The present application relates generally to a system and method for manufacturing metal containers, and in particular, to a system and method for controlling the flange projection of the metal containers during the manufacturing of the metal containers.
Container manufacturing (e.g., cans) includes drawing stock using different tools. Stock may include any metal material such as aluminum, steel, and metal alloys. For example, some conventional container manufacturing methods include a draw-redraw (DR) process to produce a can. In this method, a blank and draw punch is first used to create a metal cup by blanking off a portion of stock from a coil and drawing the metal between two pieces of tooling (e.g., the blank and draw punch and a draw-redraw die). The cup forms across the tangent points of the inner radiuses of the blank and draw punch. The draw-redraw die is then used to redraw the cup across the tangent points of the inner radiuses of the draw-redraw die to form a can having a flange. After the flange is formed, portions of the outer circumference of the flange may be trimmed off to produce an even (substantially round) flange edge. Other conventional container manufacturing methods include a drawn and ironed (D&I) process to produce a cup. In this method a blank and draw punch is used to create a metal cup by blanking off a portion of stock from a coil and drawing the metal between two pieces of tooling (e.g., the blank and draw die and a cup punch). The cup forms across the tangent points of the inner radiuses of the blank and draw punch. The cup is discharged from the machine and transferred to downstream equipment. The cup may then be provided to other machinery (e.g., a body maker) which elongates the cup body to produce a can.
In one conventional method, the blank and draw punch and the draw-redraw die are part of a single machine and the cup and can are formed in a single stroke process. In another conventional method, the blank and draw punch and the draw-redraw die are separate and the cup and can are formed separately in a two-step process. Although metal drawing and metal redrawing systems and methods exist, there is a continuing need for different and improved metal drawing and metal redrawing systems and methods.
Embodiments provide a tooling station for forming containers that includes a blank and draw punch configured to blank off a portion of stock from a stock element and draw the portion of stock to form a cup. The blank and draw punch includes a blank and draw punch inner circumferential wall defining a blank and draw punch cavity, a blank and draw punch proximal surface extending substantially perpendicular to the blank and draw punch inner circumferential wall and a blank and draw punch curved edge disposed between the blank and draw punch inner circumferential wall and the blank and draw punch proximal surface. The blank and draw punch curved edge has a radius of curvature that varies along its circumference. The tooling station also includes a draw-redraw die configured to redraw the cup to form a can having a flange. The draw redraw die includes a draw-redraw die inner circumferential wall defining a draw-redraw die cavity, a draw-redraw die proximal surface extending substantially perpendicular to the draw-redraw die inner circumferential wall and a draw-redraw die curved edge disposed between the draw-redraw die inner circumferential wall and the draw-redraw die proximal surface. The draw-redraw die curved edge has a radius of curvature that varies along its circumference.
According to one embodiment, the blank and draw punch is configured to form the cup by drawing the portion of stock across tangent points of the varied radius of curvature of the blank and draw punch curved edge.
According to another embodiment, the draw-redraw die is configured to form the can having the flange by redrawing the formed cup across tangent points of the varied radius of curvature of the draw-redraw die curved edge.
According to an aspect of an embodiment, the varied radius of curvature of the blank and draw punch curved edge is further configured to control a variance of a height of a top edge of the cup and the varied radius of curvature of the draw-redraw die curved edge is further configured to control a variance of a flange width or cup height.
Embodiments provide a blank and draw punch for forming cups that includes a blank and draw punch base; and a blank and draw punch cylindrical portion extending from the blank and draw punch base. The blank and draw punch cylindrical portion includes a blank and draw punch inner circumferential wall defining a blank and draw punch cavity, a blank and draw punch proximal surface extending substantially perpendicular to the blank and draw punch inner circumferential wall and a blank and draw punch curved edge disposed between the blank and draw punch inner circumferential wall and the blank and draw punch proximal surface, the blank and draw punch curved edge having a radius of curvature that varies along its circumference.
According to one embodiment, the blank and draw punch is configured to form a cup by drawing the portion of stock across tangent points of the varied radius of curvature of the blank and draw punch curved edge.
According to another embodiment, the varied radius of curvature of the blank and draw punch curved edge is further configured to control a variance of a height of a top edge of the cup.
Embodiments provide a draw-redraw die configured to redraw a cup to form a can. The draw-redraw die includes a draw-redraw die base and a draw-redraw die cylindrical portion extending from the draw-redraw die base. The draw-redraw die cylindrical portion includes a draw-redraw die inner circumferential wall defining a draw-redraw die cavity a draw-redraw die proximal surface extending substantially perpendicular to the draw-redraw die inner circumferential wall and a draw-redraw die curved edge disposed between the draw-redraw die inner circumferential wall and the draw-redraw die proximal surface. The draw-redraw die curved edge has a radius of curvature that varies along its circumference.
