Patent Grant
10286437
Many food can bodies and nearly all beverage can bodies are formed in a drawing and ironing (“D&I”) process, also known as a drawing wall ironing (“DWI”) process. DWI beverage cans are typically formed from a 3000 series aluminum alloy.
Conventional DWI aluminum beverage cans are often formed by first drawing a flat, circular blank into a cup in a dedicated machine known as a cupper. The cup then is inserted into another machine known as a bodymaker where the cup undergoes a redrawing process before wall ironing.
In a conventional redrawing process in a bodymaker, the cup is reduced in diameter and increased in length. The redrawn cup typically includes a flat bottom, a short angled wall that extends from the flat bottom, and a cylindrical sidewall that extends an end of the short angled wall, as shown in prior art
Conventional redraw tooling includes a punch assembly 110 that includes a center punch tool 112 and an annular punch sleeve 114 that pushes the cup through a die (not shown in the
Punch tool 112 has a nose 120 that contacts a bottom of the drawn cup. Nose 120 includes a tip 122 that is the distal-most portion of tool 112. A nose outer surface 124 extends outwardly and rearwardly from tip 122.
Punch sleeve 114 is typically ifs affixed to center punch tool 112 and includes a tapered punch sleeve nose 140 that is rearward (that is, in the direction of relative motion of the tooling assembly 10 during the redrawing operation) of punch tool tip 122 and at least a portion of punch tool nose outer surface 124. A punch sleeve inner cylindrical surface 146 surrounds center punch tool outer cylindrical surface 126
After the redrawing process, the punch assembly 110 pushes the cup through a series of dies (that is, the ironing process) to reduce the thickness of the sidewall. At the end of the ironing process, a doming tool 210 (
Tooling having spring-supported parts is known in the art, which parts tend to perform a function of deforming the workpiece. The inventor however has identified problems that make wrinkling of the redraw chine more likely. First, the trend toward thinner aluminum blanks reduces the inherent ability of the material to resist wrinkling. Second, the trend toward lightweight beverage can ends (that is, the seamed-on component at the end opposite the base) having a smaller center panel diameter has resulted in a change in base configuration.
Redraw tooling for a can bodymaker includes redraw tooling that includes a punch ring, which is positioned between the center punch tool and the punch sleeve. The punch ring contacts the wall of the cup to inhibit or prevent wrinkling that can occur when redrawing the cup using thin metal blanks. The retractable punch ring preferably inhibits wrinkling without significantly deforming the chine wall, such as not leaving a groove or bow in the chine wall. The metal cups are an intermediate structure that is formed into a can body, such as a drawn and ironed beverage can body.
The punch ring is supported by a compliant support, such as a spring plate, or other spring structure, or resilient material, such as an elastomer. The compliant support positions the punch ring to contact the wall, preferably the angled wall, of the metal during redrawing. Later, after the wall ironing process, the compliant support can be deformed (as in spring compression or elastomer compression or in retracting one part relative to another) when the doming tool contacts the metal to form the dome.
Accordingly, a redrawing tooling assembly in a can bodymaker for redrawing a metal cup comprises: a center punch tool, a punch sleeve, a punch sleeve, and a compliant support.
The punch ring is concentric with the center punch tool, outboard of at least a portion of the center punch tool, and inboard of at least a portion of the punch sleeve. The punch ring has a contact surface that is radially located between the punch sleeve forwardmost tip and the punch sleeve contact surface. The punch ring contact surface is adapted to contact the chine wall of the metal cup during the redraw process.
The compliant support is configured to axially position the punch ring contact surface to contact the chine wall of the metal cup during the redrawing process to inhibit metal wrinkling. The compliant support is deformable in response to the punch ring engaging doming tooling in the bodymaker, thereby enabling the punch ring to retract relative to the center punch tool.
Preferably, the compliant support extends circumferentially around a portion of the center punch tool and contacts a base of the punch ring to urge the punch ring forward. The punch ring can include (i) an angled contact surface configured to contact a chine wall of a can and (ii) an inboard shoulder that is urged against an undercut shoulder of the punch tool by the compliant support, and may include a punch ring undercut shoulder. The undercut shoulder is configured to contact a land surface of the punch sleeve in a fully retracted position of the punch ring.
Optionally, the compliant support is retained by a groove in the center punch tool and the compliant support bears on a portion of the center punch tool. The compliant support preferably is a spring plate. The compliant support may also include a resilient elastomer.
