SYSTEM AND METHOD FOR BENDING A HOLLOW CORE SHEET USING RODS

Abstract

A hollow core sheet having a plurality of channels and at least one bendable reinforcement rod adapted in width and thickness to a given channel dimensions for insertion inside a channel wherein the method of insertion consists in the steps of having the at least one bendable reinforcement rod having either or both of the width or the thickness having an outer dimension (OD) set between 0.50 0.75 of the given dimension of the channel with a variation of 5%.

Claims

1. A hollow core sheet having a plurality of channels and at least one bendable reinforcement rod adapted in width and thickness to a given channel dimensions for insertion inside a channel wherein the method of insertion consists in the steps of having the at least one bendable reinforcement rod having either or both of the width or the thickness having an outer dimension (OD) set between 0.50 0.75 of the given dimension of the channel with a variation of 5%.

2. The hollow core sheet of claim 1 wherein the length of the bendable reinforcement rod to be bent is directly proportional to the thickness of the sheet and the number of bends required for a particular shape and is calculated using the formula T0.5Nb=rrL wherein T is the thickness of the sheet and Nb is the number of bends and rrL is the reduced rod length.

3. The hollow core sheet of claim 1 wherein there is a minimum bend angle to stabilize the bendable reinforcement rod inside the channel wherein the minimum bend angle is calculated using the formula hyp=L/2, followed by OP=IWOD where the opposite side in a right-angle triangle is OP, the interior width of the channel is IW and the outside dimension of the rod is OD, and the angle in deis given by Sin x=OP/Hyp and x is then multiplied by 2.

4. The hollow core sheet of claim 1 wherein the reinforcement rod is made out of metal.

5. The hollow core sheet of claim 1 wherein more than one bendable reinforcement rod can be inserted into a given channel.

6. The hollow core sheet of claim 1 wherein the bendable reinforcement rod is pushed inside a channel so that each of its ends is of an equal distance inside the channel.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

[0023] Other features and advantages of the present invention will become apparent when the following detailed description is read in conjunction with the accompanying drawings, in which:

[0024] FIG. 1 is an isometric view of an example of a hollow core sheet, according to an embodiment of the present invention.

[0025] FIG. 2 is an end view of a hollow core sheet with rods of the prior art.

[0026] FIG. 3 is an end view of a hollow core sheet with 75% rods

[0027] FIG. 4 is an end view of a hollow core sheet with a flat rod set at 50% of the thickness of the hollow core sheet.

[0028] FIG. 5 is a cutaway side views of a variety of possible channel shapes.

[0029] FIGS. 6A-B are top and side see through schematic views showing various types of bend angles.

[0030] FIGS. 7A-B are isometric views showing an object having multiple bends.

[0031] FIG. 8 is a schematic view to show the trigonometric calulations to determine the minimum bend angle to stabilize a rod inside a channel.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

[0032] The following description is provided to enable any person skilled in the art to make and use the invention and sets forth the best modes contemplated by the inventor of carrying out his invention. Various modifications, however, will remain readily apparent to those skilled in the art, since the general principles of the present invention have been defined herein.

[0033] A hollow core sheet (10) having a bendable reinforcement rod (12) inserted inside a channel (14) forming part of the hollow core sheet (10). The reinforcement rod (12) is generally made out of metal for durability and bendability but any material exhibiting the same characteristics can be used. A given hollow core sheet (10) can of course have more than one rod (12). Rods (12) can be bent into many shapes and can be of any of a variety of sizes to suit the needs of the object created. More than one rod (12) can be inserted, depending upon the desired shape and size the final object happens to be. In some cases, more than one rod (12) can be inserted into a given channel. Of course, depending upon the dimensions of the channels, the rods (12) are adapted in width and thickness for the best fit. When an object requires strength, the number of rods (12) inserted inside the channels (14) can be increased to provide for a higher rod (12) density.

