The present application relates generally to stamping presses and, more particularly, to a double-hit servo press with a movable spacer wedge block for draw-in control.
Conventional sheet metal forming includes presses with drawing devices having an upper tool or die and a lower tool or die. The upper tool is typically installed on a lower surface of a vertically movable press ram, and the lower tool typically includes a stationary bottom drawing punch disposed on a press bed. A metal sheet or blank is fed between the upper and lower tools and the upper tool is brought down onto the lower tool to form a stamped metal sheet. In order to control deformities, the sheet metal is often held in multiple locations during the drawing operation to control the amount of sheet metal drawn into the forming die (i.e., draw-in). However, during the forming process, drawing too much sheet metal into the forming cavity can result in wrinkles or surface distortions of the stamped metal sheet, and drawing too little sheet metal into the forming die cavity can result in tears or cracks in the stamped metal sheet. Moreover, after pressing, some drawn panels spring back to a different shape than intended, commonly referred to as springback. Thus, while many conventional presses work well for their intended purpose, there remains a need for continuous improvement in the relevant art.
In accordance with one example aspect of the disclosure, a method of forming a finished stamped product from a blank in a servo stamping press having an upper die, a lower die, and a blank holder is provided. In one example implementation, the method includes positioning the blank on the blank holder between the upper die and lower die, and inserting a movable wedge block between the blank holder and the upper die to establish a first binder gap. While the movable wedge block is inserted, a first strike of the blank is performed by lowering the upper die a first distance to contact and partially form the blank, wherein the movable wedge block limits movement of the upper die to less than a full movement. After the first strike, the movable wedge block is withdrawn to establish a second binder gap between the blank holder and the upper die that is smaller than the first binder gap. While the movable wedge block is withdrawn, a second strike of the blank is performed by lowering the upper die a second distance greater than the first distance to contact and finally form the blank into the finished stamped product.
In addition to the foregoing, the described method may include one or more of the following: during the second strike, gripping the partially formed blank with a surface texture on at least one of the upper die and the blank holder; forming the surface texture as teeth configured to at least partially penetrate the blank; forming the surface texture as a bead configured to be received in a corresponding trough; and drawing the upper die upwardly between the first strike and the second strike.
In addition to the foregoing, the described method may include one or more of the following: drawing the upper die upward after the second strike and simultaneously re-inserting the movable wedge block between the blank holder and the upper die to re-establish the first binder gap; and wherein a cushion supports the blank holder with a variable cushion force, and further comprising performing a two-stage cushion force operation including in a first stage, providing the cushion with a relatively lower cushion force to create a low draw-in resistance force and allow the blank to have increased draw-in, and in a subsequent second stage, providing the cushion with a relatively higher cushion force to create a post-stretch condition to reduce springback of the blank.
In accordance with another example aspect of the disclosure, a servo stamping press for forming a finished stamped product from a blank is provided. In one example implementation, the servo stamping press includes an upper die for at least partially forming the finished stamped product, a lower die having a stationary punch, and a blank holder configured to provide a support surface for the blank. A movable wedge block is configured to be moved between an inserted position and a withdrawn position, wherein in the inserted position the movable wedge block establishes a first binder gap between the upper die and the lower die configured to limit downward movement of the upper die to less than a full movement. In the withdrawn position, the movable wedge block establishes a second binder gap between the upper die and the lower die. A controller is programmed to move the movable wedge block to the inserted position, while the movable wedge block is in the inserted position, perform a first strike of the blank by lowering the upper die a first distance to contact and partially form the blank, after the first strike, move the movable wedge block to the withdrawn position, and while the movable wedge block is in the withdrawn position, command a second strike of the blank by lowering the upper die a second distance greater than the first distance to contact and finally form the blank into the finished stamped product.
In addition to the foregoing, the described servo stamping press may include one or more of the following: a surface texture on at least one of the upper die and the blank holder to facilitate gripping the partially formed blank during the second strike, wherein the surface texture is formed as teeth configured to penetrate the blank, wherein the controller is further programmed to command drawing the upper die upwardly between the first strike and the second strike; and wherein the controller is further programmed to command drawing the upper die upward after the second strike and simultaneously re-insert the movable wedge block into the inserted position.
In addition to the foregoing, the described servo stamping press may include one or more of the following: a cushion configured to support the blank holder with a variable cushion force, and wherein the controller is further programmed to command performing a two-stage cushion force operation including in a first stage, provide the cushion with a relatively lower cushion force to create a low draw-in resistance force and allow the blank to have increased draw-in, and in a subsequent second stage, provide the cushion with a relatively higher cushion force to create a post-stretch condition to reduce springback.
Further areas of applicability of the teachings of the present application will become apparent from the detailed description, claims and the drawings. It should be understood that the detailed description, including disclosed embodiments and drawings referenced therein, are merely exemplary in nature intended for purposes of illustration only and are not intended to limit the scope of the present application, its application or uses. Thus, variations that do not depart from the gist of the present application are intended to be within the scope of the present application.
