The present disclosure relates a stamping machine and a method of stamping a sheet material.
Traditionally, machines used stamping techniques to stamp sheet material that lead to spring back in the sheet material. Spring back is the geometric change made to the sheet material at the end of the forming process when the sheet material has been released from the machine. Upon completion of the stamping operation, the sheet material springs back thereby affecting the accuracy of the finished sheet material. Modern machines and stamping techniques (e.g., stake beading) reduce spring back at the expense of wasting sheet material. Thus, there is a need for a machine and stamping operation that eliminates or at least substantially minimizes spring back in the stamped material while avoiding waste material.
According to a first aspect of the present disclosure, there is provided a stamping machine that is configured to shape a sheet material. The stamping machine includes a punch fixed to a support surface; an upper binder that is movable relative to the punch, and defining a cavity that is shaped to correspond to a shape of the punch; a lower binder located about a periphery of the punch, the lower binder being movable relative to the punch; a first cylinder positioned between the lower binder and the support surface, the first cylinder supporting the lower binder as it moves relative to the punch; a second cylinder positioned between the upper binder and the lower binder; a cushion pin positioned at the support surface that is configured to contact and control movement of the lower binder relative to the punch, first teeth formed on upper binder; and second teeth formed on the lower binder that are opposed to and correspond to the first teeth. A force exerted by the second cylinder is greater than that exerted by the first cylinder, and the force exerted by the cushion pin is greater than that exerted by the second cylinder. In a first stage where the upper binder is moved in a direction toward the punch, the lower binder is moved by the second cylinder against the force exerted by the first cylinder to an extent that a gap is maintained between the first teeth and the second teeth that ensures that the first and second teeth do not grip the sheet material, and in a second stage where the upper binder is continued to be moved toward the punch, the lower binder is moved by the second cylinder against the force exerted by the first cylinder until the lower binder contacts the cushion pin, and upon contact by the lower binder with the cushion pin, the gap between the first and second teeth is removed such that the first and second teeth grip and hold the sheet material. In this manner, by controlling the moment at which the sheet material is gripped by the first and second teeth, a draw-in movement of the sheet material toward the cavity can be controlled, which allows spring back of the sheet material during the stamping process to be more easily controlled and mitigated.
According to a second aspect of the present disclosure there is provided a method of stamping a sheet material that includes placing a sheet material in a stamping machine, wherein the stamping machine includes a punch fixed to a support surface; an upper binder that is movable relative to the punch, and defining a cavity that is shaped to correspond to a shape of the punch; a lower binder located about a periphery of the punch, the lower binder being movable relative to the punch; a first cylinder positioned between the lower binder and the support surface, the first cylinder supporting the lower binder as it moves relative to the punch; a second cylinder positioned between the upper binder and the lower binder; a cushion pin positioned at the support surface that is configured to contact and control movement of the lower binder relative to the punch; and first teeth formed on upper binder and second teeth formed on the lower binder that are opposed to and correspond to the first teeth, wherein a force exerted by the second cylinder is greater than that exerted by the first cylinder, and the force exerted by the cushion pin is greater than that exerted by the second cylinder. The method also includes moving the upper binder in a direction toward the punch such that the lower binder is moved by the second cylinder against the force exerted by the first cylinder to an extent that a gap is maintained between the first teeth and the second teeth that ensures that the first and second teeth do not grip the sheet material; and continuing to move the upper binder toward the punch such that the lower binder is moved by the second cylinder against the force exerted by the first cylinder until the lower binder contacts the cushion pin, wherein upon contact by the lower binder with the cushion pin, the gap between the first and second teeth is removed such that the first and second teeth grip and hold the sheet material. In this manner, by controlling the moment at which the sheet material is gripped by the first and second teeth, spring back of the sheet material during the stamping process can be more easily controlled and mitigated.