The punch tool has a forwardmost annular tip adapted for concentric contact with a base of a metal cup during the redraw process preferably such that the punch ring engages the metal cup after the center punch tool, and the punch sleeve engages the metal cup after the punch ring. The punch sleeve is concentric with the center punch tool and has a contact surface that is axially located rearward of the center punch tool forwardmost tip such that the metal cup has an angled chine wall therebetween during the redrawing process. The punch tool forwardmost tip preferably is forward (that is relative in an axial direction) of the contact surface of the punch ring contact surface such that the punch ring contact surface initially contacts the chine wall at the chine wall angled surface after the chine wall angled surface is formed by the action of the tooling.
According to another aspect of the invention, a method of forming a metal can body includes the steps of redrawing a metal cup, ironing the sidewall, and forming a dome. The redrawing step includes contacting a bottom of the cup with a concentric center punch tool and contacting the chine wall of the metal cup with a punch ring, which has a compliant support, to inhibit wrinkling of the chine wall. This step reduces the diameter of the metal cup and forms an angled chine wall between the bottom of the metal cup and a sidewall of the metal cup. Preferably, the center punch tool contacts the metal cup before the punch ring contacts the metal cup such that the punch ring contacts the angled portion (that is, the angled portion of the chine wall is already from in the base before the punch ring contacts it).
Alternatively, the punch ring may contact the cup base before the punch ring contacts the metal base. In this regard, in the embodiment in which the punch ring contacts the metal cup before the punch tool, the specification uses the phrase “contacts the chine wall” because the punch ring contacts the portion of the base that forms the chine wall. Accordingly, the punch ring may contact the flat chine wall of the cup, as distinguished from the angled chine wall.
The ironing step includes ironing the sidewall by pushing the center punch tool through ironing rings. The doming step includes forming a dome in the bottom of the cup including contacting the bottom of the cup with doming tooling such that the doming tooling compresses the compliant support.
Preferably, the compliant support urges an inboard shoulder of the punch ring into contact with an undercut shoulder of the punch tool until, during the redrawing step until the punch ring retracts relative to the punch tool. Alternatively, the punch ring can be spaced apart from the undercut shoulder of the punch tool. Upon doming, the punch ring can retract until an outboard undercut surface of the punch ring contacts a land surface of the punch sleeve.
Redraw tooling 10 according to an embodiment of the present invention is adapted for use in a can body maker. The bodymaker preferably receives a cup and first performs a redrawing operation using redraw tooling 10. Alternatively, the bodymaker may receive a flat blank and performs a drawing operation using tooling 10.
Tooling assembly 10 is on the distal end of a ram. After the redrawing step, the ram pushes the tooling assembly and cup through a series of dies to iron the cup sidewall, and thus transforms the cup into a can body or container body. When the can body is a beverage can body and when the ram is at the end of its stroke, the can body is pushed into doming tooling to form the dome, standing ring, and chine, as will be understood by persons familiar with method for forming beverage can bodies. The doming process well known in the art.
Tooling assembly 10 includes a center punch tool 12, a punch sleeve 14, a punch ring 16, and a compliant support, such as spring plate 76. Center punch tool 12 has circular, ring-like punch tool nose 20 at its forwardmost or distal most end. Center punch tool 12 has a hollow recess (not shown in the figures) radially inboard of nose 20 to receive doming tooling during the doming operation. The distal end of punch tool nose 20 forms a nose tip 22 about which the standing ring of the beverage can base is formed, a nose outer surface 24 that extends radially outwardly and rearward or proximally from tip 22, a cylindrical center punch tool outer surface or sidewall 26 that extends rearwardly from nose outer surface 24. The diameter of the largest part of outer surface 24 is greater than the diameter of punch tool sidewall 26 such that an undercut shoulder 25 is formed. Punch sleeve 14 preferably is fixed relative to punch 12 such that the sleeve 14 and punch 12 move together in the bodymaker. Punch sleeve 14 includes a distal punch sleeve nose 40, a punch sleeve inner cylindrical surface 42, a distal or forward-facing stop surface or landing or shoulder contact surface 43, a rounded or tapered surface 44, a punch sleeve outer cylindrical surface 46, a recess shoulder surface 47 and a punch sleeve cutout or recess 48. A portion of punch sleeve inner cylindrical surface 42 is in contact with or corresponds to a portion center punch outer surface 26. Sleeve inner surface 46 also includes a forward-facing shoulder 49 on which a proximal end of center punch 12 is located.