[0034] In a preferred embodiment, the rods (12) are round, e.g. They have a diameter instead of a width or height. In such case, the inserted rods (12) have a maximum outside diameter (OD) of 75% of the internal width (IW) of the channel (14) so that the rod (12) is not forced into the channel in such a way a to deform or even break the walls of the channel (14), which could weaken the board when curves or folds are made to create a desired shape. The prior art, as shown in FIG. 1 uses full size rods (8) which means a full 100% OD sized rod which fills the entire IW of the channel (14). There is no concern for bending issues since the purpose is not to bend the panel but rather to give it stiffness. Used as is, bending the rod (8) would result in damaging the channel (14) where the rod(s) is(are) located. The need for a 75% OD will be further discussed later.

[0035] Another factor to consider is how deep the rod (12) has to be inserted inside a channel (14), that is deeper than the edge of the channel (14), so that it does not stick out after a bend is made in the rod (12). To better understand this factor, let's take the example of a pair of pants: Everyone who has worn pants knows than when one sits down, the pants seem to have either gone shorter or the legs somehow magically got longer. In fact, none of that has happened, what really happened is that bending the knees makes the part of the pant legs behind the knees to fold behind the knees while at the same time stretching the part of the pant set in front of the knees. Since some of the cloth is stuck behind the knees, the front cloth cannot stretch as needed, which results in the pant legs creeping up. A similar phenomenon happens when bending the hollow core sheet (10). The interior side of the bend compresses while the exterior side of the bend stretches which results in the apparent shortening of the sheet (10) which makes the rod (10) stick out, unless one inserts the rod (12) slightly deeper inside the channel (14) so that when it creeps out, it is still inside the channel (14) instead of jutting out of the sheet (10). Since this phenomenon repeats for each bend, one only has to know how many bends the final piece and by how much each bend apparently lengthen the rod (or shorten the sheet) to measure and cut the rod (12) accordingly.

[0036] The inventive matter are thus the formulas to be used in order to do the proper calculations. How shorter the rod (12) needs to be is calculated relative to the size of the rod (12) that is inserted within the channel (14), which is directly proportional to the thickness of the sheet (10) and the number of bends required for a particular shape.

[0037] For example: Nb=Number of bends and T=Thickness of the sheet (10).

[0038] When many bends are needed to obtain a desired form, it is important to multiply the the thickness (T) of the sheet (10) by number of bends (Nb) by 0.5 to obtain the reduced rod length (rrL). The formula is thus:

T0.5Nb=rrL

[0039] So, for a sheet that is 4 mm thick where 3 bends are required, the formula would be:

4 mm0.53=6 mm

[0040] For a sheet (10) that is 100 mm long, the rod (12) would need to be

100 mm6 mm (rrL)=94 mm long

[0041] That 6 mm short should be split evenly between both ends of the channel (14).

[0042] To help stabilize the rod (12) inside the channel (14), especially when there is no bend required and without over stretching the hollow core sheet, a minimum bend angle (20) is needed to secure the rod (12) inside the channel (14). What this means is that given that it is recommended to use rods (12) having an OD that is 75% of the IW of the channel (14), one can clearly understand that there might be an issue with a loose fitting rod sliding out of the channel (14). In order to prevent that, a kink, otherwise known as the minimum bend angle (20) is given to the rod (12) so as to prevent sliding out of the rod (12) from the channel (14).

[0043] For clarity, the minimum bend angle (20) has been exaggerated in FIG. 6A. Also, the figure shows the bend is made across the width of the sheet (10) but it could also be made across the thickness of the sheet (10) as per FIG. 6B. If we consider that a flat rod (12) is in fact a rod (12) having a 180 degree angle, by making an arc from point A to point B in FIGS. 6A-B, The angle of the rod (12) would be slightly less than 180 degrees. In other words, the rod (12) is not flat but rather has a small bend that creates friction against the walls (13) of the channel (14) so that the rod (12) is prevented from sliding out.

