US20120161394A1

Movatterモバイル変換

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Publication number: US20120161394A1
Application number: US13/337,778
Authority: US
Inventors: Stephen D. Weinreich
Original assignee: Individual
Current assignee: Individual
Priority date: 2009-04-27
Filing date: 2011-12-27
Publication date: 2012-06-28
Also published as: CA2827411A1; WO2012092308A1; EP2658624A1; EP2658624A4

Abstract

A slat puzzle having segments of a target image printed on the faces of slats, adjacent to at least one edge of each slat. The target image elements are made visible by offsetting each slat against the next. The offset is achieved by tilting the slats in a box or rack. The slats are constrained by interaction between the slats and the assembly box or rack to fall into uniform tilt and spacing.

Description

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of U.S. patent application Ser. No. 12/767,116 filed Apr. 26, 2010, which claims priority on U.S. Provisional Patent Application No. 61/214,682, filed Apr. 27, 2009. This application also claims priority on U.S. Provisional Patent Application No. 61/460,259 filed Dec. 29, 2010 and U.S. Provisional Patent Application No. 61/462,491 filed Feb. 3, 2011, the entireties of all of which are hereby incorporated by reference into this application.

BACKGROUND OF THE INVENTION

Picture puzzle is a generic term for an article of manufacture that is used by people, primarily for amusement and recreation. In using a picture puzzle, a person typically assembles a coherent target image from disordered elements of the target image. Jigsaw puzzles are the most common type of picture puzzle and have been a staple amusement/recreation item for many years. Typically printed onto a finished side of a sheet of stiff cardboard, which is then die-cut, most jigsaw puzzles are of the interlocking type, where assembled pieces cannot be separated from one another without lifting one out of the plane of the puzzle. Variations have included puzzles of identically shaped interlocking pieces, puzzles printed on both sides, oddly shaped puzzles, puzzles of identically shaped rectangular pieces, and puzzles where the target image is a uniform color with no markings.

Picture puzzles have also been printed on sets of blocks of square cross section, including cubes, often with each side of each block being a section of one of four or six pictures. U.S. Pat. No. 1,636,371 to Kenney, U.S. Pat. No. 2,491,296 to Beder and U.S. Pat. No. 2,581,492 Lowe et al. are of this type. Puzzles on arrays of long, slender pieces, both square, as described in U.S. Pat. No. 2,581,492 to Lowe et al., and round, as described in U.S. Pat. No. 1,257,432 to Wetzel, are known.

Also known are picture puzzles exhibiting surface relief. Interlocking picture puzzles that include joining sections of the puzzle at angles to form three-dimensional shapes are also known.

In the late 1990's, OddzOn, a subsidiary of Hasbro, Inc., sold a product called Slivers (“a slice of puzzle fun!”). The Slivers product consisted of about 50 plastic pieces, each approximately a tenth of an inch thick, one inch wide, and four inches long. The slats were stacked face to face and the stack placed on its side in a closely fitted plastic box. Vertical slices of a target image were printed, or laminated, onto the exposed edges of the slats. When the slats were properly oriented and ordered in the stack, the target image would be assembled.

Additionally, the Slivers product had a different picture on each side of the stack, which enhanced the challenge of solving the puzzle by forcing the solver to discern which long edge of each slat belonged to each of the two pictures. And the two pictures were out of sequence with each other, so, when one was assembled, the other was disassembled. Each slat was formed with tabs projecting from opposite corners, which, in cooperation with the box, enforced the end to end orientation of the visible edge of a slat, while not enforcing which long edge was placed upward. This type of puzzle is generically referred to in this disclosure as a slat puzzle.

Particular advantages of a slat puzzle over a jigsaw puzzle, which provides a similar challenge to a solver, are: a more compact structure, particularly during assembly; the area for assembly being identical to the area of the finished puzzle; that the puzzle can easily be moved about or stored while partially assembled; and there is no need for a level surface for assembly.

SUMMARY OF THE INVENTION

The present invention addresses slat puzzles of the type that have target image elements printed on the faces of the slats, adjacent to their edges; those elements made visible by offsetting each slat against the next. More particularly, the present invention addresses such slat puzzles where the offset is achieved by tilting the slats in cooperation with a box or other structure.

In one embodiment, the assembly box supports the slats uniformly on the flat bottom of the box and generally confines the slats within the sides (left and right) and ends (top/upper, away from the viewer/user; and bottom/lower, toward the viewer/user) of the box. The dimensions of the slat stack, in relation to the length of the box (end to end), generally determine the tilt of each slat in a uniformly tilted slat stack. A wedge at the top end of the box more specifically determines the tilt of each slat in a uniformly tilted slat stack.

Edge-printed, slat puzzle can be assembled in a square-sided box roughly the same size as the printed face of the slat stack. If the box is slightly longer than the slat stack, the slats can be tilted to reveal part of their faces. With a small tilt angle, uniformity across the slat stack is a natural consequence. There are substantial advantages to more extreme tilting of the slats. As the slats are tilted, the exposed area of each slat becomes larger. Correlatively, with the exposed area held constant, greater tilt means thinner material, for savings in production cost and shipping. Visually, the thinner slats permitted by the increased tilt, and the increased angle (away from the viewer/user) itself, both help to insure that the slat edges will not become visible and intrude on the target image.

Where the slats have no edge printing, and particularly where the slats are tilted at smaller angles (e.g. 45 degrees) it is preferred to use relatively dark (particularly black) substrate (or color the slat top edges) so that, should the slat edges come into view, interference with the target image will be minimized. The following description addresses slats that are printed on their faces, adjacent to their edges, and includes slats that are also printed on their edges.

