MX2007005414A - Support cradle for rolled coils and other cylindrical objects. - Google Patents

Abstract

A cradle unit for supporting metal coils, and other cylindrical objects, consistsof two, parallel and separate saddles made of polyurethane or other materialhaving a hardness range of between 50 Shore A and 90 Shore D, which saddles are connectedtogether via a pair of parallel steel angle-brackets that provide inherent structuralintegrity to the cradle unit itself, while still allowing the unit to conformto the shape or level of the underlying support structure. The single cradle unitmay be as a mobile support-device, or may be bolted or otherwise attached to a surfacefor a specific location of the stored product. The cradle unit is generally concave-shapedand has a first main or central lower concave curvature of a first radius, and amiddle or secondary transitional curvature that connects the first main lowercurvature to an upper, tertiary concave curvature of a second radius greaterthan the first radius, so that coils or rolls of different diameter may be safelyand firmly supported. In a modification, a pair of rails are provided for fixedlymounting and supporting a plurality of support cradles, where each support cradleis held in place by the rails via metal pins protruding or projecting from the bottomsurface of the support cradle that are received in openings formed the rails,whereby no lateral or longitudinal movement or sliding of the support cradlesis possible.

Description

"SUPPORT FRAME FOR LAMINATED COILS AND OTHER CYLINDRICAL OBJECTS" FIELD OF THE INVENTION The present invention relates to a frame unit, or support member, for supporting and supporting coils, such as rolled or coiled long coils of a thin flat material made of act;), at-or metal, paper, or the like, which are processed, handled, stored and transported with the longitudinal axis of the coil oriented in horizontal direction. When they are stored in their emi-terminated stage during the foot-it is between the operations, in their waiting shipment to the finished state, or during the current shipment and the final m nii store during the current use, these coils are placed designated scaffolding areas when supporting them on the floor, since allowing these coils to stay on the ground or another flat surface produces a highly stressed load at the tangential contact points. Although these coils p < They are made of metal, they are relatively soft or flexible, and susceptible to damage due to scratches, dents or marks on the surface when they play against garbage on the ground or on another surface of storage.

- BACKGROUND OF THE INVENTION Many sites where bobmts are stored are on soils that are not flat, tending to defoam the coils over time. The coils can also be damaged by flattening or denting when settling during handling operations, or from excessive pressure or weight while sitting in storage due to an individual point tangential and a high surface load. This situation is exacerbated when the reels are stacked during storage, which is common in the metal industries. Therefore, a significant expense is incurred derived from the peidido metal and the reinstallation of the damaged coils. In addition, stacked reels, when stored on flat floors, represent a safety risk when the lower row of the stack is released. This situation is dangerous for the personnel, the installations and the coils that are affected by such collapse of the battery. Various techniques have been used in an attempt to address the aforementioned problems. Some of these techniques include: adjusting the coils on a rubber or reinforced plastic couea; use the "V" shaped blocks made of polyurethane, plastic, wood or metal; and unified plastic, wood or metal slides, or other devices built from maiera similar to include or protect the coils. The support devices of polyurethane, rubber and plastic coils have the ability to dampen the coil during its settlement. These devices are typically molded or formed into a single unit, and do not provide adequate strength or structural integrity in order to support the coil stacks without the use of additional, separate and separate support structures. The wooden supports are not elastic or durable, while the supports manufactured from meto! they do not cushion and offer a surface that basically equals a bare floor. Non-unified fabrications of wood, plastic or steel are expensive to manufacture, do not offer the durability and protection of an elasluz support, and do not conform or adapt to uneven floor conditions. An example of support of the prior art is described in the U.S. Patent. No. 4,503,978 -Smit, et al., And discloses a support of rolled coils made of polyethylene. The supports of this patent generally do not provide adequate structural support, and, therefore, are typically supported by U-shaped steel channels bolted to the ground, or other apovo surfaces, and are generally not adaptable to a substructure support.