According to a third aspect of the present disclosure, there is provided a stamping machine that is configured to shape a sheet material. The stamping machine includes a punch fixed to a support surface; an upper binder that is movable relative to the punch, and defining a cavity that is shaped to correspond to a shape of the punch; a lower binder located about a periphery of the punch, the lower binder being movable relative to the punch; a hydraulic cylinder positioned between the upper binder and the lower binder; a fluid tank in communication with the hydraulic cylinder via a valve; a switch that is operable to open and close the valve; first teeth formed on upper binder; and second teeth formed on the lower binder that are opposed to and correspond to the first teeth. In a first stage where the upper binder is moved in a direction toward the punch, the valve is in a closed position and the lower binder is moved by a force exerted by the hydraulic cylinder against the lower binder to maintain a gap between the first teeth and the second teeth that ensures that the first and second teeth do not grip the sheet material. In a second stage where the upper binder is continued to be moved toward the punch, the lower binder is moved by the hydraulic cylinder until the lower binder contacts the switch to open the valve and permit a fluid to flow from the hydraulic cylinder to the fluid tank, which permits the hydraulic cylinder to compress and allow the upper binder to move toward the lower binder until the gap between the first and second teeth is removed such that the first and second teeth grip and hold the sheet material.
Further areas of applicability of the teachings of the present disclosure will become apparent from the detailed description, claims and the drawings provided hereinafter, wherein like reference numerals refer to like features throughout the several views of 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 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.
Example embodiments will now be described more fully with reference to the accompanying drawings.
Upper binder 12 is generally U-shaped and formed of a metallic material. Upper binder 12 includes a sheet material contact surface 22, inside walls 24, and an upper cavity surface 26. As best shown in
Punch 16 is fixed on a support surface 38 and made out of a metal material. Punch 16 is received inside the cavity 30 of the upper binder 12 an initial distance when the upper binder 12 is driven downwardly along the punch 16 the initial distance and is received therein a greater distance when the upper binder is driven downwardly along the punch 16 a remaining distance. The punch 16 includes a lower end 40 and an upper end 42. The lower end 40 is positioned on the support surface 38 beneath the upper end 42.
Upper end 42 of punch 16 is aligned with the cavity 30 of the upper binder 12 and is shaped to be received within the cavity 30. The upper end 42 includes outer walls 44 and an engagement surface 46. The outer walls 44 extend parallel to the inside walls 24 of the upper binder 12 and extend perpendicular to the engagement surface 46. The outer walls 44 are adjacent to the inside walls 24 of the upper binder 12 when the upper end 42 is received within the cavity 30. The outer walls 44 include punch radii 48 that are connected to the engagement surface 46. The engagement surface 46 is disposed inside the cavity 30 of the upper binder 12 when the upper end 42 is received within the cavity 30.
Lower binder 14, as noted above, extends around a periphery of punch 16, is movable relative to punch 16, and is formed of a metallic material. Lower binder 14 includes an upper engagement surface 50 that is parallel with sheet material contact surface 22 of upper binder 12, and an opposing lower surface 52 that is parallel with upper engagement surface 50. Inner and outer side surfaces 54, 56 connect upper engagement surface 50 and lower surface 52, with inner side surface 54 extending adjacent to outer walls 44 of punch. Upper engagement surface 50, as best shown in
Each tooth of upper and lower teeth 28, 58 include a material engagement surface 64, a first side surface 66 that faces the punch 16, and a second side surface 68 that faces away from punch 16. A sharp corner 70 is formed at the intersection between material engagement surface 64 and second side surface 68. Sharp corners 70 are configured to bite into the sheet material 18 during compression of the sheet material 18 between upper and lower teeth 28, 58. An angle α between material engagement surface 64 and second side surface 68 that defines sharp corner 70 may be about ninety degrees, or may be acutely angled. If the angle α is acutely angled, the angle α may lie in the range of seventy degrees to about eighty degrees.
A rounded or bending corner 72 is formed at the intersection between material engagement surface 64 and first side surface 66. Rounded corner 72 is configured to bend sheet material 18 when sheet material 18 is gripped between upper and lower teeth 28, 58, and permit sharp corners 70 of another tooth of the upper and lower teeth 28, 58 to bite into the sheet material 18. More specifically, the rounded corner 72 of lower tooth 58 that is circled in
Again referring to
Operation of machine 10 will now be described. In a first stage where upper binder 12 is actuated downward in the direction A by the drive mechanism (not illustrated), lower binder 14 will begin to be actuated downward through the force exerted by second cylinder 76, which is greater than the force exerted by first cylinder 74, and which will cause first cylinder 74 to begin to retract. As first cylinder 74 retracts, a gap G is maintained between sheet material contact surface 22 of upper binder 12 and upper engagement surface 50 of lower binder 14. Thus, while sheet material 18 is not gripped by upper and lower teeth 28, 58, sheet material 18 will begin formation into the final part. In other words, due to the gap G between teeth 28, 58 that prevents the teeth 28, 58 from gripping sheet material 18, the sheet material 18 is permitted to be drawn in a direction toward cavity 30.
