The present invention relates, in general, to apparatus and methods for joining together the edges of sheet material which has been folded so as to form three-dimensional structures, and more particularly, relates to apparatus and methods for joining sheet material which has been folded using high-precision folding structures capable of accurately registering joinder structures for coupling together of sheet edges.
The Related Applications set forth above, and incorporated herein by reference, set forth in considerable detail apparatus and methods for bending or folding sheet material to form three-dimensional structures. Flat sheets are provided with a plurality of folding structures which will produce folding of the sheets along fold lines that can very precisely be controlled. The folding structures are typically slits, grooves or displacements that are positioned on alternating sides of a desired fold line so as to define spaced-apart bending or folding straps that precisely control folding of the sheet. Most preferably, the folding structures also produce edge-to-face engagement of the sheet material on opposite sides of the folding structures to further enhance folding precision and structural strength.
The folded sheets of the Related Applications often have been used to produce three-dimensional structures in which free or adjacent edges of the sheets are folded into abutting or overlapping relation and then are joined together to stabilize the resulting structure against unfolding. The previous techniques for securing the edges of the folded sheets together have varied considerably, depending upon the application, but in many instances the sheet edges have merely been joined together using standard fasteners such as screws, rivets, other mechanical fasteners, and/or welding, brazing or adhesives.
One of the very substantial advantages of the apparatus and method of the Related Applications is the ability to fold sheet material with both great precision and complexity using low folding forces. Precise and complex folding of sheet material allows techniques for joining the edges of the sheet material to be based upon precise registration of the edges at the end of the folding process so that joinder structures provided at, or proximate to the edges can be folded into registration with each other for the purpose of coupling the joinder structure together against separation of the edges.
The complexity with which sheets can be folded using the techniques set forth in the Related Applications allows a great reduction in the number of separate parts required to create a structure. Further reducing the number of parts by eliminating separate mechanical fasteners, therefore, is highly desirable, and elimination of separate welding, soldering and adhesive bonding steps also reduces the cost associated with the finished part.
Moreover, the precise sheet folding systems of the Related Applications can be applied to a wide range of sheet thicknesses. Thus, fastener-free sheet edge joining should also be capable of being used in applications requiring high strength joinder of the sheet edges.
What is needed is an apparatus and method to employ the ability to precisely fold sheet material in a manner which will allow fastener-free, high strength, low cost joinder of edges of the sheet material.
What is needed is an apparatus and method to provide an apparatus and method for forming enclosures or housings for various purposes, including the enclosure of electrical components, which apparatus and method lend themselves to efficient and low-cost manufacturing processes.
The apparatus and method of the present invention have other objects and features of advantage which will become apparent from, or are set forth in more detail in, the accompanying drawing and Detailed Description Of The Invention.
In one aspect, the present invention includes a sheet of material formed for bending or folding into a three-dimensional structure which includes, briefly, a sheet having edges and joinder structures proximate the edges formed to join the edges together; a plurality of shape-controlling folding structures formed in the sheet of material along a plurality of desired fold lines, the folding structures being positioned to enable folding of the sheet of material into a three-dimensional structure of a desired shape and the shape-controlling folding structures being configured to cause the joinder structures proximate the sheet edges to be positioned together in registration for joining when the sheet material is folded; and the sheet material being further formed with at least one retention structure formed to retain the joinder structures and edges together.
Most preferably, the joinder structures are provided by shaping the edges of the sheet with mating configurations, such as dovetails, which can be interlocked together against separation by the retention structure. In one embodiment, the retention structure is provided by a plurality of retention folding slits, grooves or displacements that are positioned to produce folding of the sheet material out of the plane of the joinder structures. In an alternate embodiment, the retention structure is provided by a resiliently displaceable deformation or bend which biases the joinder structures together against separation.
In another aspect of the invention, the three-dimensional object or structure formed from a sheet of material having shape-controlling folding structures, edge joining structures and retention structures is provided.
A method of fastening edges of a sheet of material together to form a three-dimensional structure is also provided and includes, briefly, the steps of: folding the sheet of material along a plurality of shape-controlling fold lines, the fold lines being controlled by a plurality of shape-controlling structures provided in the sheet of material which are adapted to cause sufficiently precise folding along the fold lines that two edges of the sheet of material are positioned in precise registered juxtaposition for fastening together; and the step of fastening the juxtaposed edges together to prevent unfolding of the three-dimensional structure.
In a further aspect, a method of assembling a plurality of components into a plurality of folded enclosures also is provided which includes the steps of: forming a sheet of material with a plurality of enclosure blanks attached in side-by-side relation to the sheet of material, with each enclosure blank having a plurality of shape-controlling folding structures formed therein and having a plurality of joinder structures formed in at least two edges of the blank. The folding structures are positioned to enable folding of the enclosure blanks into a three-dimensional enclosures with the joinder structures on the two edges being positioned together in registered relation for coupling together. The enclosure blanks also each further include a retention structures to hold the joinder structures in place against separation. The method further includes the steps of: folding each enclosure blank up out of the plane of the sheet, while still attached to the sheet of material to produce a partially formed enclosure blank; mounting a component into each of the partially formed enclosure blanks; thereafter folding the enclosure blank further while attached to the sheet of material to encircle a portion of the component and to position the joinder structures of the enclosure blank in registration for coupling together; coupling the joinder structures together; securing the joinder structures using the retention structures; and detaching the enclosures with the components therein from the sheet of material.