It is not always a trivial task to manually adjust the slat stack to be uniformly tilted (to produce uniform offsets). The present invention provides a slat rack and/or slat configuration that causes interaction between the slats and the assembly box structure to constrain the behavior of the slats, biasing them to fall into uniform tilt and spacing.

The invention will be more fully described by reference to the following drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram of an assembled folded-slat puzzle with extended image slices.

FIG. 2A is a schematic diagram of a slat core with extended image slice.

FIG. 2B is a schematic diagram of a full single fold slat.

FIG. 2C is a schematic diagram of a partial single fold slat.

FIG. 2D is a schematic diagram of a full double fold slat.

FIG. 2E is a schematic diagram of a partial double fold slat.

FIG. 2F is a schematic diagram of a reverse double fold slat.

FIG. 2G is a schematic diagram of a slat core with label.

FIG. 2H is a schematic diagram of a slat core with larger label.

FIG. 2I is a schematic diagram of a fully wrapped slat core.

FIG. 2J is a schematic diagram of a slat core with two labels.

FIG. 2K is a schematic diagram of a multi-fold slat with web.

FIG. 3 is a schematic diagram showing image slices extended by three different (but neither exclusive nor exhaustive) methods.

FIG. 4 is a schematic diagram of a representative variation of an extended image slice.

FIG. 5A is a schematic diagram of a printed web substrate with lateral perforations, and with successive extended image slices printed in irregular sequence.

FIG. 5B is a schematic diagram of a printed web substrate with successively printed extended image slices oppositely oriented in an irregular order.

FIG. 6 is a schematic diagram of a slat puzzle with tilted slats.

FIG. 7A is a schematic diagram of slats with target image slices applied near the edges of the faces of the slats.

FIG. 7B is a schematic diagram of slats with target image slices applied near the edges of the faces of square slats.

FIG. 8 is a section through a slat stack in a square-sided, flat-bottomed box.

FIG. 9 is a section through a slat stack, supported by a wedge, in a square-sided box.

FIG. 10 is a section through a slat stack held between two wedges.

FIGS. 11A and 11B are sections through wedge and sawtooth slat racks, supporting typical, rectangular slats.

FIG. 12 is an elevation at one end of eared slats in a sawtooth edged, square-sided box.

FIG. 13 is an elevation at one end of eared slats in an ordinary, square-sided box.

FIG. 14 shows a die cutting pattern for eared slats.

FIG. 15A is an elevation/section at one end of single-edged slotted slats in an ordinary square-sided box.

FIG. 15 B is an isometric view of single-edged slotted slats in an ordinary square sided box.

FIG. 16 shows a face of a single-edged slotted slat with flared slots.

FIG. 17 shows a face of a reversible slotted slat.

FIG. 18 shows a face of a reversible hybrid (slots and ears) slat.

FIG. 19 shows a face of a single-edged slotted slat with shortened earlobes.

FIG. 20 shows a face of a single-edged slotted slat, organized for longitudinal stepping.

FIG. 21 shows a face of a reversible slotted slat, organized for longitudinal stepping.

FIG. 22 diagrams the relationship between a target picture and a set of longitudinally displaced slats,

FIG. 23 shows a slat pattern A generated from a slice of a target image, a modified form C of that pattern, and a second slat pattern B generated from an adjacent slice of the target image.

FIG. 24 shows a die cutting pattern for concentric square slats.

DETAILED DESCRIPTION

The drawings and description that follow illustrate varied embodiments of the invention taught herein. Wherever possible, the same reference numerals will be used throughout the drawings and the description to refer to the same or like parts.

FIG. 1 shows a completedslat puzzle500 according to the teachings of the present invention.Puzzle500 is comprised of a stack of a plurality ofslats400.Slats400 are shown in sequence to completetarget image600 properly assembled. Extended target image slices100 are formed by extending target image slices650 perpendicular to their long axes.

Extended target image slices100 appear on theedges401 and extend tofaces402 ofslats400. Preferably, extended target image slices100 appear on the slat edge with the original target image slice essentially parallel to the long axis of the slat. Preferably,slats400 are fabricated by printing extended target image slices100 ontosubstrates200, scoring or crimping or creasing or scratching or otherwise forming lines into the substrates (to insure clean, precise folds), and folding and gluing. For example,substrate200 can be cardboard.

FIG. 2 illustrates several embodiments ofslats400. In general, a slat is a dimensionally stable, three-dimensional, rectilinear, object.

Slat

400, as understood herein, has two relatively large, relatively flat, generallyparallel faces402, each having a length and breadth, and, separating those faces, a relativelynarrow edge401, having a thickness. Where the edge changes character or direction, such as, a right angle, sections of the edge can be referred to as separate edges, as in common speech. In addition, the common use of the term “slat” implies a substantially greater length than breadth. Those proportions are generally preferred for the present invention, but they should not be taken as limiting. A preferred slat has a rectilinear shape. It will be appreciated that other shapes ofslats400 can be used in accordance with the teachings of the present invention.

Dimensions for embodiments of the invention can vary widely, but it is generally preferred that slat thickness be from about five thousandths of an inch for example (roughly half the thickness of a mass market cardboard playing card) to about one-quarter of an inch; breadth from three-eighths of an inch to an inch and three-quarters; and length from two and one-half inches to eighteen inches. The dimensions for slats in a particular embodiment generally fall in the same end (or middle) of the range for each of the dimensions.Slats400 inpuzzle500 are preferably, but not necessarily, the same size (including thickness).