Punch sleeve outer cylindrical surface 46 extends distally (forwardly) to yield to angled or tapered surface 44 that extends to punch sleeve nose 40. Forward-facing landing 43 as shown in the figures is flat and extends radially inwardly and recessed relative to nose 40. The cylindrical or axial part of wall 47 and the radial part of wall 47 form recess or cutout 48, which together with the outer surface 26 of the center punch tool form a recess to house the rear portion of ring 16 and spring plate 76.
Punch ring 16 preferably has an overall ring-like shape and includes a nose 60, an inboard shoulder 61, an inner surface 62, an angled surface 64, an undercut shoulder 65, an outer surface 66, and a rear surface 70. Punch ring inner surface 62 preferably is cylindrical and is in sliding contact with or corresponds to a distal surface of center punch outer surface 26. Punch ring inner surface 62 extends distally to inboard shoulder 61, which may be contact with punch tool shoulder 25, as the compliant support urges punch ring 16 forward. Or punch ring inboard shoulder 61 may be spaced apart from punch tool shoulder 25. Punch 16 extends distally from shoulder 61 to a rounded punch nose 60. Angled surface 64 extends radially outwardly and rearwardly (or proximally) from nose 60 to an undercut and to (preferably) cylindrical punch ring outer surface 66. Angled surface 64 in the embodiment shown in
Compliant support, such a spring plate 76, has a radially inboard portion surface that extends around the circumference of punch tool outer surface 26. Spring plate 76 is wavy around its circumference such that the crests 82 of the upper surface plate 76 contact the base or rear surface 70 of punch ring 16 and the lower surface of the troughs 84 contact the shoulder 47 of punch sleeve recess 48. Crests 82 and troughs 84 retain plate 76 in punch sleeve recess 48.
As explained below, an outboard portion of plate 76 can engage an inner wall of the punch. Spring plate 76 can have inboard and outboard clearance and spring properties according to the particular parameters desired for the application. Because spring plate 76 is compliant, punch ring 16 can be pushed rearwardly by the doming tooling assembly as explained more fully below. The compliant support my be formed in any configuration, and encompasses any compliant material, such as an elastomer or other resilient material.
Referring to
Punch ring nose 60 or angled surface 64 is the second point of contact B with cup 2 during the drawing/redrawing process, as best shown in
Upon the end of the stroke of the ram that pushes body maker tooling 10, doming tool 210 forms a dome on cup bottom 4 and chine tool 212 contacts redraw chine 5. As chine tool 212 deforms redraw chine 5, punch ring 16 is pushed backwards against the force of spring plate 76 until undercut shoulder 65 of punch ring 16 contacts land 43 of punch sleeve 14, as chine 5 is approximately linear between punch sleeve surface 46 or 44 and the curved portion of punch tool 16 where a radial deformation of chine 5 is formed. Thus, punch ring 16 supports the metal of redraw chine 5 to diminish wrinkling during the redrawing operation, and also possibly during the ironing operations, and then punch ring 16 retracts or is displaced by the doming tooling to enable formation of the chine.
Referring to
Punch sleeve 14′ preferably is fixed relative to punch 12′ such that the sleeve 14′ and punch 12′ to the extent that punch 12′ and sleeve 14′ move together in the bodymaker. Punch sleeve 14′ includes a distal punch sleeve nose 40′, a punch sleeve inner cylindrical surface 42′, a punch sleeve outer cylindrical surface 46′, and a punch sleeve cutout 48′. A proximal portion of punch sleeve inner cylindrical surface 42′ is in contact with or corresponds to a portion of center punch outer surface 26′. Sleeve inner surface 46 also includes a forward-facing shoulder on which a proximal end of center punch 12′ is located.
Punch sleeve outer cylindrical surface 46′ extends distally to yield to angled contact surface 44′. A distal portion of punch sleeve 14′ has a greater diameter than that of a proximal portion of punch sleeve 14′ such that a cutout 48′ is formed, which together with the outer surface 26′ of the center punch tool forms a recess 50′ for receiving punch ring 16′.
