is intended to cover the entire surface of the button.

(30) A proximal point 57 is defined as the point on score 42 that is closest to button sidewall 54specifically, closest to outboard radius point 53b of the button. To enhance the effectiveness of the transfer of force through button 50 to score 42, in the embodiment shown in FIG. 9, proximal point 57 is located on the side of the button opposite the vent hinge 46. Further, vent hinge 46 preferably is opposite the rivet 22 relative to the button 50, as shown in FIG. 2. The present invention also encompasses the vent hinge proximate the rivet 22 rather than opposite it, as well as other locations.

(31) Dimension X is the distance from the button center to the lateral ends of score 42 along longitudinal centerline CL. Dimension Y is the distance from the button center to the vent hinge 46. Dimension Z is the distance from the button center to the proximal point of score 42 opposite hinge 46 (that is, to proximal point 57). Alternatively, dimension Z can be defined as parallel and opposite to dimension Y (as for example in the embodiment shown in FIG. 9). For the particular dimensions below, the diameter D1 of button 50 is 0.130 inches, even though D1 and the dimensions for X, Y, and Z dimensions may vary according to particular design parameters. The inventors surmise that various configurations of vent scores would achieve reliable opening characteristics. In this regard, preferably, dimension X is greater than Z and less than 5Z. Preferably dimension Y is greater than 0.5Z and less than 3Z. More preferably, dimension X is greater than 1.2Z and less than 3Z, and dimension Y is greater than 0.75Z and less than 2Z, and more preferably dimension Y is greater than 0.9Z and less than 1.5Z. The Z dimension preferably is between 0.0625 and 0.090 inches, and more preferably between 0.065 and 0.085 inches, and more preferably between 0.068 and 0.078 inches. In the embodiment shown in FIG. 2, X is approximately 0.150 inches and Z is approximately 0.83 inches and Y is approximately 0.117 inches, each with button 50 described herein. It is clear that the present invention encompasses vent configuration that are symmetrical and ones that are asymmetrical.

(32) The present invention encompasses a vent score having other dimensions. For example, the vent score and button 50 may be configured such that X dimension is approximately 0.150 inches, Y dimension is approximately 0.082 inches, Z dimension is approximately 0.067 inches, and button diameter D1 is approximately 0.130 inches, which configuration is illustrated in FIG. 10. For another example, the vent score and button 50 may be configured such that X dimension is approximately 0.183 inches, Y dimension is approximately 0.108 inches, Z dimension is approximately 0.083 inches, and button diameter D1 is approximately 0.130 inches, which configuration is illustrated in FIG. 11. In the embodiment of FIG. 11, the width of vent score 42 is large relative to the width of deboss panel 62 such that a portion of antifracture score 48 is omitted. A circular vent score (not shown in the figures) with a button as describe herein is also contemplated, which circular vent score has an X dimension of approximately 0.083 inches, a Y dimension of approximately 0.133 inches, a Z dimension of approximately 0.083 inches, and a button dimension of approximately 0.130 inches.

(33) Tab 70 is an elongate, stay-on-tab that includes a nose 72, an elongate body 74, and a heel 76. A rivet island 78 extends below the main portion of body 74 and is flat against center panel. Preferably, opposing sides of body 74 are parallel or approximately parallel. Rivet 22 extends through a hole in rivet island 78 to affix the tab and shell together. As is conventional, tab 70 includes a hinge 80 about which the tab pivots during conventional actuation to form the main opening.

(34) A bead 82 is formed in tab body 74 near heel 76, as directly shown in FIG. 4 and shown in the negative in other figures. Bead 82 extends downwardly relative to the surrounding portion of body 74 and preferably is elongate. Bead 82 may be curved or straight in plan view. Preferably, bead 82 is sized and positioned such that at least a portion of bead 82 and preferably the entire extent of bead 82 is capable of entering into the opened vent 40 when actuating vent tear panel 44, as best shown in FIG. 13C. The present invention encompasses configurations of the center panel, tab, and vent in which a tab bead or tab structure do not enter into the opened vent.

(35) FIG. 12 illustrates a second embodiment of a vent, designated as vent 140 for a second embodiment end 110. The shell, tab, and recesses of end 110 preferably have identical structure for first embodiment end 10 but for the vent. Vent 140 includes a vent score 142, a vent tear panel 144, a vent hinge 146, a vent anti-fracture score 148, and a button 150. Preferably, vent 140 is located within a recess or deboss panel 62, which is formed in main deboss panel 34, which structure is described above.

