The present invention relates to a manufacturing method and apparatus for forming metallic can ends, and more particularly to a method and apparatus for forming can ends with little or no stretching, and with minimal thinning of material during formation of the can end.
Metallic beverage can ends are designed to have one or more stiffening beads extending around the can end adjacent the circumference or periphery of the can end. These beads are typically defined by interconnected bead radii and bead valley radii alternating with one another in a radial direction of the can end. The beads are formed inward from a countersink radius, or chuckwall radius, and can be located outward from a central panel portion of the can end.
Beverage can bodies and can ends must be sufficiently strong to withstand high internal pressures and also external forces resulting from shipment and handling. Additionally, they must be manufactured from extremely thin and durable materials to reduce costs of manufacturing and weight of the finished products. These seemingly incompatible requirements of high strength and light weight can be accomplished by aggressively working the thin materials using interacting male and female tool combinations. Unfortunately, aggressive material working can lead to inconsistencies within a given contour or geometry of can ends due to excessive stretching or thinning of material from which the can ends are made. Such inconsistencies resulting during formation may diminish strength and alter other characteristics of the can ends.
In the present application, techniques for controlling stretching and thinning in formed portions of can ends are illustrated in methods and apparatus for forming can ends from thin stock that exhibit required strength and possess improved consistency.
In accordance with an aspect of the invention, a method for forming a can end in a forming press is provided. The method comprises positioning a sheet of material between an upper punch assembly and a fixed base assembly in the forming press; cutting a can end blank from the sheet of material; clamping a peripheral portion of the can end blank; moving the upper punch assembly from a retracted position toward an extended position, and clamping a central portion of the can end blank between an upper panel punch and a lower panel punch to define a central panel section on the can end blank, wherein the central panel section is below an annular inner bead die located adjacent to the lower panel punch on the fixed base assembly; and extending the upper punch assembly subsequent to clamping the central portion of the can end blank to form an initial annular countersink radius next to the peripheral portion of the can end blank, with a substantially undeformed intermediate area extending between the initial annular countersink radius and the annular inner bead die.
The upper punch assembly may be extended to engage an annular first intermediate bead punch against the can end blank and a first intermediate bead valley radius may be initially formed in the intermediate area of the can end blank, and the depth of the countersink radius may be simultaneously increased.
The upper punch assembly may be further extended to engage an annular second intermediate bead punch against the can end blank and initially form a second intermediate bead valley radius in the intermediate area of the can end blank, wherein the depth of the first intermediate bead valley radius and the countersink radius may be simultaneously increased.
Forming the initial annular countersink radius may comprise engaging the can end blank with an outer bead punch on the upper punch assembly after an initial engagement of the upper panel punch against the can end blank.
Initial formation of the annular countersink radius may include upward displacement of the upper panel punch relative to the outer bead punch while the upper panel punch clamps the central panel section to the lower panel punch.
The peripheral portion of the can end blank may be clamped on a crown ring of the fixed base assembly, and the outer bead punch may cooperate with an inner wall of the crown ring to form a generally vertical outer wall of the countersink radius.
The upper punch assembly may include an annular outer bead punch, an annular middle bead punch, and an annular inner bead punch, and the fixed base assembly may include an annular outer bead die, an annular middle bead die, and the annular inner bead die, and wherein, subsequent to an initial engagement of the outer bead punch on the can end blank: the undeformed intermediate area of the can end blank may extend in engagement with the outer bead die, the middle bead die and the inner bead die; and the middle bead punch and the inner bead punch may be located spaced from the can end blank.
The middle bead punch may engage the can end blank prior to an engagement of the inner bead punch on the can end blank.
The outer bead punch and the inner bead punch may extend downward farther than the middle bead punch.
Movement of the upper punch assembly to its extended position may complete formation of the can end blank into a can end having a countersink radius, a middle bead valley radius, and an inner bead valley radius, wherein the central panel section may remain clamped between the upper panel punch and the lower panel punch during the entire formation of the beads.
In accordance with another aspect of the invention, a method for forming a can end in a forming press is provided. The method comprises positioning a sheet of material between an upper punch assembly and a fixed base assembly in the forming press; cutting a can end blank from the sheet of material; clamping a peripheral portion of the can end blank between a crown ring and a knockout ring; providing an upper punch assembly having a plurality annular bead punches and an upper panel punch supported for movement relative to the bead punches; providing a fixed base assembly having a plurality of annular bead dies for cooperating with the bead punches and a lower panel punch; moving the upper punch assembly from a retracted position toward an extended position. In addition, movement of the upper punch assembly comprises: engaging a central portion of the can end blank with the upper panel punch prior to engagement of the can end blank with the bead punches or the bead dies; and subsequently moving the upper punch assembly to clamp the central portion of the can end blank between the upper panel punch and the lower panel punch with the can end blank engaged with a single one of the bead punches and a single one of the bead dies.