BRIEF DESCRIPTION OF THE INVENTION Therefore, the primary objective of the present invention is to provide a support frame for coils, rolls, or other cylindrical objects that provides its own inherent structural integrity if only one coil is supported on it, also conforming to the substructure behind which it lies, support frame to be used to support coils or rolls of different diameter. It is also the primary object of the present invention to provide a support frame that provides its own inherent structural integrity to support a coil thereon, also supporting the substructure behind which it is fastened, which support must also be connected to other frames for forming a multiple unit frame support to support a series of coils on it, also maintaining its adjustment characteristics to avoid damage to the coils supported thereon, and to safely stack the rows of rolls thereon. In it, too, the primary objective of the present invention is to provide a pair of rails for fixed installation and supporting a plurality of support frames, where each support frame is held in place by the rails by means of metallic protruding or protruding from the lower surface of the support frame that are received in openings formed by the rails, while the same rails are fixed to the ground, so that lateral or longitudinal movement or sliding is not possible. the support beaters. According to the invention, the frame unit to support metal coils, and other cylindrical objects, consists of two separate and parallel frame sections or seats made of polyurethane, or other material, which has a hardness range of between 50 Shore A and 90 Shore D, whose frame sections are joined or connected together by a pair of parallel steel angle brackets that provide consistent structural integrity for the same frame unit, simultaneously allowing the seats to conform to the shape or level of the frame. underlying support structure, whereby a plurality of frame units can be used to support the coils in a staggered stack. The individual frame unit can be used as a mobile support device, or it can be screwed or otherwise joined to a surface for a specific location of the stored product. The frame unit of the invention can also be attached to the base of a transport vehicle, such as a truck trailer or a wagon in order to provide the 1 macenamient c v JJ safe and protective location of the items. In this case, the nature of the soft or elastic material from which the frame unit is made is suitable for impact absorption for the transposed bina. The frame unit generally defines a concave upper surface, and has a first major or central lower concave curvature of a radius, a pair of intermediate or secondary transverse curvature sections connecting the first major mfenoi curvature to a central curvature. pair of concave upper and tertiary curvature sections of a second radius greater than the first radius, so that the coils or rolls of different diameter can be adjusted with second 1 and firmness. In a modification of the invention, a plurality of units is provided in which a plurality of frame units of the invention are connected to one in order to form an elongated integral support structural unit. This modification is a unified beam that forms a row storage configuration in which stored coils or objects are stored randomly along the frame, not to hold and protect the coils or warehouse objects, configuring the coils along the length of the frame. In another modification, each frame unit is provided with oil receiving trays that are projected out or reservoirs for picking up oil or liquid lubricant flowing or draining away from the ends of the spool supported therein. These trays are provided for the confinement of the fluid in order to avoid contami- nation of the surrounding environment, and provide an easy and safe recovery and disposal of the liquid. In yet another modification, a plurality of support frames are loosely installed in their vicinity to a pai of rreles which, in turn, are fixed to a floor in order to prevent the sliding of the support frames while simultaneously allowing the flexibility of the support frames ba or full load conditions.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be more readily understood with reference to the accompanying drawings, in which: Figure 1 is an isometric view of the frame unit for supporting a coil, roll, or other cylindrical ob ect elucidated with the invention; Figure 2 is a top view thereof; Figure 3 is a side elevation view of the same; Figure 4 is a front view of the same, Figure 5 is an isometric view showing a series of frame units of Figure 1 which is used to support a staggered bob-pr, rolls; Fig. 6 is an isometric view similar to Fig. 5 which shows the force vectors that lie on the bobbins or coils and on the series unit that supports the stack of coils or rolls; Figure 7 is an isometric diagram of a modification in which a being is provided? < of frame units of Figure 1 in a unitary structure to form a frame to support a series of rolls, rolls, or other cylindrical objects in a row; Figure 8 is a front view thereof; Figure 9 is a side elevational view thereof; Figure 10 is an isometric view showing a frame saw of Figure 7 used or to support a plurality of rows of coils or rolls; Figure 11 is an isometric illustration of the 3rd modification of the frame unit of Figure 1 with the addition of a set of tray trays that serve as deposit to collect the lubricant that drains from the coils or rolls supported or stacked on it; Figure 12 is a side view in elevation thereof; Figure 13 is a super-view thereof; Figure 14 is a front view of the same; Figure 15 is a side view of yet another modification of the frame unit in which each frame unit is provided with protruding metal bolts for the reception in openings of a pair of solid rails to a floor, or the like, for which the elehidoi unit remains in place and the sliding motion is avoided; Figure 16 is a top row of the mispa; Figure 17 is a front view of the same; Figure 18 is a top front view of a rail f or fastened to a floor or other substructure to a pair of rims of the frame unit of Figure 15; Fig. 19 is a top plan view of a pair of rails of Fig. 18 fixed to a floor or other substructure and shown supporting and holding a plurality of frame units of Fig. 15 spaced apart by the protruding metal bolts of the housing units. frame received in the opening 'of the rails; Y - Figure 20 is a side view of the elevation in Figure 19.