Reference will now be made in detail to the preferred embodiments of the invention, examples of which are illustrated in the accompanying drawings. While the invention will be described in connection with the preferred embodiments, it will be understood that they are not intended to limit the invention to those embodiments. On the contrary, the invention is intended to cover alternatives, modifications and equivalents which may be included within the spirit and scope of the invention, as defined by the appended claims.
The apparatus and method of the present invention for joining together edges of sheet material which has been folded into a three-dimensional object or structure can be employed in a wide range of applications. In
Turning to
Sheet 23 is shown in
In
Additionally, cardholder 21 is a form of enclosure or continuous peripheral wall in which one edge 26 of the blank is folded around to produce a continuous wall which is joined to the other edge 27. The three-dimensioned structure produced and joined into a stable structure by the edge joining apparatus and method of the present invention does not have to be an enclosure or to have a continuous wall which encircles a central space, but such structures are particularly advantageously formed by the present invention.
The flat sheet or cardholder blank 23 also includes a plurality of shaped-controlling folding structures 29 formed in the sheet of material along a plurality of desired fold lines 31a, 31b, 31c and 31d which will cause the sheet of material to be folded into a desired three-dimensional shape in which sheet edges 26 and 27 will be positioned in juxtaposed registered relation. This folding process will be described in greater detail in connection with
Sheet 23 is further provided with at least one retention structure formed to retain the joinder structures 28 together against separation. In the embodiment shown in
The shape-controlling folding structures 29 and the retention folding structures 32 are both preferably constructed in the same manner. These folding structures are provided as described in the Related Applications, and they are formed in a manner which will result in very precise folding of sheet material 23 along the desired fold lines. These folding structures can take the form of slits, grooves or displacements formed in cardholder blank 23, and they define folding straps 34 between longitudinally adjacent fold inducing structures 29 and 32. Folding straps 34 between the slits, grooves or displacements have center lines which extend obliquely across folding lines 31a-31d and 33a-33b so as to precisely control folding of sheet blanks 23. In the most preferred form, the folding structures are formed with a kerf or width dimension that ensures that the sheet material on opposite sides of folding structures 29 and 32 will engage in edge-to-face engagement during folding for greater precision of folding, when combined with the precision achieved by using oblique folding straps 34. The principles which control precise sheet material folding are set forth in more detail, for example, in application U.S. patent application Ser. No. 10/256,870, identified more fully in the Related Application section of this application.
Referring now to
In
In
Once back panel portions 42a and 42b have been folded together, they will be aligned in substantially the same plane, as will joinder dovetails 28 on edges 26 and 27. Such positioning of the dovetail joinder structures in the same plane allows edges 26 and 27 to be slightly displaced inwardly or outwardly of the common plane and then displaced back into the common plane of panels 42a and 42b for interlocking of the dovetails. As long as the dovetails remain in a common plane, they will not be separable, as is well know to those skilled in the art.
It is possible for back panels 42a and 42b to be oriented in slightly skewed planes and still stay interlocked, with the amount of skewing which is possible increasing as the thickness of the sheet of material and the dimensional tolerances of the dovetails are increased. In fact, as will be described below, both front panel 35 and back panels 42a, 42b are preferably bowed somewhat, from a common plane, which can be easily accommodated by the thickness of the sheet stock and even moderate differences in the dovetail dimensions.
It also should be noted that in the broadest aspect of the present invention, joinder structures 28 do not have to be formed for joining in substantially two dimensions, as are dovetails. Corner joinder structures can be provided, for example, in which the edge joinder structures prevent separation of the edges when folded together to produce a corner. A sheet retention structure must also be appropriately formed to prevent separation of the corner joinder structures from one another. Retention of the dovetails against separation is described below for joinder structures 28.
One advantage of the edge joinder method of the present invention is that the edges do not have to be overlapped, that is, the ends or edges of the sheet material are joined in end-to-end relation with the joined wall having the same thickness across the joined edges. For example, the edges of the sheet material lay “in-plane” with respect to one another and are not overlapped, that is, the edges do not lie one upon the other. This has both aesthetic and structural advantages for certain objects, such as, business card holders.
Edge joinder structures 28 are shown in the embodiment of
At this point it also should be noted that
The structure of
In the embodiment shown in
The retention fold lines 33a and 33b result in folds which are extremely difficult for even the relatively easily folded sheet material to unfold back thereby reducing the possibility that the dovetails will become disengaged.