(36) Vent score 142 includes a longitudinal centerline CL that is perpendicular to hinge 146. Vent score 142 includes an end 145a, which is distal to hinge 146. On each side, score 142 extends from end 145a via straight sides 145b toward hinge 146. Dimensions for score 142 preferably are X of approximately 0.143 inches, Y of approximately 0.101 inches, and Z of approximately 0.083 inches. Dimension Z preferably is between 0.2X and 1X, and most preferably between 0.33X and 0.83X. Dimension Z preferably is between 0.5Y and 1.33Y, and most preferably between 0.67Y and 1.1Y

(37) Button 150 preferably has the same structure as that described for button 50 of the first embodiment vent, including a diameter of approximately 0.130 inches. Preferably button 150 is located closer to hinge 146 than to score end 145a and in this regard is off center. A proximal point 157 is defined as the point on the score 142 that is closest to button 150 and defines a distance therebetween as D13. Because of the configuration of score 142, the second embodiment vent has a pair of proximal points 157 on opposing sides of button 150.

(38) Preferably, dimension D13 is between 0.010 inches (that is, negative 0.010 inches) and 0.020 inches. More preferably, dimension D13 is between 0.006 inches and 0.015 inches, more preferably 0.003 inches and 0.013 inches, and most preferably between 0.001 or 0.000 inches and 0.006 inches. As shown in FIG. 12, D13 is measured from a point labeled 153b which corresponds defined like point 53b in FIG. 7.

(39) In its rest, as-manufactured state, button 50 (and 150) lie outside of the tab 70that is, a vertical projection of the sides of tab body 74 does not significantly encompass any part of button 50, 150. Accordingly, if tab 70 is depressed while tab 70 is in its rest state, the tab does not depress button 50, thereby preventing inadvertent rupture of vent score 42 during handing and shipping of the unseamed ends and of the filled and seamed can.

(40) FIGS. 14A and 14B illustrate beverage can ends that use raised or recessed beads. The shell structure, main score, vent score, tab, and rivet in the embodiments shown in FIGS. 14A and 14B are as described above with respect to the embodiments shown in FIGS. 1 through 12. First beaded end 210a includes a curl 212, wall structure 214, and annular bead 216 that are as described with respect to first embodiment end 10. Center panel 218a of end 210a includes a vent 240. A tab 270 affixed to the shell by a rivet 222.

(41) A main score 226 is the same as described with respect to first embodiment main score 26. A centerline CL is defined through the rivet 222 and through a centerline of tab 270 or, if tab 270 is not in a conventional position ready to actuate to open the tear panel, centerline CL bisects the pour opening area formed by main score 226. A transverse centerline TL is normal to the main centerline CL and through rivet 222.

(42) A main raised bead 288a includes a first, outwardly flared end 289 that is located to the rear of the transverse centerline TL, and preferably on the hinge side of the main centerline CL and on opposite side of line CL from vent 240b. From end 289b, bead 288a curves inwardly toward main centerline CL and then outwardly relative to line CL, after which bead 288 follows the contours of main score 226 (that is, for most of main score 226, bead 288a is equidistantly spaced apart from score 226).

(43) Bead 288a continues to curve around main score 226 to terminate in second end 290, which is forward (below in the orientation of FIG. 14A) and spaced apart from vent 240. Second end 290 includes an outward (that is, relative to centerline CL) flare above an inward curve. Bead 288a is asymmetrical relative to main centerline CL, because in the embodiment shown in the FIG. 14A, second end 290 is forward (that is, below in the orientation of FIGS. 14A) first end 289.

(44) A vent bead 299, which may either be a raised bead or a recessed bead, and preferably is circular, encircles a vent score 242. The shape, orientation, and location of the vent score and the layout of the corresponding button may be as described in any of the embodiments described for the other embodiments disclosed herein.

(45) A second embodiment beaded end 210b includes a curl 212, wall structure 214, and annular bead 216 that are as described with respect to first embodiment end 10. Center panel 218b of end 210b includes a vent 240b. A tab 270 affixed to the shell by a rivet 222.

(46) A main score 226 is the same as described with respect to first embodiment main score 26. A centerline CL is defined through the rivet and through a centerline of tab 270 or, if tab 270 is not in a conventional position ready to actuate to open the tear panel, centerline CL bisects the pour opening area formed by main score 226. A transverse centerline TL is normal to the main centerline CL and through rivet 222.

(47) A main raised bead 288b includes a first, outwardly flared end 289 that is located to the rear of the transverse centerline TL, and preferably on the hinge side of the main centerline CL and on opposite side of line CL from vent 240b. From end 289, bead 288b curves inwardly toward main centerline CL and then outwardly relative to line CL, after which bead 288b follows the contours of main score 226 (that is, for most of main score 226, bead 288b is equidistantly spaced apart from main score 226).