According to one embodiment, the draw-redraw die is configured to form the can by redrawing the formed cup across tangent points of the varied radius of curvature of the draw-redraw die curved edge.
Embodiments provide a die assembly for forming containers. The die assembly has a plurality of tooling stations. Each tooling station includes (i) a blank and draw punch configured to blank off a portion of stock from a stock element and draw the portion of stock to form a cup; and (ii) a draw-redraw die configured to redraw the cup to form a can having a flange. The blank and draw punch includes a blank and draw punch inner circumferential wall defining a blank and draw punch cavity, a blank and draw punch proximal surface extending substantially perpendicular to the blank and draw punch inner circumferential wall and a blank and draw punch curved edge disposed between the blank and draw punch inner circumferential wall and the blank and draw punch proximal surface, the blank and draw punch curved edge having a radius of curvature that varies along its circumference. The draw-redraw die includes a draw-redraw die inner circumferential wall defining a draw-redraw die cavity, a draw-redraw die proximal surface extending substantially perpendicular to the draw-redraw die inner circumferential wall and a draw-redraw die curved edge disposed between the draw redraw die inner circumferential wall and the draw-redraw die proximal surface. The draw-redraw die curved edge has a radius of curvature that varies along its circumference.
Embodiments provide a method of forming containers that includes receiving a stock element at a tooling station having a blank and draw punch comprising a blank and draw punch curved edge disposed between a blank and draw punch inner circumferential wall and a blank and draw punch proximal surface. The blank and draw punch curved edge has a radius of curvature that varies along its circumference. The method also includes blanking off a portion of stock from the stock element using the blank and draw punch and forming, via the blank and draw punch, a cup from the portion of stock by drawing the portion of stock across tangent points of the varied radius of curvature of the blank and draw punch curved edge.
According to one embodiment, forming the cup from the portion of stock further includes controlling a variance of a height of a top edge of the cup.
According to another embodiment, the method further includes receiving the cup at another tooling station spaced from the first tooling station, the other tooling station having a draw-redraw die comprising a draw-redraw die curved edge disposed between a draw-redraw die inner circumferential wall and a draw-redraw die proximal surface, the draw-redraw die curved edge having a radius of curvature that varies along its circumference. The method further includes forming, via the draw-redraw die, a can having a flange from the cup by redrawing the formed cup across tangent points of the varied radius of curvature of the draw-redraw die curved edge.
In one embodiment, forming the can having the flange further includes controlling a variance of a flange width around an outer circumference of the flange.
Embodiments provide a method of forming containers that includes receiving a stock element at a tooling station having a blank and draw punch. The blank and draw punch includes a blank and draw punch curved edge disposed between a blank and draw punch inner circumferential wall and a blank and draw punch proximal surface. The blank and draw punch curved edge has a radius of curvature that varies along its circumference. The method also includes blanking off a portion of stock from the stock element using the blank and draw punch and moving, at the tooling station, the blank and draw punch and a draw-redraw die from an open position to a cup forming position. The draw-redraw die has a draw-redraw die curved edge disposed between a draw-redraw die inner circumferential wall and a draw-redraw die proximal surface. The method also includes forming, between the blank and draw punch and the draw-redraw die at the tooling station, a cup from the portion of stock by drawing the portion of stock across tangent points of the varied radius of curvature of the blank and draw punch curved edge. The method further includes moving, at the tooling station, the blank and draw punch and the draw-redraw die to a can forming position and forming, via the draw-redraw die at the tooling station, a can having a flange from the cup by redrawing the formed cup across tangent points of the varied radius of curvature of the draw-redraw die curved edge.
According to one embodiment, forming the can having the flange further includes controlling a variance of a flange width around the outer circumference of the flange.
Embodiments provide a method of forming containers that includes receiving a stock element at a plurality of tooling stations of a die assembly. Each of the plurality of tooling stations having a blank and draw punch includes a blank and draw punch curved edge disposed between a blank and draw punch inner circumferential wall and a blank and draw punch proximal surface. The blank and draw punch curved edge has a radius of curvature that varies along its circumference. The method also includes blanking off a portion of stock from the stock element using the blank and draw punch at each tooling station and moving, at each tooling station, the blank and draw punch and a draw-redraw die from an open position to a cup forming position. Each draw-redraw die has a draw-redraw die curved edge disposed between a draw-redraw die inner circumferential wall and a draw-redraw die proximal surface. The method also includes forming, between the blank and draw punch and the draw-redraw die at each tooling station, a cup from the portion of stock by drawing the portion of stock across tangent points of the varied radius of curvature of the blank and draw punch curved edge. The method further includes moving the blank and draw punch and the draw-redraw die at each tooling station to a can forming position and forming, at each tooling station, a can having a flange from the cup by redrawing the formed cup across tangent points of the varied radius of curvature of the draw-redraw die curved edge.