Slats

400 comprisecores300 and/or foldedsubstrates200.Substrate200, as understood herein, is of the size necessary to form oneslat400. However, it should also be understood that, at any stage of production, several ormany substrates200 may be part of the same sheet or web of material. The sheet or web may be sheared, or otherwise divided, to separate thesubstrates200, or perforated, in any pattern, preferably one leaving little attachment, for later, manual separation.

Material choices forcores300 andsubstrates200 will be readily apparent to one skilled in the art. The preferred material forcores300 andsubstrates200, without cores, is what is commonly called cardboard including, for example, chipboard, card stock, and corrugated, all of which are relatively inexpensive and ubiquitous. Forslats400 comprising folded substrates, the cardboard is preferably coated. For example the cardboard can be coated with clay or faced with higher quality paper laminated to the surface to be printed. For use in combination withcores300,thinner substrates200, preferably paper, are preferred.

Core

300 can be almost coincident in size and mechanical characteristics withslat400 that's built with it. Without the images, the slats of previously known slat puzzles arecores300 under the present parlance.FIG. 2A shows such aslat core300, onto which an extendedtarget image slice100 is applied. Extendedtarget image slice100 can be applied by any conventional or unconventional technique, such as, for example, pad printing, hand painting, or silk screen.

FIG. 2B showsslat400 without acore300.Substrate200, the length of a desiredslat400 and twice its breadth, is printed with extendedtarget image slice100, then scored along its long centerline to insure a clean fold, preferably by a die associated with the printing equipment; then folded; and, preferably, glued.

Alternatively, the printing can be onto apre-scored substrate200. It should be noted that gluing is not always necessary, andunglued slats400 of this and other forms are preferred in some embodiments, as a slight tendency to unfold can provide a gentle spring action to spaceslats400 evenly in a box, while allowing the slat stack to be compressed for slat manipulation.Slats400 can be proportioned so that the spring action doesn't cause the slat stack to buckle. Also,unglued slats400 can present some manipulation difficulties, such as tending to catch on one another as they are inserted into the stack.

Slat

400 ofFIG. 2C is folded only near one edge ofsubstrate200, while the opposite edge remains unfolded. This form is unlike mostpreferred slats400, in that the thinner, unfolded edge is not fully supported and stabilized by adjacent slats in the stack, but it can be especially useful, for example, in an arrangement whereslats400 are inserted into individual slots in an assembly rack. Separators in the rack would then not force the printed edges apart.

FIG. 2D showssubstrate200 with two folds, to formslat400 that is uniform in thickness and can carry an extended image slice on each of two edges.

Slat

400 ofFIG. 2E is similar to that of2D, having two folds in which there is a break in material between the folds to provide a slight savings in material.

FIG. 2F shows reversedouble fold slat400. A twosided puzzle500 comprising such slats, requiressubstrates200 to be printed on both sides.

InFIGS. 2G,2H,2I, and2J,thin substrates200, carrying extended target image slices100, are bonded tocores300 in various configurations. Bonding can be by any conventional or unconventional technique, such as glue, staples, or tape, including using adhesive labels as pre-bonded substrate material.

Shown inFIG. 2K,large slats400 can be formed as narrow hollow boxes, with no cores. Dimensional stability is insured by end closures and/or an internal diagonal web that can be a continuation of the box material. In this case, the slat edge is formed by two right-angle folds instead of a single fold. An edge defined by two folds can also be useful in any of the previously described slat configurations, where it is desired to have a particularly flat edge and/or with relatively thick substrate materials.

FIG. 3 shows three kinds of extended target image slices100. In each case, artwork fortarget image600, acquired in any conventional or unconventional way as, for example, by photography, drawing, clip-art, or gyotaku (Japanese fish printing), is adjusted or cropped to an appropriate size for apuzzle500. The artwork is usually the same size as the intended slat stack, but the following techniques may require original artwork slightly larger than that. A target image is understood to be essentially the same size as the slat stack with which it is associated.Target image600 is then divided into a plurality of target image slices650 to match the number ofslats400 intended forpuzzle500. As a result, target image slices650 are approximately as wide as intendedslats400 are thick.

Eachtarget image slice650 is then extended perpendicular to its long axis to any desired degree to present solving information and/or for other design reasons to form extendedtarget image slice100. Extendedtarget image slice100 is extended preferably to at least three times the thickness ofslat400.

InFIG. 3A,target image slice650 is extended by copying and concatenating adjacent target image slices650 oftarget image600. Thus (with the slices numbered in their original, assembled sequence, from top to bottom)slice3 could be extended by copying

slices

1 and2 and concatenating them to its top edge and copying

slices

4 and5 and concatenating them to its bottom edge.

The resulting image is preferably continuous, not divided into strips. With extension by copying, the original art work is preferably longer, in a direction perpendicular to the slices, by the width of one extended target image slice, at least. That is to provide material for extension of theextreme slices650 oftarget image600.

The described image manipulation can be done, almost manually, by making several physical copies of the artwork and slicing them apart on a paper cutter. The several copies are needed because successive extended slices overlap each other. Common methods of computer image manipulation, including those in commercial software packages like Adobe PhotoShop, particularly slice and divide tools, are suitable, and usually preferred.