(48) Bead 288b curves around main score 226 and continues to curve inwardly to form a waist 291, which is forward (below in the orientation of FIG. 14A) and spaced apart from vent 240b. Bead 288b then extends outwardly toward vent score 242 and forms a hook-like, curved portion 292 that extends rearward of vent score 242. Preferably, as shown in the FIG. 14B, curved portion 292 extends to the inboard side (that is, between vent score 242 and main centerline CL) and forward to terminate in second bead end 293.

(49) Bead 288b may be a raised bead throughout its extent from first end 289 through second end 293. Alternatively, bead 288b can transition from a raised bead that extends around main score 226 to a recessed bead roughly at a transition, indicated in FIG. 14B by reference numeral 301 near waist 291. The vent score shape, orientation, and location and the layout of the corresponding button may be as described in any of the other embodiments described herein.

(50) Beads 288a and 288b preferably are symmetrical or approximately symmetrical in transverse cross section and may be formed in a conventional configuration by conventional methods, as will be understood by persons familiar with end technology. The specific dimensions and layouts of beads 288a and 288b and vent score 242 may be chosen according to achieve desired tension across vent score 242 to enhance pressure performance and opening performance.

(51) To open the beverage container, a user grasps and lifts up heel 76 with a finger. In response to lifting heel 76, tab 70 deforms about hinge 80 (best shown in FIG. 4) such that tab nose 72 contacts main tear panel 28. The user continues to lift heel 76 until main score 26 ruptures to form the main pour opening. Preferably, the process for opening the main pour opening is conventional.

(52) A user then pushes heel 76 down such that tab 70 is near its original position. Tab 70 may then be pivoted about rivet 22 until tab bead 82 is aligned with vent button 50, as shown in FIG. 6. Preferably, bead 82 contacts button 50 at a location that is offset from a center of the button in a direction toward proximal point 57 (in the first embodiment), which in turn preferably is positioned on the opposing side of button 50 from vent hinge 46.

(53) As illustrated in FIG. 13A, bead 82 contacts button 50 first at a point A that is oriented relative to proximal point 57 as described above. As downward force is applied by the user by pushing downwardly on tab 70, vent score 42 ruptures initially, as shown in FIG. 13B near point 57. The orientation of proximal point 57 (for the first embodiment) and initial contact point A, and the geometry of button 50 and vent score 42, promote efficient and reliable opening. The elongated shape of vent tear panel 44 provides enhanced venting area (that is, the area of opening between the lip of vent tear panel 44 relative to deboss panel 62 that is not deflected upon rupture of vent score 42) compared with a circular score shape. After initial rupture, vent tear panel 44 pivots about hinge 46 such that subsequent downward movement of bead 82 changes the contact point from initial point A rearward (as oriented along the tab centerline) to contact point B and eventually more rearward to contact point C, which is shown in FIG. 13C. In other, the point of contact between the tab and button moves rearward as the present embodiment of the vent is actuated. The rolling or sliding of contact points A through C toward the vent hinge during the opening process enhances the angular deflection of vent tear panel 44, which is beneficial to the opening area. In embodiments in which bead 82 is sized to enter into the vent opening, the magnitude of the vent opening (as manifested by greater angular deflection about the hinge enabled by the bead entering into the opening) is enhanced for better venting performance.

(54) After rupture of vent score 42 near proximal point 57, the rupture propagates in two directions about button 50 until reaching the opposing ends of vent score 42 as vent tear panel 44 is downwardly deflected.

(55) In second embodiment vent 140, contact point A is not in line with the proximal point 157, but rather is at 90 degrees from it about the button circumference. After initial rupture, contact points A through C (not shown in the figures) more, by rolling or sliding, rearward (away from the rivet) or toward the vent hinge as generally described above. Vent score 142 likely first ruptures near one of the proximal points 157. The rupture propagates in two directions until reaching the opposing ends of vent score 142 as vent tear panel 144 is downwardly deflected. Alternatively, if enough energy builds up in vent tear panel 144 before initial rupture, score 142 may rupture initially at points that are 90 degrees from proximal points 157 or at several places simultaneously or virtually simultaneously.

(56) The term between in the claims includes limits of the range. For example, if the claim recites between dimensions A and B, the claim encompasses the dimension being exactly A and exactly B, as well as equivalents and approximations.

(57) Several features of a beverage can end and combination of can end and can body have been described. The present invention is not limited to any combination of the features described herein. Rather, the claims should be interpreted according to their full appropriate scope. The explanation of features relies on a person familiar with aluminum beverage can technology for understanding, such as technology for forming and seaming ends, forming recess, beads, and scores in ends, and the like.