Steel in sheets or other forms have regularly experienced strong markets for use in the United States' industrial sectors. This need has created a need for warehousing and processing of steel sheets.
Historically, in the steel industry, warehousing of steel generally involved the stocking and selling of steel in various shapes and sizes. The warehousers did little or no processing of the steel that was inventoried. Yet, because of growth in the industrial sectors, warehousers quickly began moving into larger buildings.
The need for rolling metal sheets into coils became a natural progression for warehousers because of the large equipment and space needed for coil processing, which the warehousers could accommodate. Mainstream steel manufacturers did not have the technical ability or large equipment needed to wind steel sheets into coils.
All told, the large scale manufacture of sheet material, tinplate, ferrous alloys, tantalum, or steel to name a few examples of sheet material, has been going on since the early 17th century. For example, one process involves making tin, which is extremely malleable, into sheets for making tin cans. The shear number of tin products that get made requires that tin be made into long sheets, rolled, and then delivered in large rolls to the product manufacturers. Specialty metal shops, thin gage metal stamping operations for instance, purchase mandrels, which are large spinning machines, for use in receiving coils of steel and processing them as required.
A mandrel is used for rolling sheets of metal, tinplate for instance. The tin sheet is spun onto the mandrel. The spinning method requires clamping one end of the sheet, then spinning the mandrel so the sheet gets turned around the mandrel several times. The roll of tin sheet is held from inside the hole formed by winding, usually by an outward exertion of force of the mandrel parts. The mandrel spins and adds sheet material and increases the diameter of a coil.
In industry, it is desirable to wind these metal sheet into coils using rapid speeds. High RPMs create pressure on the clamped end of the sheet. Additionally, the heavy nature of the sheet material tugs on the sheet and the mandrel while rolling. Great forces are exerted during the process of rolling steel, for example, onto a mandrel, including those caused by high speeds and heavy weight.
The high speed spinning involved in rolling metal sheets onto mandrels is problematic. Particularly, the forces exerted on the sheets when rolling or unrolling of the sheet material damages the material by spinning it around humps, gripping mechanisms, or other imperfections of the mandrel. In fact, workers talk of a noticeable thumping sound that occurs from spinning coils being wound around such mandrel imperfections. Today, this problem prevents winding of thick gauge metal sheets because the winding results in severe imperfections.
There is a need in the mandrel industry for a new type of mandrel that can minimize or eliminate the damage to metal sheet caused by spinning the sheet around imperfections in today's mandrels. The apparatus should not detract from the mandrel's purpose of winding or unwinding metal sheet at high speeds. Such a mandrel should be usable on thicker materials as well as thinner materials.
The present invention is directed to an apparatus that satisfies these needs. The apparatus comprises a mandrel with a compensating segment that adjusts according to the thickness of metal sheet that the mandrel is processing.
The apparatus is useful to process, wind and unwind for instance, thicker metal sheet than is possible to do today without creating imperfections. The device provides a useful apparatus for winding metal sheet around a mandrel and virtually eliminating humps in the coil that occur due to imperfections found near the gripping area of present day mandrels.
The invention is an improvement to a mandrel, a clamshell mandrel to name one example, because it virtually eliminates humps, makes the winding process due to humps less noisy, and allows for winding larger thicknesses of metal sheet. Essentially the problem we are solving with this invention eliminates the hump that naturally occurs when wrapping anything around a cylinder.
One version of the inventive mandrel for mounting on an arbor shaft comprises a body segment. The body segment being substantially tube shaped. The body segment having a bore along its longitudinal axis. The body segment being mountable and demountable around the arbor shaft.
At least two hinge segments. The at least two hinge segments each being rectangular and arcuate along its short side. A compensating segment. The compensating segment being rectangular and arcuate along its short side. A gripper bar. An external body segment. The body segment being integral with the external body segment.
The at least two hinge segments, the compensating segment, the gripper bar, and the external body segment being oriented to form a tubelike shell having a diameter larger than that of the body segment. The body segment being substantially located within the tubelike shell. The at least two hinge segments being connected to the body segment. The gripper bar being moveably engaged with the body segment. The gripper bar being movable between a position inward toward the arbor shaft and a position outward away from the arbor shaft along a line substantially perpendicular to the longitudinal axis of the arbor shaft.
The gripper bar being located below and between the external body segment and the compensating segment.
A mandrel of this type could further comprise the compensating grip having a concave side. The body segment having a convex side. At least one gusset being integral with the concave side. At least one rib being integral with the convex side. At least one hole on the gusset. At least one hole on the rib. The at least one hole on the gusset being substantially aligned with the at least one hole on the rib allowing a hinge pin to pass through the substantially aligned holes such that the compensating segment is rotate-ably connected to the body segment.
Too, a mandrel of this type could further comprise a spring. A first portion of the spring being attached to the compensating segment. A second portion of the spring being attached at a point on the mandrel away from the first portion that allows the spring to exert a force on the compensating segment for moving the compensating segment toward the gripper bar which is located below the compensating segment.
The mandrel could also be such that the convex side is positioned below the outside diameter of the tubelike shell when the gripper bar is positioned inward toward the arbor shaft.
It could be such that the mandrel is a clamshell mandrel.
We envision that this mandrel could also be one where one of the at least two hinge segments is attached to the body segment via the hinge pin.