InFIG. 3B,target image slice650 is extended by stretching either eachslice650 or theentire target image600 before slicing. Conventional computer software, including Adobe PhotoShop, provides handles and tools to stretch images and tools to slice them. Alternatively, a stretching operation can be accomplished by physically dragging an original image along the glass of a copy machine or scanner as it is copied, but that's not necessarily a practical approach. A stretched version oftarget image600 can also be relatively easily created as original artwork.

InFIG. 3C, the slice is extended by repetition. A starting pattern, can be entiretarget image slice650 or a representation oftarget image slice650. Such a representation can be, for example, a slender sample parallel to the long axis oftarget image slice650, or an essentially linear image, maybe no more than a pixel wide, showing the average color and average brightness at closely spaced cross sections oftarget image slice650. The starting pattern is then repeated several or many times, each repetition being displaced by its own width, generally perpendicular to the long axis of the slice, to form extendedtarget image slice100.

Repetition of the image slice itself can, in principle, be accomplished with a paper cutter and glue if one has enough copies of the original art work and a great deal of time and patience. Alternatively, a computer, with conventional commercial software, such as Adobe Photoshop, can be used for repetition oftarget image slice650 less tediously and more precisely. A slender sample of the slice is likewise relatively easily selected and repeated, using the same software. To repeat an essentially linear representation is similarly straightforward.

In an embodiment of extension by repetition, preferred particularly for relativelythick slats400, slender samples are selected at the extreme edges oftarget image slice650.Target image slice650 is left whole, as a portion of extendedtarget image slice100 that will eventually be registered onedge401 ofslat400, as in a mass market cardboard slat puzzle. The balance of extendedtarget image slice100 is generated by repetition of the extreme edge samples. As a result,edge401 ofslat400 will bear a detailed portion oftarget image600; faces402 of the slats will bear linear indications of the edge information.

With extension by repetition, regardless of which starting pattern is used, registration with the slat edge may not be critical. Essentially, any portion of such extendedtarget image slice100 that falls on the edge of the slat will present the same sequence of color and brightness along the slat edge as any other portion. Only whereslats400 are relatively thick and entire target image slices650 are retained in expanded target image slices100 will imprecise registration of expanded image slices100 onedges401 ofslats400 be noticeable.

An essentially linear representation of the cross sections of the image slice has to be generated, before it can be repeated. Commercial image processing software can be used. One method is to shrink an image slice perpendicular to its long axis, and to use the shrunken slice as the starting pattern for repetition.

With repetition of an essentially linear representation oftarget image slice650, image detail will be removed, which can result in a morechallenging puzzle500, especially whereslats400 are relatively thick. However, completedtarget image600 will show as a coarser grained version of the original artwork. Whereslats400 are relatively thin, the difference will not be so noticeable. In either case,extended image slice100 need not be precisely registered onslat edge401.

Each kind of extended image slice has characteristics that can provide advantages or disadvantages in particular embodiments. Those image slices extended by copying must be precisely registered on the slat edges; they provide a lot of information for the solver; they are very simple to generate. By comparison, those image slices extended by stretching are not so sensitive to registration on the slat edges; provide somewhat less information to the solver; are a little more difficult to generate; cause the assembled target image to be discontinuous from slat to slat. Those image slices extended by repetition may not need to be precisely registered on the slat edges; in many cases provide minimal information for the solver; are sometimes more difficult to generate; allow more varied design choices. Also, the visual texture of assembled puzzles will depend on the kind of extension.

Varied design choices include non-uniform extension (different image components to different extents) of an image strip, such as differential extension by color or by area, or by any other characteristic, or even randomly. For a preferred embodiment of this effect, a roughly linear starting pattern is repeated, essentially as described above. But, as the repetitions are laid down, successive repetitions are modified by fading out different colors at different rates. Or some color can be abruptly terminated after so many repetitions, an additional color after so many more repetitions, and so forth. This effect is illustrated inFIG. 4. InFIG. 4, repetition of an essentially linear representation of atarget image slice650 has resulted in a pattern of color bands. Also, successive repetitions can be slightly displaced parallel to the long axis of the slice, several stepping in one direction and then several stepping back, to present the slice extension in a wavy pattern. For an effect similar to repetition of a very narrowtarget image slice650, or of a linear representation of atarget image slice650, extension can be accomplished by physically smearing the ink of each image slice after (or during) printing.

Neither the discussion of kinds of target image slice extension nor the design choice descriptions should be taken as exhaustive.

Extended target image slices100 have to be organized for printing, which should be understood to mean any reasonable method of reproduction. Whether eachsubstrate200 is to be printed individually, or as part of a sheet or web, the order and orientation of the successively printed extended target image slices100 have to be determined. If the intent is to produce an assembledpuzzle500,substrates200 are best printed with extended image slices100 in sequence. However, it is preferred to presentpuzzle500 unassembled, so its extended target image slices100 should be printed in irregular, for example, not readily apparent order. Somepuzzles500 will also benefit by presenting the extended target image slices100 oppositely oriented in irregular order. That is especially important in such embodiments as those withslats400 ofFIG. 2D, where it is desirable to disguise the orientation of the slats by disconnecting the correct orientation of the information from the orientation of the butt seam on one face of theslat400. Also, forslats400 shown inFIG. 2D, or others, used in a two-sided puzzle500, extended target image slices100 of afirst target image600 and extended target image slices100 of asecond target image600 must be arranged so that eachslat400 will comprise, on opposite edges, extended target image slices100 from each of thetarget images600.

FIG. 5 diagrams printedweb substrates200 prior to cutting and folding. InFIG. 5A, successive extended target image slices100 are printed out of their original sequence. InFIG. 5B, successive extended target image slices100 are printed in an irregular sequence of orientation.FIG. 5A also shows the web as laterally perforated betweensuccessive substrates200.