DETAILED DESCRIPTION OF THE INVENTION Referring now more to the drawings, and to Figures 1-6 for now, a frame unit 10 of the invention is shown to support a coil, roll, or other large cylindrical object. The frame unit 10 consists of a pair of identical base sections configured in parallel or seats 12, 14 preferably made of polyurethane, in the hardness range of between 50 Shore A and 90 Shore D. The length of each section The frame or seat 12, 14 depends on the size or sizes of the coils or rolls to be supported. In one example, each frame section is thirty-three inches (83.8 cm) long and three inches (7.6 cm wide) Each frame or seat section 12.14 defines an ascendingly oriented concave bearing surface 16, 18 which consists of a first lower or main portion 16 ', 18', respectively, having a first lane R1, and a second upper or tertiary end portion 16", 18" each of which has a second radius R2 which is greater than the radius Rl. By connecting the surface porcron 16 'or 18' with the portions 16"or 18" are the portions or regions 20, 22 of curvaturd of transition, respectively. The values of Rl and R2 will vary depending on the size of the coils or rolls to be supported. The value Rl corresponds to the radius of the bob - > roll to be supported by the frame 10, while the value R2 corresponds to the radius of the coil or max (or) to be supported by the frame 10. In the previously determined example, the radius pr rmer Rl is twenty inches (50.8 cm), while the second radius R2 is thirty-six inches (91.4 cm), increasing the height of each frame or seat section by a minimum of one inch (2.54 cm) in the medial or central part is a maximum of five inches (12.7 cm) at the extremity or end 24, 26. With respect to the transrron regrings 20, 22, it is observed that the first lower or main portion 16 '. , 18 'and the second superror or tertiary end portions 16' ', 18' 'not only have different radii Rl and R2, but, of course, they also have points different from the centers ptl and pt2, respectively. The shape or curvature of each transition region 20, 22 is formed to general a certain number of circles of different radii and from a variable center position pt [?] Between the central poles ptl v pt2 in linear relach. Using the linear equation: pt [?] - ptl + (pt2 - ptl) / (r2 - rlj? Ab ^ (l-i [i]), where pt [?] Is a center point of a circle of transition and r (i) is the radius of the transition circle, connecting the tangents of these circles generated from the curve of each transition region., 22. The frame unit 10 also includes ai, pair of angular steel supports 30, 32 in parallel configurable which provide the unit with the inherent structural integrity. Each angular support connects the corresponding ends of the two frame sections 12, 14, as seen in Figure 1. Each angular support 30, 32 consists of a horizontal section 34 and a vertical section 36, with a respective end of a frame unit mounted on them. The right angled supports are joined to the ends of the frame sections by conventional inion techniques, so that a flexible and adaptable rectilinear structure is formed. In the above-mentioned example, the length of each angular support can be typically thirty-six inches (91.4 cm), typically being the width of each of the horizontal and vertical sections of three inches (7.6 cm), and typically made of steel 3/16"(4.77 mm) Each horizontal section 34 may be provided with a pair of holes 46 for passing screws through them to hold the frame unit 10 to a floor or other sub-structure Referring to the Figure 5 and 6, it can be observed how a series of frame units 10 can be used to support a staggered vertical stack of windrows or windrows 40. The force vector diagram graphically represents windings Cl to C8 stacked on the frame units 10 of coils of the same ion. . The charges are calculated as if the stack continued to the left of the diagram. It has been assumed that each coil shown is 72"(182.9 cm) of D.E. (diameter outside or -outer diameter) and a weight W. Due to the stacking, the downward force W is divided into two vector forces W ^ and W. (For the sake of clarity, only the C2 coil has been shown with the designated forces In the middle phase, the forces acting on coil C1 are its weight W plus R derived from coil Cl and L derived from coil C. The resulting force, 2-, is derived using vector addition The forces that lie on the coil C5 are its weight plus R derived from the coil C2.The resultant force is demolished using the vector addition.In the lower row, the forces acting on the coil C6 are its weight plus 2. - P derived from coil C3 and 2 • L from the coil C4, the resultant force, 3-W, is derived using vectorial ad The forces acting on the coil C / are its weight plus 2-WR derived of the coil C4 and L derived from the coil CS.The resulting force is derived by using vectorial addition. The forces acting on the C8 coil are its weight plus 2 • R derived from the coil. The resulting force is broken using vectonal addition. In the lower row, lines are derived from the center of the coils to the edges of the ends 24, 26 of the frame unrdaaes. If the resulting power vectors remain between these lines, the stack will be stable, assuming that the coils in the stack have no function and without considering the inertia. In use it acts, the battery could be stable even if the limits were exceeded a little. Due to the condition of two separate upper curved sections of different radii Rl and R2 for each frame unit, multiple layers of drier