In order to further enhance the interlocking of dovetail joinder structures 28, however, a keeper assembly further can be provided in cardholder blank 23 which is adapted to resist unfolding of the sheet material along the retention fold lines. In the embodiment of
In
It should be noted that the fold along retention fold line 33b is one in which the sheet is almost folded back on itself. This can be readily done using the technology of the Related Applications and it makes unfolding of the structure even more difficult, which is, of course, the purpose of the retention structures.
In the embodiment of
In one embodiment illustrated in
Referring to
Again, there is a possible issue of unfolding of the enclosure blank from around component 125a, 125b, and in the embodiment of
The retention structure employed in the embodiment of
The folds or corners 162 between enclosure blank side walls 139 and enclosure blank back wall 163, and between enclosure blank side wall 141 and back wall 163 are made using the technology of the Related Applications. Folds 162, therefore, are much more easily made, and they tend to resiliently spring back or have memory to a much lesser degree than bends 161. Standard or conventional metal bending becomes very difficult as shapes become complex, so it is preferable to minimize the use of reliant folds, such as corners 161, and use folds, such as folds 162, for as many of the enclosure forming folds as possible.
Once component 125a, 125b is mounted to the enclosure blank at stations 135, 140, folds 162 can be bent into the closed condition shown at stations 145 and 150. The result will be that dovetails 128 will be interlocked, and the conventional bends or deformations of the enclosure blank at folds 161 will act as resilient springs or retention structures that resist unfolding of blanks 124. The angle to which conventional corners or folds 161 are bent can be slightly less than 90 degrees so that a resilient downward biasing of sides 129 and 131 toward component 125a, 125b is maintained. This will cooperate with folding of the sides 129, 131 into abutting relation against the enclosed electronic component to keep the dovetail joinder structures from opening up or becoming separated.
As will be seen from
A sheet or strip of sheet material 123 is formed with a plurality of side-by-side enclosure blanks 124. These blanks are preferably attached to a common sheet or strip 123 which can be moved through a plurality of assembly stages, 130, 135, 140, 145, 150 and 155. The enclosure blank as formed with a plurality of shape-controlling folding structures, such as slits, grooves or displacements, and side edges 126 and 127 of the enclosure blank, are formed with joinder structures therein, such as dovetails 128. A retention structure, such as a deformation or conventionally formed fold 161 is formed in blanks 124 at an early assembly station or stage, such as stage 130, to provide a corner or bend that will resiliently return to its bent shape to provide a biasing structure. The process also includes the steps of folding the enclosure blank 124 to produce a partially formed enclosure blank; mounting a component or components in the partially formed enclosure blank; thereafter folding the blank to complete the enclosure and position the dovetail joinder structures in interengagement; and retaining or securing the joinder against separation by, for example, a resilient biasing corner, bend or deformation.
The foregoing description of specific embodiments of the present invention have been presented for purposes of illustration and description. They are not intended to be exhaustive or to limit the invention to the precise forms disclosed, and obviously many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and its practical application in order to thereby enable others skilled in the art to best utilize the invention and the various embodiments with various modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the claims appended hereto and their equivalents.
This application claims priority to U.S. Provisional Patent Application No. 60/654,545 filed Feb. 17, 2005 and entitled APPARATUS AND METHOD FOR JOINING THE EDGES OF FOLDED SHEET MATERIAL TO FORM THREE-DIMENSIONAL STRUCTURES, the entire contents of which is incorporated herein by this reference. This application is also a Continuation-in-Part of U.S. Ser. No. 10/795,077 filed Mar. 3, 2004 and entitled SHEET MATERIAL WITH BEND CONTROLLING DISPLACEMENTS AND METHOD FOR FORMING THE SAME and published as U.S. Patent Application Publication No. US 2004/0206152 A1, which is a Continuation-in-Part of U.S. Ser. No. 10/672,766 filed Sep. 26, 2003 and entitled TECHNIQUES FOR DESIGNING AND MANUFACTURING PRECISION-FOLDED, HIGH STRENGTH, FATIGUE-RESISTANT STRUCTURES AND SHEET THEREFOR and published as U.S. Patent Application Publication No. US2004/0134250A1, which is a Continuation-in-Part of U.S. Ser. No. 10/256,870 filed Sep. 26, 2002 and entitled METHOD FOR PRECISION BENDING OF SHEET MATERIALS, SLIT SHEET AND FABRICATION PROCESS and now U.S. Pat. No. 6,877,349, which is a Continuation-in-Part of U.S. Ser. No. 09/640,267 filed Aug. 17, 2000 and entitled METHOD FOR PRECISION BENDING OF A SHEET OF MATERIAL AND SLIT SHEET THEREFOR and now U.S. Pat. No. 6,481,259, the entire contents of which applications and patents is incorporated herein by this reference.
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Child | 11357934 | US | |
Parent | 10672766 | Sep 2003 | US |
Child | 10795077 | US | |
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Child | 10256870 | US |