Contrary to the diagram representation, one should not expect to find the slat sequence numbers onslats400 of a real puzzle.

Target image

600 can be any graphic image, simple or complex, realistic or not, in colors or not. However, to be useful,target image600, or at least a substantial portion of it, must be distinguishable as properly sequenced or not.Target images600 should recognize the unique physical structure of a slat puzzle. For example, a picture that includes a recognizable major element that crossesmany slats400 at an angle, may severely reduce a puzzle's difficulty. It should be noted that an adjustment of the angle of the slices can be helpful to make such artwork more useful; the artwork need not be square to the slat orientation.

While it is generally preferred that eachslat400 be the same length, the lengths of the slats can be divided, into equal segments or not, and identically to other slats or not and assembled into the same assembly box or adjacent boxes, or into one box divided into columns or other sections.

As shown inFIG. 6, an assembly box can be arranged, with or without a sloped side or internal wedge, to allow the slats to tilt, thereby offsetting each slat from the next to expose the faces of the slats, adjacent to the edges of the slats. With the slats tilted sufficiently away from an observer, the slat edges are hidden from view; there is no apparent distinction between a slat with printing on its edge and one without. The slats shown inFIG. 6 are numbered400/800 as either type can be used in such an embodiment.

Where the slats are so tilted in relation to one another, they can be printed only on their faces, adjacent to edges. That does not require folding of asubstrate200.FIG. 7A shows aslat800 comprisingtarget image slice650 onslat face802.FIG. 7B shows aslat800 with four edges of equal length and extended target image slices100 printed on portions offace802 adjacent to each edge. Expanded target image slices100 are shown to terminate short of the corners ofslat800 so they do not overlap at the corners. This is a design choice; expanded target image slices100 might instead be allowed to overlap at the corners, or be mitered at the corners.

Likewise, expanded image slices100 can be printed ontosubstrates200 that are then folded over the edges ofcores300 to formsquare slats400.

And, of course, other polygonal shapes can be used in the same manner.

Additionally, if the material ofcore300 is sufficiently porous, inks or dyes printed onto its face can be absorbed intoslat core300 and will be visible, without folding, atslat edge401 as well asslat face402 ofslat400.

FIG. 8 illustrates an embodiment ofslat puzzle500 includingslats800 manufactured identically to ordinary playing cards, which (after centuries of product improvement) are particularly comfortable to manipulate and, for a paper product, extremely durable.Slats800 are printed with slices of a target image (or target images), rather than (or in addition to) the mass market cardboard playing card faces (and/or backs). The target image slices are preferably, not necessarily, extended, as described above. It is known that playing cards are relatively heavy and slippery, so they readily distribute themselves according to gravity and other forces. If one rests a deck of cards on its edge on a flat surface, the opposite/top edge of the deck will remain flat, the cards distributed uniformly, as the cards are tilted substantially from the vertical orientation. A double deck (104 cards), set on a long edge and tilted, for example, 63½ degrees from vertical, can make an excellent face-printed, tilted-slat puzzle.

As the tilt forslats800 becomes more extreme, gravity no longer tends to enforce the uniform tilt and spacing ofslats800. It becomes easier forslat800 to lift and displace its neighbor.FIG. 9 illustrates anembodiment having slats800 supported atend801 of the stack bywedge25. For example,wedge25 can have a 26½ degree angle supporting the stack ofslats800 at a 63½ degrees. Forslats800 in a straight-sided assembly box50,slats800 may readily slide under one another, making it difficult to manually equalize the spacing of the card/slats. In this particular instance, control can be substantially facilitated by confiningslats800 between two opposing surfaces.FIG. 10 illustrates an embodiment having a second, inverted,wedge25, secured atend802 of stack ofslats800 which can be used to constrain the stack withslats800 filling the space betweenwedges25, thereby uniformity is automatically achieved in stack ofslats800.

Individual slats

800 can only be removed and repositioned by sliding them parallel to themselves. The size ofwedge25 can be reduced such that it bears against only part (preferably including the bottom edge) of the front face ofslat800, rather than covering most of the surface to allow easier removal and repositioning ofslats800.Inverted wedge25, of any extent, can be mounted to, or made of, resilient material, to allow manual displacement during manipulation ofslats800. Following is discussion of a face-printed, tilted-slat puzzle, to be manufactured substantially similar to a mass market cardboard jigsaw puzzle.

For this puzzle, 75 slices of 8×9½ inch, vertically/portrait oriented, target image are preferably, not necessarily, extended. Extending the image slices can provide increased printing and die-cutting tolerances, gives the user/assembler a better look, and make the slats more attractive.

For this example, image slices for a single target image are formatted for printing onto 8×⅞ inch slats, on a 27×22 inch sheet (typical of mass market cardboard jigsaw puzzles) to accommodate, with room to spare, three, 8 inch wide columns, each with twenty-five, ⅞ inch wide slats.

As described above, a 9½ inch high target image for this puzzle is divided into 75 slices for processing and printed to 75, 1/16 inch thick slats. The total thickness of the 75 slats is 4¾ inches. Tilting the slats 45 degrees would offset each slat by its 1/16 inch thickness, which would support a target image no more than 4¾ inches high. But, the target image for this puzzle is intended to be 9½ inches high, and the slices are each ⅛ inch. In order to produce an offset of ⅛ inch per slat, the slats must be tilted to (90−arctan 0.5=) 63 1/2 degrees from vertical.