Now referring to
Then, referring to
With above-described configuration, spring back is reduced during formation of the part. Spring back is reduced because the teeth 28, 58 do not grip the sheet material 18 during the initial formation of the part, which allows the sheet material 18 to be drawn in the direction toward cavity 30. That is, by initially maintaining the gap G between upper die 12 and lower die 14 during the stamping operation, the material is permitted to stretch, but also permitted to be drawn toward cavity 30. By allowing the sheet material 18 to be initially stretched and drawn in the direction toward cavity 30, the total amount of force that is applied to the sheet material 18 during the stamping operation is reduced, which assists in preventing split when forming a deep draw part. In this manner, the chance of the sheet material 18 cracking or tearing is reduced. This is particularly advantageous when the sheet material 18 is formed from a material such as a high-strength steel or other high-strength material.
Now referring to
In a first stage of the stamping operation that is conducted by machine 80 (
When the stamping operation is finished, upper binder 12 will begin to be moved upward. Because valve 84 is still in the open position, second cylinder 76 will be permitted to uncompress (i.e., extend by oil re-fill). As second cylinder 76 extends, air pressure in the fluid tank 82 will force fluid through the open valve 84 back into second cylinder 76. Then, as upper binder 14 is pulled upward by second cylinder 76 along with upper binder 12, the pressure on arm 88 will be relieved and permit arm to move switch 86 to the closed position. At this time, valve 84 will close and second cylinder 76 will be ready to conduct another stamping operation.
With above-described configuration, spring back is reduced during formation of the part. Spring back is reduced because the teeth 28, 58 do not grip the sheet material 18 during the initial formation of the part, which allows the sheet material 18 to be drawn in the direction toward cavity 30. That is, by initially maintaining the gap G between upper die 12 and lower die 14 during the stamping operation, the material is permitted to stretch, but also permitted to be drawn toward cavity 30. By allowing the sheet material 18 to be initially stretched and drawn in the direction toward cavity 30, the total amount of force that is applied to the sheet material 18 during the stamping operation is reduced, which assists in preventing split when forming a deep draw part. In this manner, the chance of the sheet material 18 cracking or tearing is reduced. This is particularly advantageous when the sheet material 18 is formed from a material such as a high-strength steel or other high-strength material.
While switch 86 has been described as a mechanical switch that is actuated by contact with lower binder 14, it should be understood that other types of switches may be used in place of switch 86. For example, mechanical switch 86 may be replaced by an optical switch that emits a laser or some other type of beam of light without departing from the scope of the present disclosure. In such a configuration, as lower binder 14 is moved downward and contacts the laser or beam of light, the optical switch will actuate valve 84.
The foregoing description of the embodiments has been provided for purposes of illustration and description. It is not intended to be exhaustive or to limit the disclosure. Individual elements or features of a particular embodiment are generally not limited to that particular embodiment, but, where applicable, are interchangeable and can be used in a selected embodiment, even if not specifically shown or described. The same may also be varied in many ways. Such variations are not to be regarded as a departure from the disclosure, and all such modifications are intended to be included within the scope of the disclosure.
Number | Name | Date | Kind |
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4576030 | Roper | Mar 1986 | A |
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20200197997 | Zhou | Jun 2020 | A1 |
Number | Date | Country |
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10334483 | Mar 2005 | DE |
102008017728 | Oct 2009 | DE |
20090010448 | Jan 2009 | KR |
101611735 | Apr 2016 | KR |
Entry |
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Machine translation of DE 102008017728, Retrieved from Search Oct. 17, 2022, 5 Pages. (Year: 2009). |
Machine translation of KR 101611735, Retrieved from Search Oct. 17, 2022, 9 Pages. (Year: 2016). |
Machine translation of KR 20090010448, Retrieved from Search Oct. 17, 2022, 5 Pages. (Year: 2009). |
Machine translation of DE 10334483, Retrieved from Espacenet Oct. 17, 2022, 10 Pages. (Year: 2005). |
Number | Date | Country | |
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20220161307 A1 | May 2022 | US |