diameters can be stacked more securely, as seen in Figures 5 and 6. Referring now to the Figures 7-10, he mu < There is a modification in which a plurality of frame units 10 is provided so as to form a frame support 50 to support a plurality of individual balls on it from end to end to form a ladder type structure. The support 50 consists of a plurality of frame elements 52 similar to the frame sections 12, 14 of the frame unit J, whose frame sections 52 are connected with one another by a pair of plates. elongated steel angles 54, 56 similar to the angled supports 30, 32 of the frame unit 10 of FIG. 1. The spacing between the frame elements 52 is generally smaller than the spacing between the frame or seating actions 12, 14 of the frame unit 10. While the spacing between the frame sections 12, 14 in a previously cited example is thirty inches (76.2 cm), the spacing between the adjacent frame elements 52 is 15-1 / 4 inches (38.74 cm), so that not only rolls of various sizes or coils of different diameters can be supported and stored on the support 50, but also coils or rolls of different lengths can be supported thereon. In addition, due to the series configuration of the frame sections 52, the positioning of a coil or roll on the support 50 can be achieved at any portion along the same allowing consequently greater ease in positioning and storage. A plurality of support 50 can be used in parallel formation, as seen in Figure 10, in order to allow the support and storage of multiple stacked rows of bobbin rolls 40. The spacing between supports 50 is dependent on the size of the bobbins. or rolls '' to lean on. Each individual support 50 is screwed to = -floor or sub-structure by screws passing through the angular supports, in the same manner as described above with reference to the base unit 10. In addition, the oil trays similar to the oil trays described below with reference to the Figures 11-14 can also be used to collect oil, or another flurry. It is noted that the individual rolls or horns are supported from end to end, their lengths being parallel to the length of the support, so that the support 50 supports them in the manner previously discussed using only a bushing. Consequently, the support 50 exerts the double function of acting as frame supports and as a coil bearing. Referring now to Figs. 11-14, another modification 60 of the frame unit 10 is shown in which a pair of oil collecting trays or reservoirs 62, 64 are provided at the ends of the frame unit in order to collect the oil or other lubricant or fluid that drains or drains from the ends of the coil supported by them. These trays proportion the confinement of the fluid in order to avoid the contamination of the surrounding environment, and provide safety, easy recovery and disposal of liquid. Each oil-based collector bank 62, 64 is preferably formed integrally with the section of the frame 12, 14 respectrva, and typically has a width of twelve inches (30.48 cm) and a length of two feet (61 cm). Each tray 62, 64 is provided with a straight edge or edge 62 ', 64' for receiving the oil. The remainder of the frame member 60 is substantially identical to the frame unit 10. The frame of the frame is inherently and inherently adapted to the contour of the underlying support structure or floor, providing spacing between the corner supports and between the frames. seats a unitary structure of self-adaptation, so that uneven or non-uniform floors will not adversely affect the support provided by the frame of the invention. In addition, the inherent elasticity of the material used in the seats offers impact absorbing characteristics. Although the preferred material for the seats has been indicated as polyurethane, comparable or equivalent material may be used instead, or composite materials, provided that these other materials are collected within the same hardness range of between 50 Shore A and 90 Shore D. Some of these other materials are, for example: nylon; nyrrm; polyethylene of all those [those molecular ones (copolymers, ultra high homopolymers density, high density, medium density, density to density); rubber such as SBR, EPDM, nitrile, neoprene (pol chloroprene), natural, Hypalon (polyethylene chlorosubstituted rubber 1), butyl; rubber granulate and re-bond); and recycled plastrcos; plastic / reclaimed wood floor (a) or other formulated combinations of m. similar nanny; Polypropylene; vmilo (PVC). Although specific dimensions have been previously determined, it should be understood that these have been determined only by way of example. Current drums can vary depending on the lengths and diameters of the coils or rolls intended to be supported. Although the regions of transitions 20, 22 have been described as having the shape or contour described above, it should be understood that other methods may be employed to produce the shape or contour thereof, as well as other different shapes and curvatures. In a variation of the support frame, the support or basestation section 12, 14 defines an ascendingly oriented concave support surface 16, 18 which consists of a first lower or main portion 6 ', 18', respectively, having a first Rl radius of about 18 inches (45.7 cm), upper-segmented portions or tertiary-end 16", 18" having a second radius R2 ele approximately 36 inches (91.4 cm), increasing the height of each frame or seat section from a minimum of 1-1 / 2 inches (3.81 cm) at the middle or center point to a maximum of 8.5 inches (21.6 cm) at the extremity or