With a design angle of 63½ degrees, and 75 relatively narrow slats, manual adjustment for uniform tilt is bothersome. Retaining these relatively stiff slats atend801 and end802 of a stack of slats800 (with wedge and inverted wedge) can be effective to enforce uniformity, but, as noted above, limits the degree of freedom with which the slats can be manipulated. With only wedge25 atend802, the top of slat stack ofslats800 control the tilt angle when in a smooth box,slats800 tend to slide about in the box, pushing each other out of alignment. Ifbox25 is provided with increased friction (as by adding a soft rubber pad inside the bottom of the box)slats800 resist being moved to their correct positions.

It is possible to take advantage of easy slat movement by assuring that the slats are biased to move to uniform position and orientation, as they come to rest.FIGS. 11A and 11B illustratesawtooth slat rack35, having preferably onetooth804 per slat800 (although two or several teeth per slat will sometimes be effective), appropriately angled to reflect the tilt for the desired offset. Slat rack35 can be used with stack ofslats800 urging, automatically produce uniform tilt and spacing in stack ofslats800, particularly with little manual where/whentop slat800 is supported by anappropriate wedge25. In this embodiment,wedge25 is integrated intoslat rack35 atend801 without constrainingopposite end802 of the stack. However, whenslats800 are removed (singly and in groups) for repositioning, slats below the break can tilt back into the break.

The term “sawtooth” is meant to include toothed, crenelated, crenate, crenulated, and other, regularly ordered support elements, having an integral number of repetitions per slat distance; that distance being determined by the actual slat thickness and the desired tilt angle. Regular order does not require that the tooth form be constant (or change regularly), but that is preferred. Regular order is not obviated by occasional anomalous teeth (regularly spaced or not), as might receive slats for a puzzle designed with occasional anomalous (e.g. particularly wide) slats, defining a skeleton into which narrower slats are interposed.

Slat rack35 incorporating aslat support wedge25 andteeth804 can have low manufacturing costs. A washboard type sheet,slat rack35, shown inFIG. 11B, (edges turned downward, so as not to present a hazard to fingers manipulating the slats) can be vacuum formed from thin, rigid, plastic sheet, such as commonly used for take-out food boxes and lids, and dropped intoassembly box50. A pair of sawtooth rails can be usedslat rack35, shown inFIG. 11A, each preferably incorporatingwedge25, that can be die cut along withslats800, from the same typical jigsaw puzzle blank (where the 75 slat pattern had room to spare). The pair of rails can be made to engage for support with holes in the sides of the box, or additional slat rack members can be die cut from the same puzzle blank. Die cutting the slat rack along with its puzzle, permits customized slat racks, e.g. with occasional anomalous teeth. An inexpensive slat rack is formed from a sheet of single faced corrugated cardboard with corrugations facing up in the bottom ofassembly box50.

A change in position of the sawtooth rails produces an even more stable configuration.

FIG. 12

shows slats

850 are provided withears851.Ears851 are short projections at the upper corners of the slats (that's at both ends of the target image slices).Ears851 are formed by removing, at each end of each slat, a narrow strip, for example ⅛ inch by preferably ⅔ of the slat width (i.e. the greater dimension visible at either end of the slat), as shown inFIG. 14.FIG. 14 shows a pattern for die-cutting that produces slats withears851 being ⅓ of the slat width, and waste only at the outside edges of the die. It will be appreciated that smaller ears (i.e. less than ⅓ the slat width) can be more stable, and are often preferred. Also, it is generally preferred to arrange printing layouts with slats arranged to avoid adjacent active slat edges, thereby greatly reducing the die cutting precision required. It is also generally preferred that, in such cases, rows of slats be separated, so as not to leave uncontrolled dropouts (i.e. so that the waste bits are connected to each other).

Witheared slats850, a durable slat rack can still be preferably die-cut from the puzzle blank. In an alternate embodiment as shown inFIG. 12, the puzzle box can act as a slat rack for further reducing manufacturing costs.Eared slats850 of this example are 7¾ inches long, and have a pair of ⅛ inch ears, for a total length of 8 inches.Eared slats850 are placed crosswise inbox60 that is slightly over 7¾ inches wide.Eared slats850 hang byears851 ontop edges852 of the sides ofbox60.Top edges852 of the sides ofbox60 are cut into a sawtooth to fit the thickness ofeared slats850, at the tilt angle that will produce the desired offset. This arrangement can ensure uniform slat spacing, but (unlesseared slats850 are delicately balanced about ears851) is not sufficient to urgeeared slats850 to uniformly align to that angle.Eared slats850 of this example are ⅞ inch wide and 1/16 inch thick. If the depth ofbox60 is calculated, or empirically determined, for the bottom edge of each hangingeared slat850 to contact the bottom ofbox60 wheneared slat850 is hanging at the desired angle,eared slat850 will therefore come to rest at that angle. In this example, the required depth ofbox60 from the root (lowest point) of the sawtooth, is ¼ of an inch. In practice, it isn't necessary for the box depth to be so limited; it's only necessary to support the bottom edges of the slats at a couple of points with parts of a slat rack structure, preferably die cut from the puzzle sheet.

With hangingeared slats850, the angle of each slat is individually controlled, so, when slats are removed for repositioning, there is no change in the tilt of slats above or below (upstream or downstream of) the gap. As shown inFIG. 13, with this element of stability, the eared slat configuration can be adequate in anassembly box50, without the additional spacing control afforded by the sawtooth. Eacheared slat850 is biased, by support ofears851 and the bottom ofassembly box50, to hang at the predetermined angle. Therefore, in an assembly box50 (or rack) that contains its design complement of slats, the slats will also fall into equal spacing.

