Tubular core and method

Abstract

Disclosed is a tubular core on which sheets of metal or other material can be wound and supported, for shipment, handling and dispersal, and a method for forming the core. The core comprises a metal sheet or strip which has a rectangular-ribbed cross-sectional profile comprising rectangular, flat ribs, and which is wound spirally into a tubular configuration. The core is formed by passing the strip through a plurality of roll-forming stands, to progressively form sections of the ribs and progressively define the sections into the rectangular ribbed profile in which the flat ribs collectively form a support surface for the sheets which are to be wound on the core.

Claims

1. A method for forming a metal strip into a cylindrical core, comprising: passing an elongated metal strip having width and length and opposite longitudinal edges through a multiplicity of forming stands which form rectangular components and generally straight segments thereof in said strip and change the size and shape of the segments and components previously formed at said forming stands, wherein upon the completion of the corrugation forming process the strip comprises longitudinally extending, alternating ridges and grooves having generally vertical spaced-apart sidewalls with the ridges further comprising longitudinally extending, flat, spaced-apart top surfaces extending between adjacent ridge sidewalls and the grooves further comprising longitudinally extending, flat, spaced-apart bottom surfaces extending between adjacent groove sidewalls, the flat ridges and flat grooves together forming a rectangular, flat ribbed cross sectional profile extending along the width of the strip transverse to the length thereof; forming the opposite longitudinal edges of the as-formed corrugated metal strip into flanges adapted for forming an interlocking seam; helically coiling the as-formed corrugated strip into a cylinder having a longitudinal axis and an outer surface defined by flat, spaced-apart surfaces selected from the top surfaces and the bottom surfaces; and compressing the opposite edge flanges together thereby forming an interlocking seam extending in a spiral around the cylinder along the longitudinal axis thereof.

2. The method of claim 1 wherein the metal strip is aluminum and is 0.005″ to 0.050″ thick.

3. The method of claim 2 wherein during the helical coiling step, the metal strip is oriented at a helix angle of approximately 60° or greater relative to the longitudinal axis.

4. The method of claim 2 wherein during the helical coiling step, the metal strip is oriented at a helix angle relative to the longitudinal axis selected for forming a cylinder having a diameter of at least approximately 6″.

5. A cylindrical core, comprising: an elongated metal strip having width and length and being helically coiled into a cylinder, the cross-sectional profile of the strip along the width thereof transverse to the length thereof comprising a rectangular ribbed configuration formed by longitudinally extending, alternating ridges and grooves, the ridges having longitudinally extending, flat, spaced-apart top surfaces, the grooves having longitudinally extending, flat, spaced-apart bottom surfaces, and the flat ridges and the flat grooves together forming a flat ribbed transverse cross section; said cylinder having an outer surface formed by flat spaced-apart surfaces selected from the top surfaces of the ridges and the bottom surfaces of the grooves; and a lockseam of joined opposite edges of the metal strip, the lockseam extending in a spiral around the cylinder along the longitudinal axis thereof.

6. The core of claim 5 wherein the metal strip is aluminum and is 0.005″ to 0.050″ thick.

7. The core of claim 6 wherein the pipe diameter is at least approximately 6″.

8. The core of claim 7 wherein prior to forming the cylinder the aluminum strip is approximately 0.023″ thick and approximately 35/8″ wide; the vertical dimension between adjacent top and bottom surfaces of the as-formed cylinder is approximately 0.27″; the width of the flat ridge surfaces is approximately 0.27″; the distance between adjacent flat ridge surfaces is approximately 0.27″; the width of the flat groove surfaces is approximately 0.27″; the distance between adjacent flat groove surfaces is approximately 0.27″; and the diameter of the cylinder is within the range approximately 16″-24″.

Description

BRIEF DESCRIPTION OF THE DRAWING

[0009] FIG. 1 is a transverse cross-section of a metal strip having a rectangular corrugated transverse profile formed therein in accordance with the present invention, and preparatory to the strip being helically wound into a tubular core.

[0010] FIG. 2 depicts a strip such as that of FIG. 1 being wound into a helical tubular core.

[0011] FIG. 3 is a transverse cross-section of two adjacent windings of a strip such as that of FIG. 1 where the strip is helically wound to form a core such as that of FIG. 2, and the leading edge of one winding of the strip is joined by a lockseam to the trailing edge of the adjacent winding.

[0012] FIGS. 4-13 depict the changes in the profile of a strip or sheet at sequential stages of the profile-forming process.

DETAILED DESCRIPTION

[0013] The pipe forming in accordance with the present invention can be achieved via fixed forming using a forming shoe with a predetermined inside diameter to provide the desired pipe diameter, or by free forming using several sets of roller dies of different sizes to achieve pipes of different diameters, by adjusting the helix angle or by a combination thereof.