Punch ring 16′ preferably has an overall ring-like or cylindrical shape and includes a nose 60′, an inner surface 62′, an angled surface 64′, an outer surface 66′, and a recess 68′. Punch ring inner surface 62′ preferably is cylindrical and is in sliding contact with or corresponds to a distal surface of center punch outer surface 26′. Punch ring inner surface 62′ extends distally to rounded punch nose 60′. Angled surface 64 extends radially outwardly and rearwardly from nose 60′ to (preferably) cylindrical punch ring outer surface 66′. Angled surface 64′ in the embodiment shown in the figures is rounded or convex outward (that is, bulging). Punch ring recess 68′ is formed in an radially inboard portion of punch ring inner surface 62′. In its rest state, punch ring recess 68′ has an upper and lower boundary walls that preferably are aligned with the corresponding upper and lower boundary walls of center punch recess 28′. Alternatively, the upper and lower boundary walls of recesses 68′ and 28′ are not aligned, as the recesses 68′ and 28′ overlap and in direct communication when punch ring 60′ is in its rest position.
Compliant support, such a spring plate 76′, has a radially inboard portion 78′ that is located in center punch recess 28′ and a radially outboard portion 80′ that is located in punch ring recess 68′. Spring plate 76′ is wavy around its circumference such that the crests 82′ of the upper surface plate 76′ contact the top boundary wall of recess 28′ and the lower surface of the troughs 84′ contact the lower boundary wall of recess 28′. Crests 82′ and troughs 84′ retain plate 76′ in groove 28′.
As explained below, outboard portion 80′ of plate 76′ engages the punch ring recess 68 such that spring plate 76′ locates punch ring 16′ in a desired position for diminishing wrinkles during the redraw process. Because spring plate 76′ is compliant, punch ring 16′ can be pushed rearwardly by the doming tooling assembly as explained more fully above. The compliant support my be formed in any configuration, and encompasses any compliant material, such as an elastomer or other resilient material. Preferably the complaint support bears on the center punch tool, which preferably encompasses the compliant support contacting or being supported by the center punch tool.
Referring to
Upon the end of the stroke of the ram that pushes body maker tooling 10′, doming tooling forms a dome in the can and urges punch ring 16 rearward, as generally described for first embodiment tooling 10. The doming tool forms a dome on cup bottom and chine tool contacts redraw chine. As the chine tool deforms redraw chine, punch ring 16′ is pushed backwards against the force of spring plate 76′. Thus, punch ring 16′ supports the metal of redraw chine 5′ to diminish wrinkling during the redrawing operation, and also possibly during the ironing operations, and then punch ring 16′ retracts or is displaced by the doming tooling to enable formation of the chine.
The first and second embodiments 10 and 10′ are illustrated with the forwardmost point of the punch tool nose 20 located forward (that is, forward or relatively distal along an axial centerline of the tooling, without regard to radial position) of the forwardmost portion of the punch ring nose 60 such that tooling 10 and 10′ contacts the workpiece in the sequence at point A, then point B, then point C. The present invention is not limited to this configuration of tooling 10 and 10′ nor the order of contact with the workpiece.
Rather, the present invention encompasses a structure in which the forwardmost portion of the punch ring nose is forward of the punch tool nose 20 such that the punch ring contacts the workpiece before punch tool 12 contacts the workpiece. For example, as shown in
Thus, the first portion of the tooling 10a that contacts a metal cup during redrawing is nose 60a of punch ring 16a, which then retracts against spring 76. As will be understood by persons familiar with container tooling technology, spring 76 may be chosen to provide resistance for anti-wrinkling without significant deforming of the chine wall. The dimensions of recess 48 may be chosen to provide sufficient space for punch ring 16a to retract consistent with the structure and function described herein.
The second embodiment tooling 10′ may also accept an alternative punch ring 16a′ that extends forward of the punch tool nose 22′ according to the same principles described above for punch ring 16a. Punch ring 16a′ is illustrated by dashed lines in
The above disclosure describes an embodiment of the invention. The invention is not intended to be limited to the particular structure or function of the components disclosed described herein, but rather it is intended to encompass the full scope recited in any claims.
| Number | Name | Date | Kind |
|---|---|---|---|
| 20150239029 | Yamamoto et al. | Aug 2015 | A1 |
| Number | Date | Country |
|---|---|---|
| H10-0272526 | Oct 1998 | JP |
| WO 9505253 | Feb 1995 | WO |
| Number | Date | Country | |
|---|---|---|---|
| 20170225217 A1 | Aug 2017 | US |