Slats with ears that are simply rectangular projections at the ends of the upper edge of each slat can be inadvertently skewed, causing the slats to fall from the rails (or box edges) from which they hang. This can be a mild annoyance to the puzzle assembler and may limit the ways in which the puzzle can be handled, stored, and/or displayed.

This limitation can be overcome by extending the ears substantially beyond the slat rack, but that strategy does not resolve another limitation introduced by ears that are simply rectangular projections at the ends of the upper edge of each slat. The ears define the upper edges (those with the ears) and lower edges of the slats. Puzzle picture slices appear only at (and/or on) the upper edges. Accordingly, where rectangular slats allow complex challenges with picture elements on both long edges of each slat, slats with ears appear to be more limited.

Ears can be supplemented or reconfigured so that the slats are better retained on the support rails, while re-enabling two-edge puzzles.

It should be understood that face-printed, tilted slat puzzles with rectangular slats can have slices of eight different pictures; four of the pictures on the four edges of one face of the slats and the other four on the four edges of the opposite face of the slats. For the relatively slender slats of this example (i.e. those with two long edges and two insignificant edges) the number of pictures is reduced to four. For relatively slender slats with only a single active face (which are substantially more economical to produce) the number of pictures is reduced to two. A two-edge puzzle (with disparate slat sequences) can be a significantly greater challenge than a single-edge puzzle, particularly where the colors and patterns of the two pictures are similar.

FIGS. 15A,15B and16

show slats

875 that are similar toeared slats850. Rather than removing the lower corners of the ends of the slats, eachslat875 is provided with a pair ofslots852 extending from its bottom edge about two-thirds of the way to its top edge.Slat875 is thereby able to hang on a pair of support rails859, similar toeared slat850. Withslots852

engaging rails

859 ofassembly box50, or rails within or without the assembly box,slats875 are secure from slipping off the rails.

FIGS. 17 and 18 show reversible slats.FIG. 17 has a pattern ofslots852 attop edge856 andbottom edge857 ofslat875 that are 180 degrees rotationally symmetrical about the center ofslat875.FIG. 18 is similar, but material between the extreme slots and the ends ofslat875 has been removed to formears876. In each embodiment,top edge856 andbottom edge857 are indistinguishable. If support rails forslats875 in this assembly are positioned inassembly box50, one rail will be farther than the other from the centerline ofassembly box50.

FIG. 19 shows a variation, withslat portions854 extending beyondslots852 to formear lobes855.Ear lobes855 are shortened to reduce possible mechanical stress on the narrowest portion ofslat875.

FIGS. 20 and 21

show slats

875 with a plurality ofslots852.FIG. 20 shows a single-edged slat, preferred for embodiments with longitudinal adjustment;FIG. 21 shows a reversible slat variation. On a pair of support rails, theseslats875 can be shifted longitudinally.Puzzle500 built on a stack ofsuch slats850 can be far more challenging than one in which the slat stack has uniform edges (i.e. with no protruding slats).

Target images for mass market cardboard slat puzzles and tilted slat puzzles with longitudinal adjustment are preferably wider than the length of a slat by the distance of maximum longitudinal adjustment.FIG. 22 shows the relationship between atarget image600 and an assembled set of longitudinally displacedslats875. Eachslat875 carries a, preferably extended, image slice that appears along the full length of the slat.

A preferred completed slat stack will have half the slats, on average, shifted to the left and half shifted to the right (preferably in no particular order).

While the slats ofFIGS. 20 and 21 are to be adjusted incrementally, useful puzzles with infinite adjustment are possible. A mass market cardboard slat puzzle (i.e. with zero tilt angle; no offset) with infinite longitudinal adjustment can be nothing more than a stack of slats held together by rubber bands. Incremental adjustment in a mass market cardboard slat puzzle (or in some embodiments of tilted slat puzzles) can be controlled with very shallow slots engaging even a single rail.

As stated above, the manufacture of the puzzle of this example is virtually identical to that of mass market cardboard jigsaw puzzles. That includes usual choices of substrate materials, printing, and die-cutting methods. Jigsaw puzzle manufacture is mature and economical, readily available technology. For this example, ears and/or slots are preferably formed by the die that divides the sheet (or web) into slats.

In other embodiments, it might be preferred to form the ears and/or slots after the slats are separated (or if they were made separately). A simple die arrangement, such as used to punch binder holes and slots in printed materials, can be used to punch individual slats or groups of slats. An entire set of slats can be clamped into a rectangular block and the block sawn or routed in a direction perpendicular to the slats.

Any other suitable cutting method, including, but not limited to, lasers, water jets, and the like, can be used to form the slats, ears, and/or slots.

Support rails for eared and/or slotted slats can be the edges of the assembly box or inserted within the assembly box. A pair of cardboard strips, each on edge and straddled by slat slots, are sufficient to control the slats in cooperation with the surface on which the strips and slats rest. A preferred rail arrangement for economical cardboard puzzles is a simple rectangle folded from a strip of chipboard, placed on edge on the bottom of the assembly box, and secured inside the ends of the box, adjacent to the top and bottom of the slat stack. For a little more stability the rails can be the edges of a narrower box, inside the assembly box.

It is often preferred to flare/widen the open end ofslots852, to allow more casual placement of the slats onto the support rails, as shown inslat875 ofFIG. 16.