[0044] How much of a bend is to be imparted on the rod (12) depends upon the length of the rod (12). Here is what that means: Looking at FIG. 6B, if the rod (12) is 3 mm in thickness and the channel (14) is 4 mm high. The rod (12) only requires a 1 mm rise to create friction at point M. But if the rod (12) is 1 mm thick and the channel (14) is still 4 mm, the rod (12) needs a 3 mm rise to create contact at point M. If in both cases the rod (12) has the same length, the degree of bend has to be higher in the 1 mm than the 3 mm rod.(12). So, when the rod (12) has a given thickness and a given length and is inserted in the channel (14) which has a given height, the rod (12) requires at least an angle of x degree in bend in order for it to make frictional contact with the interior side of the channel (14) and prevent it from sliding out. Since there is a minimum degree angle in order to achieve that, we conveniently call that the minimum bend angle (20) and make it as a rule that whenever using rods (12) having a given thickness and length that is inserted in a channel (14) of a given dimension (height or width depending on the orientation of the bend within the channel (14)), we have a specific minimum bend angle (20).

[0045] For example, if the rod (12) is 3 mm thick by 1,000 mm long and the channel (14) is 4 mm in height, applying the formula we can get the minimum bend angle (20) of x degrees.

[0046] The way it is calculated goes like this:

[0047] FIG. 8 shows a bent rod (12) represented by two right-angle triangles co-joined at their trigonometrically defined opposite sides. The angles x are identical and we know the length of both hypotenuse and the length of the opposite sides. Given that the length L of the rod (12) is 1,000 mm, that means that from A to M the length is 500 mm, and the same for M to B.

[0048] So we do hyp=L/2 to get the 500 mm

[0049] Then we need to know how much of a rise we need. The IW of the channel (14) is 4 mm and the OD of the rod (12) is 3 mm.

[0050] Thus we have rise, which is defined by the opposite side or OP:

OP=IWOD

[0051] Because the channel has an IW of 4 mm and the rod has an OD of 3 mm,

[0052] we have 4 mm3 mm=1 mm (OP).

[0053] Now having the measurements for the hypotenuse (hyp) and the rise (OP) we can obtain the minimum required angle x by applying the trigonometric function of sinus of opposite side over hypotenuse (Sin x=OP/Hyp)

Sin x=1/500

x=Sin1/500

[0054] Which gives 0.012 degree for the minimum required angle, rounded up from 0.1145.

[0055] In FIG. 8 all x are the same angle so in order to properly bend the rod, it would in fact be

20.12=0.24 degrees

[0056] In order to get the appropriate bend angle. With a much shorter rod (12) length, one quickly understands that the minimum required angle is more pronounced because the OP hyp ratio is different.

[0057] The determined angle applied to the rod (12) is measured in function of length of the rod (12) and IW of channel (14).

[0058] FIG. 5 shows variations where there is more than one angle bend which results in most of the rod (12) touching one side of the channel and only points A and B touching the opposite side of the channel. Also, the M point does not need to be in the middle.

[0059] Although the invention has been described in considerable detail in language specific to structural features, it is to be understood that the invention defined in the appended claims is not necessarily limited to the specific features described. Rather, the specific features are disclosed as exemplary preferred forms of implementing the claimed invention. Stated otherwise, it is to be understood that the phraseology and terminology employed herein, as well as the abstract, are for the purpose of description and should not be regarded as limiting. Therefore, while exemplary illustrative embodiments of the invention have been described, numerous variations and alternative embodiments will occur to those skilled in the art. Such variations and alternate embodiments are contemplated, and can be made without departing from the spirit and scope of the invention.

[0060] It should further be noted that throughout the entire disclosure, the labels such as left, right, front, back, top, bottom, forward, reverse, clockwise, counter clockwise, up, down, or other similar terms such as upper, lower, aft, fore, vertical, horizontal, oblique, proximal, distal, parallel, perpendicular, transverse, longitudinal, etc. have been used for convenience purposes only and are not intended to imply any particular fixed direction or orientation. Instead, they are used to reflect relative locations and/or directions/orientations between various portions of an object.

[0061] In addition, reference to first, second, third, and etc. members throughout the disclosure (and in particular, claims) are not used to show a serial or numerical limitation but instead are used to distinguish or identify the various members of the group.