The invention relates generally to a variable width roll forming apparatus capable of forming a continuous web of sheet material as the web passes through a plurality of matching die rolls, and more particularly to a variable width roll forming apparatus which is capable of varying the spacing between matching die rolls, as well as compensating for variations in the width of the web.
Known roll forming machinery usually has a plurality of sets of roll dies, typically arranged in upper and lower matching pairs, and usually spaced apart along the length of the machine on roller stands. Typically, the roller dies at one stand will produce a continuous formation in the web, and the roller dies of the next stand will produce another formation, or for example increase the angle of the formation which has already been started at the previous stand and so on.
A wide variety of commercial and other products are made on such roll forming machines, such as roof decking siding, as well as a large number of components for consumer equipment. The shapes may simply be webs with edge formations formed along one edge or both, or may be C sections or U sections but in many cases consist of relatively complex formations with longitudinal formations being formed along the length of the web, side by side.
Generally speaking at each stand of rolls there are two lower dies and two upper dies arranged in pairs, on either side of a central web axis to form thereby various bends or shapes in the web. The lower dies engage the underside of the web and the upper dies engage the upper side of the web. The dies have circular shapes, and are mounted on rotatable axles so that the dies can rotate at the same speed as the sheet metal. A gear drive mechanism is coupled to the dies so as to drive them at the speed of the sheet metal.
In order to keep capital costs low, it is desirable to use the same roller dies for forming finished products from webs of varying widths. Thus, spacing between opposing roller die stands may need to be increased or diminished according to the width of the web being formed. In the past, each of the stands situated on either side of the web would have to be manually moved further apart, or closer together, to account for the width of the new web to be processed. However, as will be readily appreciated, it was time consuming to manually dismantle the arrangement of dies for one web width, and then reassemble the dies with a greater or lesser number of rolls between them to suit the new web width.
Commonly assigned U.S. Pat. No. 6,647,754, titled “Variable Width Roll Forming Apparatus”, herein incorporated by reference in its entirety, discloses several embodiments of a roll forming machine that is capable of quickly moving groups of roller stands, on either side of a metal web, either farther apart or closer together to accommodate webbing of differing widths.
In a preferred embodiment disclosed by U.S. Pat. No. 6,647,754, as shown in
However, in practice, it has been found that the guide pins and bushings do not adequately ensure smooth and continuous motion of the collector plates toward and away from the side plates or each other.
Accordingly, it is desirable to provide a variable width roll forming apparatus in which the collector plates can be moved smoothly and continuously toward and away from the side plates and each other.
After diligent investigation, it has been discovered that the traditional arrangement of jack screw, guide pins, and bushings can often result in frictional binding of a collector plate along one or more of the guide pins. In particular, the collector plate will tend to bind on a guide pin that is even slightly out-of-parallel with the jack screw. Since the guide pins are subject to forces transverse to the jack screw axis, while the jack screw ideally is not subject to transverse loading, parallelism of the guide pins to the jack screw varies depending on the distance between the collector plate and the side plate. In particular, as the collector plate moves further from the side plate, it becomes increasingly likely that one or more guide pins will bend elastically out of alignment with the jack screw, resulting in frictional binding.
It has further been discovered that frictional binding of the collector plate on a guide pin produces a torque on the collector plate transverse to the axis of the jack screw. This transverse torque twists the collector plate bushings out of alignment with the guide pins, leading to a further bind-up of the collector plate on additional guide pins that is relieved only when torque on the jack screw exceeds the frictional drag exerted by the guide pins on the bushings.
Accordingly, it would be desirable to distribute loads transverse to the jack screw axis so as to maintain the jack screw and the guide pins in alignment, regardless of spacing between the collector plate and the side plate. However, due to the differing mechanical cross-sections of the threaded jack screw and the cylindrical guide pins, it has not proven practicable to achieve the desired distribution of loading by varying the guide pin and jack screw dimensions.
Thus, according to an embodiment of the present invention, a variable width roll forming apparatus includes opposed pairs of collector plates, each collector plate being mounted to a corresponding side plate only by a plurality of jack screws engaged into a corresponding plurality of internally-threaded collector plate fittings.
It has further been discovered that, given a sufficient number of jack screws, and given sufficient rotational synchronicity among the jack screws, the collector plate can be supported against forces transverse to the jack screw axes and can be driven toward and away from the side plate along the jack screw axes, without requiring a guide pin and bushing to restrain rotation of the collector plate.
It has also been found that a planar dispersed array of jack screws, wherein a single line cannot be traced transverse to all of the jack screw axes, advantageously reduces transverse loadings on the jack screws due to torque transferred from each jack screw to the collector plate.