The inventive mandrel could also comprise a workpiece. The workpiece being metal sheet. Wherein the gripper bar moves between the inward and the outward position, the gripper bar in the outward position gripping a free end of the workpiece between the gripper bar and the external body segment, and the compensating segment pivoting on the hinge pin to accommodate the gripped workpiece.
It is important to understand that the hinge segment, the compensating segment, the gripper bar, and the external body segment are essentially the same length. Though, there is some shortening of the gripper bar because it fits between the retainers on either end. Such retainers are commonly used on mandrels.
Regarding the aforementioned spring, we envision that it rests on the outsides of a bolt and is capable of pulling the compensating and hinge segments in toward the center of the mandrel.
The workpiece mentioned would follow the outer profile of the gripper bar, smoothly bending along the compensating segment, before getting to the full diameter of the tubelike shell. Inserting a workpiece between the gripper bar and the external body segment determines the amount of space exiting between the convex side of the compensating segment and the outside diameter of the tubelike shell, i.e. the outside diameter of the mandrel. This is part of how the inventive mandrel compensates for different thicknesses of metal sheet. So, for instance, thinner sheet needs less space between the convex side of the compensating segment and the outside diameter whereas thicker sheet needs more space. This compensation for thickness is automatically controlled by the gripper bar and compensating segment based on their geometry. We have determined that the best geometry for the gripper bar should include a sloping outside plane, the gripper bar's face, with an offset apex. However, any geometrical configuration will work so long as the desired adjustment for workpiece thickness is achieved.
The imperfection elimination occurs because when the metal sheet wraps toward the first at least one hinge segment, then the metal sheet is at the working outside diameter of the mandrel. More particularly, the compensating effect (from the compensating segment—gripper bar—external body segment configuration) creates a sort of spiral with the first turn of the mandrel, which allows for a more gentle transition between layers of the coil. This continues with each wrap and becomes more and more subtle as the coil grows in diameter (more wraps).
These and other features, aspects and advantages of the present invention will become better understood with regard to the following description, appended claims, and accompanying drawings where:
Though the body segment 3 is tube shaped, it can have grooves, slits, channels, and the like along its length to accommodate various parts that are common to a working mandrel. Too, it is interesting to point out that the gripper bar 6 can move in and out from the center of the mandrel. This causes the gripper bar 6 to cooperate with the compensating segment 4 in altering the path around which a metal sheet can be wound; The geometries of those two elements working together.
In this particular embodiment, the mandrel was envisioned to be one that attaches to a pre-existing arbor, arbors generally hold the mandrel in place. Clamshell-style mandrels are usually designed to slip onto the arbor, and applications will require different mandrels that all are mounted and unmounted on one common arbor. This invention of course can work for mandrels that mount/unmount or those that are integrally attached to a mandrel.
A shown in
In this embodiment the gripper bar 6 has a lower gripper portion 27 to which it is slide-ably connected and is separated from the arbor by a liner 28. The foregoing pieces surrounding the arbor shaft 2.
The compensating segment 4 is rotate-ably attached to a rib of the body segment 22 via a hinge pin mechanism 21 and gusset portion of the compensating segment 23. The rib of the body segment 22 is part of the body segment which is present but beyond the cutting plane of the section view. The gripper bar 6 can be actuated such that it pushes the compensating segment 4 such that the compensating segment pivots at the hinge pin 21. A commonly known spring mechanism 26 is used to provide tension on the compensating segment, allowing it to move inward and toward the arbor shaft 2.
As shown in
This embodiment depicts a metal sheet 39 being captured between the gripper bar 37 and the external body segment 34. Notably, it can be seen at 40 that the compensating segment 31 pivots at 36 and moves inward toward the center of the mandrel. This movement of the compensating segment 31 eliminates the imperfect nature that would otherwise occur. Thus the sheet 39 winds around the mandrel at this point without traversing any hump or other such imperfections. This solution occurs chiefly because the outermost surface of the compensating segment 31 dips to a position that is below the outermost circumference of the mandrel. This effect is depicted clearly in
As shown in
As shown in
Although the present invention has been described in considerable detail with the reference to certain preferred versions thereof, other versions are possible. For example, the compensating grip can be located to accommodate clockwise or counter-clockwise spinning of the mandrel. Another possible configuration is where the mandrel and the arbor are integrally attached. Too, a body segment could fully encircle an arbor shaft and still allow for the mechanism that actuates a gripper bar to interact with a compensating segment. Of course, the inventive mandrel is intended to be used on metal sheet but is usable on any sheet material to be coiled that requires a mandrel. Therefore, the spirit and scope of the appended claims should not be limited to the description of the preferred versions contained herein.
Any element in a claim that does not explicitly state “means for” performing a specified function, or “step for” performing a specific function, is not to be interpreted as a “means” or “step” clause as specified in 35 U.S.C. § 112, ¶ 6. In particular, the use of “step of” in the claims herein is not intended to invoke the provisions of 35 U.S.C. § 112, ¶ 6.
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1067564 | Warner | Jul 1913 | A |
2265087 | Tooke | Dec 1941 | A |
2723086 | Russell | Nov 1955 | A |
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3093338 | Trapp | Jun 1963 | A |
3276715 | Tsukamura | Oct 1966 | A |
3815839 | Madachy | Jun 1974 | A |
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20180222710 | Wahlberg, Jr. | Aug 2018 | A1 |
Number | Date | Country |
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10333004 | Apr 2004 | DE |
987937 | Apr 1962 | GB |
972230 | Jul 1963 | GB |
Number | Date | Country | |
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20200164418 A1 | May 2020 | US |