US2018214921A1PendingUtilityA1
Universal Dies Of Controllable Curvature
Est. expiryAug 2, 2031(~5.1 yrs left)· nominal 20-yr term from priority
Inventors:Viswanathan Madhavan
B21D 11/02B21D 7/085
60
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Claims
Abstract
A flexible but strong universal die is disclosed, that is flexible enough to be elastically deflected into different curvatures by actuating forces and moments, while being strong enough to support the die forces and moments that it has to apply to parts to form them to the shape corresponding to its shape. A design of the die and actuation locations that makes it easy to deflect it into different constant curvatures, as well as into shapes with gradients of curvature along the length of the die, and the use of these dies for stretch roll forming are disclosed.
Claims
exact text as granted — not AI-modified1 . A forming process comprising:
forming a part around one or more first universal dies, by a means applying forming force, to take a shape similar to that of the one or more first universal dies, wherein the one or more first universal dies contain one or more active areas whose curvatures can be changed while the part is being formed and simultaneously moved along the one or more active areas, wherein the change in curvature is accomplished by use of one or more actuators to cause actuating forces and moments at the active areas that are more than die forces and moments at the active areas, that are caused by the forming force, wherein the one or more actuators act either over portions of the active areas, or over other regions of the one or more first universal dies.
2 . The forming process of claim 1 wherein the forming force is reduced by stretching the work piece along its length.
3 . The forming process comprising:
forming a part by means of one or more first universal dies to take a shape similar to that of the one or more first universal dies, wherein one or more second universal dies of shape that mate with the one or more first universal dies is provided wherein the one or more first universal dies and second universal dies contain one or more active areas whose curvatures can be changed while the part is being formed and simultaneously moved along the one or more active areas, wherein the change in curvature is accomplished by use of one or more actuators to cause actuating forces and moments at the active areas that are more than die forces and moments at the active areas, that are caused by the forming force, wherein the one or more actuators act either over portions of the active areas, or over other regions of the one or more first universal dies wherein the means of applying forming force acts through the one or more first universal dies, the one or more second universal dies, or a combination thereof such that the part is clamped between the one or more first and second universal dies to form the part to a local curvature of the one or more first and second universal dies, the one or more first and second universal dies and the means of applying forming force together comprising a station.
4 . The forming process of claim 1 or claim 3 wherein the one or more first universal dies, and the one or more second universal dies, when provided, have a compliant material over it/them so as to apply traction to the part and to accommodate mismatch in the curvatures of the mating dies.
5 . The forming process of claim 4 wherein the one or more first universal dies and second universal dies, when provided, are circumscribed by a respective endless belt with elastomeric backing that serves as the compliant material.
6 . The forming process of claim 5 wherein the belts are driven in opposite rotational directions around each of the one or more first and second universal dies of a station, so that the belts at a station together pull the part in one direction.
7 . A forming process using in series two or more stations of claim 4 , the curvatures of each of the active areas of which are changed to form one or more local shapes at different locations along the length of the part, to form the part to the desired curvature at each of these locations.
8 . The forming process of claim 7 wherein the part moves through the series of two or more stations, each of which adjusts the curvatures of each of the active areas of the one or more first universal dies or first and second universal dies, to correspond to the local shape required to form area of the part in contact with each of the active areas.
9 . The forming process of claims 8 wherein the two or more stations pull the part in opposing directions to generate longitudinal stress within the part.
10 . The forming process of claim 9 wherein bending of the part by the two or more stations is assisted by substantial longitudinal tensile stress within the part, which reduces the bending moment required to plastically bend the part.
11 . The forming process of claim 9 wherein bending of the part by the two or more stations is assisted by substantial longitudinal compressive stress within the part, which reduces the bending moment required to plastically bend the part.
12 . The forming process of claim 10 wherein the stations are arranged into two sets, a set of exit stations that pull the part through, and a set of brake stations that apply an opposing force to the part as if to try to prevent the part from being pulled through the set of brake stations.
13 . The forming process of claim 12 wherein the part enters at the beginning of the first brake station and exits at the end of the last exit station.
14 . The forming process of claim 13 wherein changes in curvature of each local region of the part occur during the time the local region of the part is within the first exit station.
15 . The forming process of claim 14 wherein the position and orientation of each of the exit stations is changed to place these stations at the correct locations and orientations determined by the already established shape of the part, so that they can pull the part without further deformation.
16 . The forming process of claim 6 wherein said belts have harder fibers and/or particles embedded in the elastomeric backing, to introduce additional local surface deformation of part, to produce surface finish or properties similar to that of shot peened parts.
17 . The forming process of claim 5 wherein the interfaces between the belt(s) and the universal dies contains low friction lubricants that reduce friction between the dies and the belt(s).
18 . The forming process of claim 6 wherein rolling elements are interspersed between the belts and the universal dies to reduce friction between the universal dies and the belts.
19 . A forming process comprising:
forming a part around one or more first universal dies, by a means applying forming force, to take a shape similar to that of the one or more first universal dies, wherein the one or more first universal dies contain one or more active areas whose curvatures can be changed while the part is being formed and simultaneously moved along the one or more active areas, wherein the change in curvature is accomplished by use of one or more actuators to cause actuating forces and moments at the active areas that are more than die forces and moments at the active areas, that are caused by the forming force, wherein the one or more actuators act either over portions of the active areas, or over other regions of the one or more first universal dies, wherein the means of applying forming force acts through a matching set of second universal dies of shapes that mate with the previously said one or more first universal dies to form a first station where the part is clamped between the one or more first and second universal dies to form the part to the local curvatures of the one or more first and second universal dies, wherein the one or more first and second universal dies are each circumscribed by endless belts that are driven around the dies along the active areas, and where a second station acts on the part and has endless belts driven so as to pull the part in a direction opposite the direction the part is moved by the first station, to generate longitudinal stress within the part that reduces the bending moment required to plastically bend the part.
20 . The forming process of claim 1 wherein the one or more first universal dies, and the one or more second universal dies, when provided, have a compliant material over it/them so as to apply traction to the part and to accommodate mismatch in the curvatures of the mating dies.Cited by (0)
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