Accordingly, an improved adjustment mechanism includes a collector plate movably mounted to a side plate by a plurality of jack screws disposed in a dispersed planar array, rotation of the plurality of jack screws being synchronized by means of a chain engaging a corresponding plurality of jack screw sprockets.
These and other objects, features and advantages of the present invention will become apparent in light of the detailed description of the best mode embodiment thereof, as illustrated in the accompanying drawings.
Roll forming of the web is performed progressively at a series of roller die stands indicated generally as 110, 111, 112, 113, 114, 115, 116, 117, 118, 119, 120, 121, 122, 123, 124, 125, 126, and 127. The stands are mounted on the base B, in a manner to be described, at spaced apart intervals along the path of the web. The roller die stands are mounted in five groups: Group I, comprised of stand 110, is the lead in or pinch roll section where the flat web is gripped and driven along the path to the rest of the rolls; Groups II, comprised of stands 111, 112, 113, 114 and 115, and III, comprised of stands 116, 117, 118, 119, 120, 121, and 122, are forming dies which function to form the progressive bends in the web. Groups IV and V, comprised of stands 123, 124, 125, 126 and 127, perform finishing and straightening actions. It will be readily appreciated that stands 110-127 each comprise a pair of roller dies situated on either side of the web. That is, stand 110 comprises dies 110 A and 110 B on opposing sides of the web, stand 111 includes 111 A and 111 B on opposing side of the web, and so on. Moreover, each stand, for example 110 A and 110 B, are themselves comprised of matching upper and lower dies for contact with the upper and lower planes of the web, respectively.
As was discussed previously, it has been known to mount all of the matching upper and lower dies, for each of the stand Groups I, II, III, IV and V, on one side of the roll forming apparatus 90 through a continuous side plate 38. The counterpart matching upper and lower dies for each of the stand Groups I, II, III, IV and V are themselves mounted through a similar continuous side plate 40 (illustrated in
Turning to
Thus, the roll forming apparatus 90 need not coordinate the movement and positioning of several different side plates on each side of the roll forming apparatus 90 during operation, thereby making both the manufacture and operation of the roll forming apparatus 90 less expensive and less complex. Moreover, having a single side plate 38/40 on each side of the roll forming apparatus 90 enhances rigidity and therefore mitigates the warping and bending stresses experienced by the roll forming apparatus 90 during normal operation.
However, the single side plate construction of the roll forming apparatus 90 initially restricts the roll forming apparatus 90 to define a uniform separation distance between matching die stands on either side of an axis of movement X of the web. As was explained previously, it is oftentimes necessary to orient a given station or Group of the roll forming apparatus 90 to have a differing separation distance, or width, than the station either preceding or following the given station or Group. A number of collector plates 200 can be used for this purpose.
As depicted in
Thus, the collector plates 200 enable the roll forming apparatus 90 to selectively control the effective spacing between die stands housed within either the side plate 38 or and the side plate 40. In this manner, the roll forming apparatus 90 is capable of accommodating a web whose width varies as the web is fed through the roll forming apparatus 90, while still maintaining the rigidity of the roll forming apparatus 90 as a whole.
In order to maintain alignment between the lower dies 202 and the matching upper dies 210, each of the upper matching dies in
Additionally, a plurality of adjustment blocks 220 are mounted to the collector plates 200 via bolts 222, not to the side plate 38 (40). With such a configuration, as the collector plates 200 are shifted by operation of the jack screws 206, the blocks 220 are themselves carried either away or towards the side plate 38 (40). The ensuing interplay between the generally diagonal slot formed in the block 220, and the cam roller 225 that is fixed to the arm 215, causes a corresponding horizontal, or axial, movement of the upper dies 210.
Thus, movement of the collector plates 200 not only operates to shift a selected number of lower dies 202 in a horizontal, or axial, direction, but also precipitates an equal displacement of the matching upper dies 210, thereby maintaining proper registration between the upper and lower dies, 210 and 202 regardless of the movement of the collector plates 200.
Returning to
As shown in
Accordingly, the present invention provides a variable-width roll forming apparatus wherein collector plates carrying upper and lower roller die pairs are smoothly and continuously movable toward and away from each other without frictional binding.
This application claims the benefit of U.S. Provisional Application Ser. No. 61/221,277, filed on Jun. 29, 2009, which is herein incorporated by reference in its entirety.
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Number | Date | Country | |
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20100326160 A1 | Dec 2010 | US |
Number | Date | Country | |
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61221277 | Jun 2009 | US |