end 24, 26 Referring now to Figures 15-20, another modification 68 of the frame unit is shown. This version has special relevance for the storage of coils, rolls, and the like, on the floor of a truck during the transportation of the same, although it is intended to be used in all environments and storage locations, whether mobile or parking in a f ja In order to take into account the mom <; In addition to the forces and forces that tend to dislodge or move the support frames during normal use and load, at least one pair of longitudinal rails is provided on the floor of the truck, as shown in Figures 18-20. The pair of rails 70, 72 is spaced on the ground or other substructure by a distance that accommodates the width of the support frame unit 68, which width is defined in the direction between the seats 82 of the frame unit or alternatively for the length of each connecting arm 90, 92. In the preferred embodiment, this spacer is > is 30 or 36 inches (76.2 or 91.4 cm), taken between the exterior surfaces 70 ', 72' of the rails. Each rail 70, 72 is pioporcrona with a first series of pair ae oiificios or openings 76, 78 by which The screws or bolts permanently frosted the rails to the ground. A second series of holes or openings 80 spaced equidistantly are also provided by which the support frames are connected to the reels. The unit 68 which frame is similar to the seat units of the other embodiments described above, with the section of the addition of a pair of spaced metal bolts 84, 86 formed in each of the frame sections or seats 82. Each metal bolt 84, 86 comprises a protruding or protruding lower section 84 ', 86' provided in and projecting from the lower surface 82 'of a seat 82, the projecting sections 84', 86 'of which are received in the respective openings of the series of openings 80 of the rails 70, 72. The openings 8 (are of a diameter larger than that of the incineration bolts 84, 86 that the protruding lower sections 84 ', 86' are received loosely in the orrfrcios 80 with ob et This limited id of the bolts in the openings 80 is realized because, during normal loading of the support frames with the bobbins, the frame units undergo push-ups vd Obleces so that the difference between central lines of bolts 84, 86 tends to camoiar. This loose fit allows such flexion and bending. In the preferred embodiment, each non-metallic bolt 84, 86 ^ s of approximately 4-7 / 16 inches (0.64 to 1.11 cm) from the jo and has a diameter of approximately 7/8 of an inch 2.22 cm), with a protruding portion 84 ', 86' projecting outwardly from the 82 'bottom surface of approximately 1.11 cm Each metal bolt is urged into a respective seat upon first puncturing an opf, and then inserting and adhesively securing a bolt in the In the preferred embodiment, the holes 0 of the rail elements have a diameter of approximately 1-1 / 16 inches (2.7 cm), which given the diameter of 7/8 of an inch (2.22 cm) of each metal bolt 84 , 86, allows a play or movement of approximately 1/16 gag (0.159 cm) of the bolt in a hole, which is mac which is adequate to allow changes in spacing between bolts 84 or 86 during flexion and fold or full load conditions, as mentioned previously, the spacing between the two rails J os 70, 72 is equal to the width of the frame unit 68. Also in the preferred embodiment, the length of each rail is approximately 239-7 / 8 inches? 6-29.28 cm) with a width of three inches (7.6 cm), and a thickness x inch (1.27 cm). The spacing between the orifices 80 it is approximately crnco inches (12.7 cm), from cent to center. Also in the preferred embodiment, I heard spacing between the bolts of a seat} The spacing between the other seat bolts is approximately thirty inches (76.2 cm) from center to center. The width of the frame unit may be approximately 30 inches (76.2 cm) or 36 inches 91.4 cm), which is equal to the length of each of the steel halves 90, 92 configured in parallel. It is also noted that in this modification, the steel arms 90, G steel configured in parallel are not angular supports, as in the other modalities previously removed, but are only straight elements that connect the pair of seat supports 82 in portions of the supports are placed above the lower surfaces 82 'of the frames, so that the projecting bolts 84, 86 can be used to install the frame unit 68 on the rails 70, 72, in the manner described with anterroriclacl. Also, in the preferred embodiment, the radius Rl for the frame unit 68 is 18 inches (45.7 cm) and the radius P2 is six and six inches (91.4 cm). The transition region is determined using the nrsmc prior-deserrto method or reference to the modality of Figure 1 Although it has been indicated that the bolts 82, 84 are metals, it should be understood that equivalent materials may be used. In addition, the dimensions listed above have been determined only through the example and are not intended to be construed as meaning. Moreover, although the overhanging members have been described as bolts, other equivalent members may be used instead, it being understood that the protruding members should not be construed to exclude other equival members or ways to install the seats in the holes of the rail elements for a limited degree of movement in them. Although the specific embodiments of the invention have been shown and described, it is understood that numerous changes and modifications may be made to the same without being insulated from the scope and spirit of the invention as set forth in the appended claims.