The present application is generally directed to systems and methods for controlling draw-in of a sheet metal blank during a stamping process. In one example, a double-hit capacity servo stamping press operates a first hit with a first distance to achieve a partial formation of the blank, followed by a second hit to form a completed stamped metal sheet. During the first hit, a movable wedge block is disposed in the stamping press between the die and the blank holder to control the gap distance of binders during the first hit to thereby ease the draw-in. After the first hit, the movable wedge block is withdrawn a predetermined distance to allow wedge position adjustment and reduction of the gap distance such that during the second hit the blank is held between teeth on the dies to reduce draw-in or even lock the sheet's movement for springback reduction.
Referring to
In the example embodiment, the upper die 22 defines a cavity 24 configured to shape a top surface 62 of the blank 60. A periphery 26 of the upper die 22 at least partially surrounding the cavity 24 includes a surface texture 28 on portions thereof configured to contact, engage, or otherwise grip top surface 62 to facilitate holding the blank 60 during the stamping process, as described herein in more detail.
As shown in the illustrated example, lower die 30 includes stationary punch 32 having a punch surface 34 configured to shape a bottom surface 64 of the blank 60.
In the example embodiment, blank holder 40 includes a support surface 42 defining an opening 44 configured to receive the stationary punch 32 therethrough. The support surface 42 includes a surface texture 46 on portions thereof configured to contact, engage, or otherwise grip the bottom surface 64 of blank 60. Additionally, or alternatively, support surface 42 or upper die periphery 26 may include a bead (not shown) configured to be received in a trough formed in the other of the support surface 42 or upper die periphery 26.
In the example embodiment, movable wedge block 50 generally includes a wedge 52 with a block 54 extending upwardly therefrom. A fixed wedge or actuator 56 (e.g., a motor) is configured to selectively horizontally insert/remove the movable wedge block 50 from in between the upper die 20 and the blank holder 40. When in the inserted position, movable wedge block 50 is configured to establish a first predetermined binder gap ‘G1’ (
In the example embodiment, servo stamping press 10 is digitally programmable and includes a programmable controller 70 for controlling movements and components of the servo stamping press 10. As used herein, the term controller refers to an application specific integrated circuit (ASIC), an electronic circuit, a processor (shared, dedicated, or group) and memory that executes one or more software or firmware programs, a combinational logic circuit, and/or other suitable components that provide the described functionality.
In one example operation, controller 70 commands the servo stamping press 10 to begin in the position shown in
As shown in
In the example operation, controller 70 commands the upper die 22 to then be lowered to a third predetermined distance ‘D3’ beyond distance ‘D1’ to engage and finally form the blank 60 around the stationary punch 32 in a second strike or press (as shown in
In one example, ‘D1’ is between approximately 80% and approximately 100% of ‘D3’ or between 80% and 100% of ‘D3’. In another example, ‘D1’ is approximately 90% of ‘D3’ or 90% of ‘D3’.
As shown in
In a second stage after the first strike, the servo stamping press 10 is operated with a relatively higher cushion force (e.g., 60 tons) to create a high draw-in resistance force or a near lock condition. This higher cushion force is configured to reduce draw-in or even lock movement of blank 60. Additionally, the higher cushion force is configured to create a post-stretch condition, which is a die process where the blank is locked-up (e.g., clamping the blank with stake bead, teeth, etc.) to stop draw-in and subsequently stretched over the punch prior to the press reaching the bottom of the strike. This is configured to induce a minimum of 2% stretch in the blank near the bottom of the press strike, which has proven effective in reducing residual stresses gradient and reducing or eliminating springback to thus form a finished stamped product with more accurate dimensions. Moreover, the resultant stretch in the sidewall of the blank is configured to reduce part-to-part variation caused by incoming material variation.
It will be appreciated that while shown with the example servo stamping press 10 illustrated in
Described herein are systems and methods for controlling draw-in of a sheet metal blank during a stamping process. A double-hit capacity servo stamping press performs a first strike to partially form the blank. During the first strike, a movable spacer wedge is disposed in the stamping press between the die and the blank holder to control the binder gap distance of the ram during the first hit to thereby ease the draw-in. After the first hit, the movable space wedge is removed and a second strike causes the partially formed blank to be held between gripping surfaces on the dies to reduce draw-in or even lock the sheet's movement for springbuck reduction.
It will be understood that the mixing and matching of features, elements, methodologies, systems and/or functions between various examples may be expressly contemplated herein so that one skilled in the art will appreciate from the present teachings that features, elements, systems and/or functions of one example may be incorporated into another example as appropriate, unless described otherwise above. It will also be understood that the description, including disclosed examples and drawings, is merely exemplary in nature intended for purposes of illustration only and is not intended to limit the scope of the present disclosure, its application or uses. Thus, variations that do not depart from the gist of the present disclosure are intended to be within the scope of the present disclosure.