Embodiments provide a double action tooling station for forming containers that includes an outer slide having a blank and draw punch configured to blank off a portion of stock from a stock element, the blank and draw punch further having a blank and draw punch inner circumferential wall defining a blank and draw punch cavity; a blank and draw punch proximal surface extending substantially perpendicular to the blank and draw punch inner circumferential wall; and a blank and draw punch curved edge disposed between the blank and draw punch inner circumferential wall and the blank and draw punch proximal surface, the blank and draw punch curved edge having a radius of curvature that varies along its circumference. The blank and draw additionally supplies draw pressure to the blank. The double action tooling station also includes an inner slide having a draw punch configured to draw the portion of stock to form a cup, the draw punch further having a punch center have a radius of curvature that varies along its circumference, where the outer slide is configured to move independently of the inner slide.
According to one embodiment the blank and draw punch is configured to form the cup by the inner slide drawing the portion of stock across tangent points of the varied radius of curvature of the blank and draw punch curved edge.
According to one embodiment, the varied radius of curvature of the blank and draw punch curved edge is further configured to control a variance of a height of a top edge of the cup.
Additional features and advantages of this disclosure will be made apparent from the following detailed description of illustrative embodiments that proceeds with reference to the accompanying drawings.
The foregoing and other aspects of the present invention are best understood from the following detailed description when read in connection with the accompanying drawings. For the purpose of illustrating the invention, there is shown in the drawings embodiments that are presently preferred, it being understood, however, that the invention is not limited to the specific instrumentalities disclosed. Included in the drawings are the following Figures:
As described above, a portion of metal is blanked from a coil of stock to be drawn and formed into a cup. In conventional systems and methods, when the cup is formed, the height of the cup wall varies around the circumference of the cup at the cup top. That is, the metal is unevenly distributed at the cup top. For cans produced using the D&I process described above, the higher portions of the cans are subsequently trimmed off after the body maker elongates the cup body to provide the more evenly distributed cup top. The trimmed off portions are essentially wasted portions of materials (e.g., metal) that are not part of the produced can.
For cans produced using the DRD process described above, when the cup is redrawn to form the can, a flange is formed that extends from the can sidewall. The width of the flange from the can sidewall to the edge of the flange varies around the circumference of the flange. That is, the redrawing of the metal causes an earring effect by which portions of the flange are caused to be wider than other portions of the flange. Because it is desirable to have a minimum flange width and an evenly distributed (e.g., substantially round) flange width, a minimum amount of metal is blanked off the coil to provide the minimum flange width. The wider portions are subsequently trimmed off to provide the more evenly distributed flange width. The trimmed off portions are essentially wasted portions of metal that are not part of the produced can.
The minimum amount of metal blanked off the coil may be determined by the overall size of the radius continuously around the inner circumference of the draw punch. In some conventional metal container methods, when more metal is needed for the flange (e.g., the minimum width is not achieved), the overall size of the inner radius of the draw punch is decreased. That is, if the overall size of the inner radius of the draw punch is decreased, the metal is constricted and stretches to provide a taller cup providing more metal on the flange and a larger flange width. If the overall size of the inner radius of the draw punch is increased, the metal is less constricted to provide a shorter cup, thereby providing less metal on the flange and a smaller flange width. Reducing or increasing the overall size of the inner radius of the draw punch does not, however, prevent the uneven distribution of metal to the flange. That is, regardless of the overall size of the inner radius of the draw punch, the width of the flange from the can sidewall to the edge of the flange varies around the circumference of the flange.
The cost to produce each can includes the cost for the amount of metal used to form each can. Accordingly, if the portion of metal used to form the can is decreased, then the cost to produce each can decreases.
Embodiments disclosed herein provide a method and system that includes a blank and draw punch having varied inner radiuses to distribute the metal more evenly at the top of a cup. The varied inner radiuses of the blank and draw punch reduce the amount of metal to be trimmed off the cup top, thereby decreasing the cost of producing the cup.
Embodiments also provide a method and system that includes a draw-redraw die having varied inner radiuses to provide a more evenly distributed flange width. The varied inner radiuses of the draw-redraw die decrease the amount of metal used to form a can while maintaining a desirable minimum flange width around the outer circumference of the flange, thereby decreasing the cost to produce the can.
Embodiments provide a method and system that includes both a blank and draw punch having varied inner radiuses and a draw-redraw die having varied inner radiuses. The varied inner radiuses of the blank and draw punch and the draw-redraw die may each contribute to a more evenly distributed flange width. In some embodiments, the cup and the can may be formed at a single tooling station having both the blank and draw punch and the draw-redraw die. In other embodiments, the cup may be formed at one tooling station having the blank and draw punch and the can may be formed at a separate tooling station having the draw-redraw die.