Claims (1)

1. NOVELTY OF THE INVENTION Having described the invention as antecedent, the content of the following claims is claimed as propredad: CLAIMS 1. A supporting frame to support coils, rolls, and other identical objects, has been expressed because it comprises: a pair of parallel seating elements made of a material within the hardness range of between 50 jhore A and 90 Shore D; each asperate element comprises a concave upper surface on which a portion of a coil or roll lies; defining this superfrcie superror concav < a central curve section of a radius Rl, and a pai of curved super-thermomic sections of one of a radius R2 greater than Rl, and the pair of transition sections, making the transition each section of the transition from the curved section central and lower to a respective pair of super-curved thermionic secrons, said radius Rl corresponding to the minimum radius of a coil or roll to be supported by said pair of pins, and said radius R2 corresponding to the maximum radius of a coil or roll to be supported by said pair of seats; and a pair of parallel connection elements, each of connecting elements connecting the corresponding ends of said pair of seat elements in order to form a rectilinear structure. 2. The support frame for supporting coils, rolls, and other roller objects according to claim 1, characterized in that the material from which said pair of parallel seating elements is made is polyurethane. 3. The support frame for supporting coils, rolls, and other cylindrical objects according to claim 1, characterized in that each pair of parallel connecting elements comprises an angular support consisting of a vertical section and a horizontal section, is nested the corresponding corresponding ends of said pair of asrento elements in parallel in the same and fixed to it. The support frame for supporting coils, rolls, and other cylindrical objects according to claim 3, characterized in that the material from which said pair of parallel seating elements is made is polyurethane. The support frame to support bobbins, rolls, and other cylindrical objects according to claim 3, characterized in that each horizontal section comprises installation orrfrros for recrbrr screws to secure the frame to an underlying structure. 6. The support frame for supporting coils, rolls, and other cylindrical objects according to claim 1, further characterized in that it comprises means for depositing fluids to collect the fluid that drains from the object resting on the same. 7. The support frame for supporting coils, rolls, and other cylindrical objects according to claim 6, characterized in that said means for depositing fluids to collect fluids comprises a pair of fluid collection means, a fluid collection means. understood outside of a pair of asrentos elements and the other means of collecting fluids extended out of the other pair of seating elements. 8. The support frame for supporting bobbins, rolls, and other cylindrical objects according to claim 1, characterized in that it comprises a series of support frames connected together to form a storage configuration support in rows of support frames.; said support comprising the pair of parallel connection elements connecting the corresponding ends of the respective pairs of the elements. of all the seats of support frames. 9. A method for using the support frames to support coils, rolls, and other cylindrical objects, wherein each support frame comprises a pair of parallel as- peret elements, each as- peret element comprising a concave upper surface defining a curved section central and lower of a radius R], a pair of upper curved sections cad terminals one of a radius R2 greater than Rl, and the pair of transition sections that perform the transition from the central and lower urva section to the pair of upper terminal curved sections, and the pair of Parallel connection elements each connected to the corresponding ends of said pair of seat elements in order to fuse a rectilinear structure, the method being characterized in that it comprises: (a) supporting on the surface surface 1101 concave an object cylindrical radro approximately equal to the radius Rl; (b) resting on said surface supepoi concave a cylindrical object of radius approximately equal to radius R2. (c) step (a) comprises supporting the cylindrical object by contacting the central and lower radius curve sec- tion R1; (cl) step (b) comprises supporting the cylindrical seat by contacting the central and inverse sections of radius R2. 10. The method for using support frames to support coils, rolls, and other cylindrical objects according to claim 9, characterized in that the land (a) comprises supporting the cylindrical object of an -adio approximately equal to the radius Rl on said surface upper concave of a frame support prrmer; the step (b) comprising supporting the cylindrical object of a radius approximately equal to the radius R2 on the concave supercorruous surface of a second support of the frame. 11. The method for using support frames to support coils, rolls, and other cylindrical objects according to claim 9, characterized in that the passage (a) comprises supporting the cylindrical object of a celery unit equal to the radius Rl on said surface super concave of a frame support; extracting the cylindrical object with radius approximately equal to the radius Rl of the upper concave surface of the frame support; and step (b) comprising supporting the cylindrical object d a radius approximately equal to the radius R2 on the upper concave surface of the same basher support in the > aso (a 12. The method for using support frames to support coils, rolls, and other cylindrical objects according to claim 10, further characterized by comprising repeating steps (a) and (b) a multitude of times to form a lower layer of a series of cylindrical objects supported, and that, therefore, stack at least two additional layers of cylindrical objects supported thereon in order to form a staggered stack of stored cylindrical objects; the stacking step comprises supporting each cylindrical object of the stacking step on and between two adjacent cylindrical objects contained in the layer thereunder. 