The upper punch assembly may be extended subsequent to clamping the central portion of the can end such that the single one of the bead punches moves the can end blank down into engagement with one or more of the remaining bead dies.
Subsequent to the can end blank moving into engagement with the one or more of the remaining bead dies, further movement of the upper punch assembly may move the remaining bead punches into engagement with the can end blank.
The single one of the bead punches may comprise a radially outermost bead punch and the single one of the bead dies may comprise a radially innermost bead die.
A substantially undeformed intermediate area may extend between the outermost bead punch and the innermost bead die.
The lower panel punch may be immovably fixed relative to the bead dies.
In accordance with a further aspect of the invention, an apparatus is provided for forming a can end from a sheet of material in a single acting press having a fixed base assembly and a movable upper punch assembly. The apparatus comprises a crown ring rigidly supported on the fixed base assembly and having an upper surface defining a contour for a crown of the can end. A knockout ring is carried by the upper punch assembly, the knockout ring being aligned with the crown ring for engaging a workpiece upon movement of the upper punch assembly toward the fixed base assembly to form a crown in a peripheral portion of the workpiece. A plurality of annular bead punches are supported on the upper punch assembly and an upper panel punch is fluidly supported on the upper punch assembly for movement relative to the bead punches. A plurality of annular bead dies and a lower panel punch are supported on the fixed base assembly for cooperating with the bead punches and the upper panel punch, respectively. Movement of the upper punch assembly from a retracted position toward an extended position engages the workpiece between the crown ring and the knockout ring, and positions the upper panel punch in engagement with the workpiece prior to engagement of the workpiece with the bead punches or the bead dies. Subsequent movement of the upper punch assembly clamps the workpiece between the upper panel punch and the lower panel punch with the workpiece engaged with a single one of the bead punches and a single one of the bead dies.
The upper panel punch may displace into the upper punch assembly during movement of the punch assembly toward the extended position subsequent to clamping the workpiece between the upper panel punch and the lower panel punch.
The plurality of bead punches on the upper punch assembly may be supported in fixed relation to each other and the upper panel punch may be movable relative to the plurality of bead punches.
While the specification concludes with claims particularly pointing out and distinctly claiming the present invention, it is believed that the present invention will be better understood from the following description in conjunction with the accompanying Drawing Figures, in which like reference numerals identify like elements, and wherein:
In the following detailed description of the preferred embodiment, reference is made to the accompanying drawings that form a part hereof, and in which is shown by way of illustration, and not by way of limitation, a specific preferred embodiment in which the invention may be practiced. It is to be understood that other embodiments may be utilized and that changes may be made without departing from the spirit and scope of the present invention.
The present application discloses methods and apparatus for forming panels, shells, or can ends so that formed portions of the can ends have controlled thinning to substantially prevent warping, twisting and/or fractures that may occur if thinning is uncontrolled. In accordance with an aspect of the disclosed methods and apparatus, the formed portions of the can ends can be produced with no stretching, or negligible stretching, of the material during the forming process.
Reference is now made to
A bead punch assembly 112 is secured in fixed relation to the upper die shoe 108 and includes an annular outer bead punch 112a, an annular middle bead punch (first intermediate bead punch) 112b, and an annular inner bead punch (second intermediate bead punch) 112c. Punch bead spacers 115 may be provided to enable positioning of the middle bead punch 112b and inner bead punch 112c relative to each other and relative to the outer bead punch 112a. Further, an additional bead punch spacer 117 may be provided above the outer bead punch 112a to enable positioning the outer, middle, and inner bead punches 112a, 112b, 112c relative to the upper die shoe 108. Alternatively, the bead punch assembly 112 may comprise the outer bead punch 112a, middle bead punch 112b, and inner bead punch 112c formed integrally, i.e., as a single unit, with the positions of the bead punches 112a, 112b, 112c fixed relative to each other.