According to another embodiment, the draw-redraw die can be configured to form a redrawn cup (i.e. no flange) by redrawing the formed cup across tangent points of the varied radius of curvature of the draw-redraw die curved edge.
The blank and draw punch 104 is configured to blank off a portion of stock (e.g., metal) from a stock element 1002 shown at
As shown in
The blank and draw punch 104 also includes an inner circumferential wall 402 defining a blank and draw punch cavity 404 and a blank and draw punch proximal surface 406 extending substantially perpendicular to the blank and draw punch inner circumferential wall 402. The blank and draw punch 104 also includes a blank and draw punch curved edge 506 disposed between the blank and draw punch inner circumferential wall 402 and the blank and draw punch proximal surface 406.
As shown in the cross sectional view at
The values (R1, R2, R3) shown in
Embodiments may include different methods of selecting the radius values (R1, R2, . . . Rn). In one embodiment, one or more cups may be produced using the blank and draw punch 104 having a first curved edge 506. After the one or more cans are produced, the distribution of the metal along a cup top surface 802 (shown in
The draw-redraw die 106 is configured to redraw a cup (e.g., cup formed by blank and draw punch 104) to form a partially completed can (hereinafter can) having a flange. As shown in
The draw-redraw die 106 also includes an inner circumferential wall 412 defining a draw-redraw die cavity 414 and a draw-redraw die proximal surface 416 extending substantially perpendicular to the draw-redraw die inner circumferential wall 412. The draw-redraw die 106 also includes a draw-redraw die curved edge 606 disposed between the draw-redraw die inner circumferential wall 412 and the draw-redraw die proximal surface 416.
As shown in the cross sectional view at
The values (R1 and R2) shown in
Embodiments may include different methods of selecting the radius values (R1, R2, . . . Rn). In one embodiment, one or more cans may be produced using the draw-redraw die 106 having a pre-varied curved edge. After one or more cans (e.g., can 902 having flange 904 shown in
The embodiment in
The die assembly 100 shown in
As shown in
In some embodiments, varying the draw radius of the blank and draw punch curved edges and/or varying the draw radius of the draw-redraw die curved edges produces more cans with the same amount of metal. In other embodiments, varying the draw radius of the blank and draw punch curved edges and/or varying the draw radius of the draw-redraw die curved edges produces the same amount of cans with less metal.
Embodiments provide different methods for forming containers, such as a cup 802 and a can 902. Some embodiments provide a method of forming the cup 802 and the can 902 having a flange 904 in the in the same tooling station 102. This method will now be described with reference to
The method includes receiving stock element 1002 at a tooling station 102 of die assembly 100 when the die assembly 100 is an open position, as shown at
The method also includes forming a cup 802 from the portion of stock between the blank and draw punch 104 and the draw-redraw die 106 at the tooling station 102, as shown in the cup forming position in
The method further includes moving the blank and draw punch and the draw-redraw die from the cup forming position to a can forming position shown at
The method described above includes forming the cup 802 and the can 902 having a flange 904 in the same tooling station 102. Other embodiments provide a method of forming the cup 802 and the can 902 in separate steps and in different tooling stations. Other embodiments provide a method of forming a plurality of cups 802 and cans 902 at a die assembly having multiple tooling stations. In these embodiments, each tooling station may include a blank and draw punch and a draw-redraw die. The cups and cans may be formed simultaneously in the multiple tooling stations.
The double action press 1200 can allow for better control of the drawing process by allowing a user to maintain a more consistent pressure throughout the entire draw process. The more accurate control of the draw pressure at the conclusion of the draw process can prevent pinching of the material while greatly reducing or eliminating stray slivers, as well as reducing haring of the material at the top edge of the container. A double action press system 1200 can allow for less tonnage per slide, while allowing for shorter strokes and faster operating speeds.
The system and processes of the figures are not exclusive. Other systems, processes and menus may be derived in accordance with the principles of embodiments described herein to accomplish the same objectives. It is to be understood that the embodiments and variations shown and described herein are for illustration purposes only. Modifications to the current design may be implemented by those skilled in the art, without departing from the scope of the embodiments. As described herein, the various systems, subsystems, agents, managers and processes can be implemented using hardware components, software components, and/or combinations thereof. No claim element herein is to be construed under the provisions of 35 U.S.C. 112, sixth paragraph, unless the element is expressly recited using the phrase “means for.”
Although the invention has been described with reference to exemplary embodiments, it is not limited thereto. Those skilled in the art will appreciate that numerous changes and modifications may be made to the preferred embodiments of the invention and that such changes and modifications may be made without departing from the true spirit of the invention. It is therefore intended that the appended claims be construed to cover all such equivalent variations as fall within the true spirit and scope of the invention.
This application claims the benefit of U.S. Provisional Application No. 62/078,597, filed on Nov. 12, 2014, which is incorporated herein in its entirety.
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