13. A support of support frames to support bulbs, rolls, and other cylindrical objects, further characterized in that it comprises: a serrated seating element configured in parallel, each asperate element being made of a material within the range of hardness of between 50 Shore A and 0 Shore D; each seat element comprising a concave upper surface on which lies a potion of a coil or roll; said upper concave surface defining a central and lower curve section of t R1, and a pair of terminal upper curved sections of a radius R2 greater than R1, and a pair of sec- transition, transitioning each transition section of the central and lower curve section a respective of the pair of upper curved thermionic sections, the radius Rl corresponding to the radius of a coil or roll to be supported by the pair of seats, cor esp? nclrendo the radius R2 to the maximum radius of a coil or roll to be supported by the seat; and a pair of parallel connecting elements extending transversely with respect to the series of seating elements, each connecting element connecting the corresponding ends of the series of seat element S in order to form a stair tripod structure; defróm the rectilinear structure a parallel branch in drreccron of the section of the pair of connecting elements. The support of support frames for supporting coils, rolls, and other cylindrical objects, according to claim 13, characterized in that each pair of parallel connecting elements comprises an angular support consisting of a vertical section and a horizontal section, the respective corresponding ends being of the series of parried seat elements admired and fringed thereto. 15. The support of support frames to support coils, rolls, and other cylindrical objects, according to claim 13, characterized in that the mate1-al a paitir of which the seat element is made is polyurethane. 16. Support support frames to support bulbs, rolls, and other cylindrical objects, according to claim 13, in combination with a series of cylindrical objects supported by the same; defining each cylindrical object a longitudinal axis; the series of cylindrical objects being configured in said series of seating elements along their lengths so that the longitudinal axes thereof are parallel to the section of said ladder tripod structure, so that it will be of objects cylindrical is configured end to end supported each crlrndrrco object at the menoL two senes of seating elements. 17. A support frame for supporting bolls, rolls, and other cylindrical objects, characterized in that it comprises: a pair of parallel seating elements made of a material within the range of 50 Shore A and 90 Shore D, def I ncrease each seat element a lower surface; each seat element comprising a concave upper surface on which a portion of a coil or roll lies; defining the upper surface concave a central section and lower radius Rl, and a p n ele upper curved thermal shields each? a radius R2 greater than Rl, and the pair of transverse sections, with each transition section transitioning to the central and lower curve section to a respective pair of upper-end curved secrons; a pair of connection elements in order to connect each connection element with the corresponding positions of the pair of as- peret elements with the purpose of forming a rectilinear structure; comprising each asperate element of at least one pair of projecting members protruding from the lower surface, for use in the mstalacioi of the support frame in a fixed support to prevent movement of the support frame during the storage of coils, rolls, and other cylindrical objects. The support frame for supporting coils, rolls, and other cylindrical objects according to claim 17, characterized in that the material from which the pair of elements in parallel is made is selected from at least one of the following g upo: polyurethane, nylon, nyrrm, polyethylene, rubber, cotton, polychloride, polyethylene chloride, chlorosulphonane, butyl, granulated and re-bonded rubber, recrystallized plasters, Tiles / recycled wood (a) and other combinations formulated in a similar way, polypropylene, and PVC. 19. The support frame for supporting billets, rolls, and other cylindrical objects according to claim 17, in combination with a pair of spaced apart elements, each rail element being fixed to a substructure; I have every element of rrel medie-? of clamping for use in securing a substructure, and a series of spaced orrfrcros, each orifice being capable of receiving therein a protruding member and a seating element. 20. The support frame for supporting bobbins, rolls, and other roller objects according to claim 19, characterized in that the holes of said series of holes are equidistantly spaced apart along the respective rail element, having a hole in said opening. the series of holes a size greater than the size of a protruding member so as to allow the movement of a respective protruding member therein, in order to accommodate the bending and bending of a supporting frame or load. 21. The support frame for supporting coils, rolls, and other cylindrical objects according to claim 17, characterized in that said upper surface with a ve defines a central and lower curved section of radius R, and a pair of thermoregular curved secrions each with radius R2 greater than Rl, and the pair of transitional secrons, the transition enhancing each transition section from the central and lower curved section to a respective pair of terminal super-rotating curved sections; Each transrcron region is defined by generating a different number of circles of different radii and from a variable central poscrum pt [?] between the center points ptl and pt2 in linear relation using the equation: p + [?] = ptl t- (pt2 - ptl) / (r2 - rl) * abs (rl-r [i]), where pi [j is a center point of a transition circle and r [?] is the radius of the transition circle, connecting the tangents of these circles generated from the curve of each transition region. 22. The support frame for supporting coils, rolls, and other cylindrical objects according to claim 20, characterized in that the orifices of the orifice of each rail element are spaced equidistantly in such a way that the protruding mrembros of an element The respective seat can be received in a number of different orifices of a respective rail element to allow different spacing between the support frames. 23. The support frame to support coils, rolls, and other cylindrical objects according to the re vindication. 