The upper punch assembly 102 further includes an upper panel punch 114 that is secured to the punch piston 106 and supported for movement relative to the bead punch assembly 112. One or more spacers 119 may be provided between the punch piston 106 and the upper panel punch 114 to adjust the vertical position of the upper panel punch 114 within the upper die shoe 108. In the illustrated configuration, two spacers 119 of different diameter are illustrated wherein the thickness of one or both of the spacers 119 may be ground to adjust the vertical position of the upper panel punch 114. In an alternative configuration, a single spacer having a stepped diameter could be provided in place of the two spacers 119 illustrated herein. In the illustrated embodiment, the inner bead punch 112c may be located at the same height or slightly above the outer bead punch 112a, and the middle bead punch 112b may be located at a height above both the outer and inner bead punches 112a, 112c, see
The lower fixed base assembly 104 includes a lower bead die assembly 116 for cooperating with the bead punch assembly 112 during a forming process performed on a workpiece or blank 130 which is cut from a sheet of material in the forming press. The bead die assembly 116 comprises an annular outer bead die 116a, an annular middle bead die 116b, and an annular inner bead die 116c. Additionally, the lower bead die assembly 116 includes a lower panel punch 118 for cooperating with the upper panel punch 114.
Die spacers 120 can be provided to position the middle bead die 116b and inner bead die 116c relative to each other and relative to the outer bead die 116a, and a lower panel punch spacer 122 can be provided to position the lower panel punch relative to the inner bead die 116c. Alternatively, the lower bead die assembly 116 may comprise the outer bead die 116a, middle bead die 116b, inner bead die 112c, and lower panel punch 118 formed integrally, i.e., as a single unit, with the positions of the bead dies 116a, 116b, 116c fixed relative to each other and fixed relative to the lower die assembly 116.
As seen in
As shown in
Referring to
Further downward movement of the draw punch 124 with the upper punch assembly 102, following clamping at the crown clamping area 134A, moves the outer clamping area 128A down below the crown clamping area 134A, such that the peripheral portion 130A is extracted from the outer clamping area 128A.
At substantially the same time or after the peripheral portion 130A is released from the outer clamping area 128A, the upper panel punch 114 can engage against the center panel portion 130. The crown ring 134 is rigidly supported in the lower fixed base assembly 104 and the knockout ring 132 is spring biased downwardly in the upper punch assembly 102. Hence, the knockout ring 132 can retract into the upper punch assembly 102 following clamping of the crown portion 130B in the crown clamping area 134A and as the upper punch assembly 102 continues to move toward the fixed base assembly 104. Further continued downward movement of the upper punch assembly 102 engages the upper panel punch 114 against a center panel section 131 of the blank 130 to the position shown in
It may be noted that an air pressure is applied to a chamber 107 above the punch piston 106, see
Referring to
Additionally, as a lower surface of the upper panel punch 114 moves below the inner bead die 116c, a portion of the blank 130 adjacent to the center panel portion 130C is positioned in engagement over the inner bead die 116c. At this stage of the can end formation, an intermediate area 130D of the blank 130 spanning between the upper bead punch 112a and the inner bead die 116c comprises a substantially undeformed portion of the blank 130 that is out of engagement with the middle and inner bead punches 112b, 112c and out of engagement with the outer and middle bead dies 116a, 116b. In the illustrated exemplary embodiment, the upper punch assembly 102 may move downward about 0.067 in. (0.170 cm) between the position shown in
Referring to
Referring to
Referring to
Referring to
Referring to
The forming stage illustrated in
It should be understood that although the steps for forming a can end include initiating formation of the middle bead valley radius V2 as a first intermediate bead valley radius following the step of initiating formation of the countersink radius additional aspects of the invention may include a different order of bead valley radius formation. For example, the bead punch assembly 112 and bead die assembly 116 may be configured to initiate formation of the inner bead valley radius V3 as the first intermediate bead valley radius followed by initiating formation of the middle bead valley radius V2 as the second intermediate bead valley radius.
From the above description, it may be understood that the can end is formed with successive formation of valley radii wherein initial formation of the valley radii may be staged to occur at different times in the forming process. In particular, formation of the countersink radius may be initiated first and successive intermediate valley radii may be formed sequentially which, in combination with only providing the upper forming tooling “on air” while the bottom tooling is “on solid” or fixed, results in a reduction in press tonnage required for formation of the can end.
In forming the can end, a bending of the material forming the blank 130 can be performed gradually wherein bending of the material can be accommodated by either pulling additional material from the outer portion 130A of the blank 130 or by a localized thinning of material at the bead radii or valley radii. Performing the forming operation as a sequential draping of the material over the tooling of the bead punch assembly 112 and bead die assembly 116, as is illustrated in
While particular embodiments of the present invention have been illustrated and described, it would be obvious to those skilled in the art that various other changes and modifications can be made without departing from the spirit and scope of the invention. It is therefore intended to cover in the appended claims all such changes and modifications that are within the scope of this invention.