[0014] The illustrative equipment and process described here use, and are improvements of, the multi-pass roll former, three roll, free forming system disclosed in commonly assigned and incorporated U.S. Pat. Nos. 3,940,962 and 3,247,692 as specifically adapted to bellows pipe (relatively small diameter corrugated pipe) in commonly assigned and incorporated U.S. Pat. No. 5,074,138.

[0015] According to the present invention and referring to FIG. 1, initially a flat metal strip or sheet is roll-formed to a desired profile.

[0016] Referring to FIGS. 4-13, according to the present invention, a flat metal strip or sheet is passed through multiple stands of forming rolls to initially form rectangular features and/or straight line segments of rectangular features and to progressively add to and refine these segments and features to form the desired rectangular ribbed profile. More specifically, FIGS. 4-13 depict the sequence of changes in the strip profile starting with the initial flat strip profile and progressing through the finished rectangular ribbed profile. The ten FIGS. 4-13 depict the associated profiles 40-49 after the strip is driven through each of the ten stands of forming rollers. Illustratively, ten passes through roll-forming stands are used to form the profile.

[0017] The above profile-forming method results in the profile 10 shown in FIG. 1 which comprises alternating rectangular ribs in the form of rectangular ridges 11 and rectangular grooves 12. The ridges 11 have flat top or upper surfaces 13 and the grooves 12 have flat bottom or lower surfaces 14. A downward (or upward) opening flange or tab 16 is formed extending along one longitudinal edge of the strip or sheet transverse to the width of the strip and an opposite opening upward (or downward) extending tab 17 is formed extending along the opposite longitudinal edge of the strip.

[0018] To form the profiled strip into a tube or core, and referring to FIG. 2, the rectangular-ribbed profile strip or sheet 10 is wrapped using helical forming apparatus into a cylindrical pipe or core 20 of the desired diameter and, as shown in FIG. 3, the mating tabs 16 and 17 are compressed together to form a four-ply interlocked helical seam 21 which wraps around the pipe lengthwise along the pipe. The strip edges are held together via a continuous mechanical lockseam which is pushed together to lock the lockseam.

[0019] In the formed pipe 20, the spaced-apart adjacent flat surfaces 14 of the rectangular grooves/ribs 12 form the outside surface 22 of the core 20 and the spaced-apart flat surfaces 13 of the rectangular ridges/ribs 11 form the inside surface 23 of the core.

[0020] The strip 10 illustrated in FIG. 1 is symmetrical top-to-bottom and thus can be reversed top-to-bottom during the pipe wrapping process depicted in FIG. 2. Then the spaced-apart flat ridge/rib surfaces 13 form the outer surface 22 of the core and the spaced-apart flat groove/rib surfaces 14 form the inside surface of the core.

[0021] Referring to the FIG. 3 cross-section of the core 20 depicted in FIG. 2, in the pipes made in accordance with the present invention, the ridges and grooves maintain their generally rectangular, ribbed shape and form an open structure with spacing between the adjacent ridges 11 as well as spacing between the adjacent grooves 12. This is unlike prior designs which use non-rectangular shapes and/or an additional deformation step to form a continuous outer surface in order to provide the required strength and integrity and to provide ample flat surface area for sheet support. The outer surface is interrupted by the spacing of the inside rectangles. In a present embodiment, the width of the ridges and the grooves, and the spacing between adjacent ridges and between adjacent grooves, are all equal.

[0022] Embossments or reinforced embossments can be formed in the ribs, e.g., in the vertical legs of the ribs, to provide additional strength to the core.

EXAMPLES

[0023] The above design and method have been used to form cylindrical cores of different sizes.

[0024] Specifically, in strips or sheets 10 of aluminum which were 0.010″ to 0.023″ thick and 3⅝″ wide, ridges 11 and grooves 12 were formed which were 0.27″ in height from the top of the a ridge to the bottom of the adjacent groove. Both the ridges and the grooves were 0.27″ wide and were spaced apart 0.27″ from adjacent ridges and grooves, respectively. See FIG. 1. The rectangular corrugated strips or sheets 10 were fed to three-roll apparatus using helix angles ≥60° measured from the axis of the outgoing pipe to form continuous length pipes of 16″, 20″ and 24″ inside diameters. The pipes 20 were then cut into various lengths for use as recyclable cores onto which sheets of metal such as aluminum were to be wound for handling and dispersal.

[0025] Other dimensions and materials will be readily adapted to the invention described here by those of usual skill in the art. For example the invention can be used to form pipes approximately 6″ in diameter and greater. For a given sheet width, increasing the helix angle increases the pipe diameter. For a given pipe diameter, increasing the sheet width reduces the required helix angle. Increasing the strip width tends to increase the pipe wrapping/manufacturing speed and to decrease the number of seams in a given length of pipe.