17, Characterize because each element of seat is made of polyurethane of a hardness in the range of between 50 Shore A and 90 Shore D. 24. A method to support a plurality of support frames used to support coils, rolls , and other cylindrical objects, wherein each support frame comprises a pair of parallel asynchron elements, each seat element comprising a superf? The concave upper part defines a central curve and a pair of parallel connecting elements each connecting the corresponding sections of the pair of seat elements in order to form a rectrlnarly structure, characterized in that it comprises : (a) fixing a pair of Rrel elements to a sub-structure in a spaced manner; (b) Loosely attaching a plurality of support frames to the rail elements such that each support frame is supported by the rail element panel; (c) step (b) comprises inserting projecting members projecting from the surface rnfenn of the seat elements in parallel into the holes formed in the pair of rail elements; (d) step (c) comprises inserting the members protruding into the holes in such a way that the overhanging members are allowed a degree 1 i t? movement in the orrfrcios in order to accommodate induced distortions in the support frame under loading conditions. The method according to claim 24, characterized in that each support frame has a width approximately equal to the length of a connection element of the support frame, comprising step (c) installing the projecting members of an element of aster c in holes of one of the rail elements, and install the protruding members of the other seat element in the orrfrros of the other rail elements. 26. A supporting frame for supporting bobbins, rolls, and other cylindrical objects, characterized by the fact rque comprises: a set of seat elements for elo, each seat element defining a lower Jc i e; each seat element comprising a super-concave surface on which lies a piece of a coil or roll; a pair of connection elements in order to connect each connecting element by the two ccrespont lenses of the pair of seat elements with object to form a structure of rectrlnenea shape; each seating element comprising at least one projecting member protruding from the lower surface, for use in the installation of the basl? d < > r of support in a fixed support to avoid the movement > of the support frame during the storage of coils, rolls, and other cylindrical objects on the same. 27. The support frame for supporting coils, rolls, and other crimson objects, according to claim 26, characterized in that the material from which the pair of parallel element is made is selected from at least one of the following group: polyurethane, nylon, nyrrm, polyethylene, rubber, nitnide, polychloroprene, polye rubber * full chlorosulfonaclo, butyl, granulated rubber and reer. zade, recycled plastics, plastic floor / recycled wood (a) and other combinations formulated in a similar way, polypropylene, and PVC. 28. The support frame for supporting bobbins, rolls, and other cylindrical objects, according to claim 26, characterized in that in combination with a pair of spaced rail elements, each rail element being capable of being fixed to a subest? U > Luisa each element of rrel having a serre of spaced holes, each hole being able to receive in the they are a protruding member of the element eleiei t. 29. The support frame for supporting rolls, rolls, and other cylindrical objects, according to claim 26, characterized in that the holes in the series of holes are spaced equidistantly from the arc of the respective element of the element.each orrfrc or or series of orrfrios having a size greater than the size of the protruding member so that a respective overhanging member is allowed a limited amount of free movement in the mrsmo, in order to facilitate the clutch and accommodation of bending and dblz of a support frame under load. 30. The support frame for supporting coils, rolls, and other cylindrical objects, according to claim 26, characterized in that the super-concave surface defines a central and lower curve sec- tion of a radius RI, and a pair of upper terminal circular sections of each radius R2 greater than Rl, and the pair of transitional sections, making the transition each transition seccron from the zenithal curvature section and lower to a respective pair of ternary upper curved sections; each transducer region being defined by generating a certain number of circles of different radii and from a central variable position pt [?] between the central points ptl and pt2 in linear relation using the same equation: pt [] = ptl + (pt2 ptl) / (r2 - rl) * abs (rl-r [?]), donae pr [rj is a central point of a transition circuit and r [?] is the radius of the transient circle, connecting the tangents of these circuits generated from the curve of each transrcron region. The support frame for supporting bobbins, rolls, and other cylindrical objects, according to claim 29, characterized in that the asperate element comprises at least one pair of protruding members protruding from the superframe to install at least one pair of the protruding members protruding from the fritted superfrequency to install at least a pair of orifices of the being of the orifices of a respective rail element. 32. The support frame for supporting bobbins, rolls, and other cylindrical objects, according to claim 31, characterized in that the orrfrcios of the series of holes of each rrel element are spaced equidistant so that the pair of faces protruding from a respective seat element can be received in a certain number of holes or = a respective rail element to allow a different spacing between the supporting frames. 33. The support frame to support bobiias, rolls, and other cylindrical objects, according to the claim 27, characterized in that the seat element has a hardness range of between 50 Shore A and 90 Shore D. 34 The support frame for supporting bobbins, rolls, and other cylindrical objects according to the reference 32, characterized in that the seat element is made of a hardness polyurethane on the basis of between 50 Shore A and 90 Shore D, SUMMARY A frame unit for supporting metal booms, and other cylindrical objects, consists of: two parallel and separate seats made of polyurethane or other material having a hardness range of between 50 Shore A and 90 Shore D, seats which are connected with by means of a pair of parallel steel angular supports that provide inherent structural integrity to the same frame unit, simultaneously allowing the unit to assume the shape or level of the underlying support structure. The support frame unit can be a mobile support device, or it can be screwed or otherwise attached to a surface for a specific location of the stored product. The frame unit is generally concave in shape and has a central or lower central concave curvature of a first radius, and an intermediate or secondary transition curvature connecting the first major lower curvature with a superior tertiary concave curvature of a second radius greater than the first radius, so that the coils or rolls of different diameter can be supported firmly and safely. In one modification, a pair of rails is provided to be installed in the fixed array and to support a plurality of support frames, where each Support frame is held in place by: • Measuring metal bolts protruding or protruding from the undersurface of the support frame > What are received in openings formed by the rreles, for which no lateral or long-distance movement or sliding of the support frames is possible.