In most embodiments, it is preferred that the rails on which the slats are supported be somewhat thinner than the slots to broaden manufacturing tolerances and to help insure free movement of the slats.

The preferred proportions and size for this example particularly support the use of slat patterns that are extensions by repetition, as shown inFIG. 3C, of each slat's associated image slice. However, it is here preferred to introduce an additional effect to make each slat pattern somewhat harder to comprehend as part of the target image; thereby increasing the puzzle challenge. These patterns are also incidentally attractive.

FIG. 23 shows slatpatterns100, generated by repetition from a slice of atarget image600. However, in these patterns, every second repetition is inverted top to bottom (perpendicular to its long axis). The top strip of the slat pattern100A is a copy of the fourth slice of thetarget image600; the second strip of that pattern is the same slice, inverted top to bottom; the third strip is upright; the fourth inverted.

In practice, it is advisable to add an additional strip at the top; that is so, if the top edge of a slat is cut imprecisely, the pattern will nevertheless continue to the edge of the slat. For the same reason, if the slat pattern is to continue to the bottom edge of the slat, an additional strip should also be added at the bottom ofslat pattern100.

If the slats are carefully manufactured, so that the top edge of each slat falls precisely at the top edge of an upright strip, the assembled target image will be precisely rendered. If the slats are die cut above or below that line, the assembled target image will appear textured (increasingly so, with greater deviation from the line).

The manufacturing scenario for this example (i.e. essentially identical to mass market cardboard jigsaw puzzle manufacturing) uses a single die to cut all the puzzle pieces from a single sheet of cardboard, to which is mounted a printed paper sheet. Mass market cardboard printing tolerances (which, e.g., accommodate fine registration of colors over large areas) easily assure quite precise placement of slat patterns on the printed paper sheet. Modern die manufacturing ordinarily produces quite precise knife placement. Registration of the die with the printing is more difficult to control, particularly as production speeds are increased.

Slat patterns described herein are capable of producing a continuous, non- textured, assembled target image; and it exhibits a vibrant, attractive, visual effect.

Imprecise registration of these patterns produces texture in the assembled target image that may not be desirable. However, precision in the printing and in the die insure that each slat pattern will be positioned virtually identically on each slat. Where precision cutting is impractical, that consistency supports various approaches to controlling the degree and character of the texture (i.e. discontinuities in the resulting assembled image) of a target image on an assembled slat puzzle.

One approach, shown by the relationship between slat patterns100A and100B ofFIG. 23, is to use an almostidentical slat pattern100 structure on each slat, but to modify theslat pattern100 for every second slat, by beginning with an inverted band. Slat pattern100B, generated from the fifth slice oftarget image600, has an upright second band, rather than top band. The two slat patterns,100A and100B, therefore follow the modified sequence. It should be noted that, while this approach limits the overall degree of discontinuity, it also imposes a minimum level of discontinuity.

Another approach, to reduce the effect of an imprecise die strike, is to compress the inverted bands and expand the upright bands. Slat pattern100C of

FIG. 23 is so derived from slat pattern100A.

Production and shipping costs can be reduced (or play value increased) for some configurations of face-printed, tilted-slat puzzles (particularly those with die cut slats). Slats with broad faces are preferred for some embodiments; particularly useful are square slats, printed with slices of four different images (for example, four views of a single 3D scene). Also contemplated are two sided slats with slices of eight different images, or with the same four images on each side, but with one side color coded at its corners to distinguish the elements of each of the four pictures.

Whatever the artwork, square (or otherwise broad) slats, while relatively easy to manipulate, use up a lot of coated/laminated, printed cardboard. For conventional (or unconventional) edge-printed slat puzzles that would be a substantial limitation. For face-printed, tilted-slat puzzles it's an opportunity. The center of a square slat is not necessary to the operation of the puzzle. For example, 6 inch square slats could have 2 inch square holes punched at their centers without appreciably affecting manipulation of the puzzle.

For the cost of artwork preparation and another slight increase in die cost, the extraneous 2 inch squares can be additional puzzles. With the same tilt angle, aspect ratio of the large and small target images is maintained by reducing the number of slats for the small puzzle. In this example, one third of the 2 inch square slats produced from a 6 inch square puzzle will produce proportions similar to the six inch puzzle. Thus, for each 6 inch puzzle with, for example, 75 slats, three 2 inch puzzles with 25 slats each will be manufactured at almost no cost, to be included as a bonus, or packaged and sold separately.

For the cost of artwork preparation and a slight increase in die cost, two four inch, 37 piece puzzles can be added. One four inch piece will be left over. In some printing environments, production can be organized to produce another four inch bonus puzzle with the production of every thirty-seven, six inch puzzles. Alternatively, a number of slats like 60, 72, 84, 96, or 120 can be used.

FIG. 24 shows a die cut pattern forslat810 withinslat805, which is withinslat800.

The above-described examples use a 63½ degree tilt, producing an offset that is double the slat thickness. Various degree tilt can be used. The 63½ degree tilt was chosen to produce a useful/pleasing aspect ratio in a puzzle based on a double deck of playing cards, and to stay within the production parameters of a single typical mass market cardboard jigsaw puzzle. For some other embodiments, tilt angle for an offset triple the slat thickness is about (90−arctan 1/3 =) 71½ degrees, and tilt angle to produce a quadruple thickness offset is about (90−arctan ¼=) 76 degrees.

It is to be understood that the above described embodiments are illustrative of only a few of the many possible specific embodiments that can represent applications of the principles of the invention. Numerous and varied other arrangements can be readily devised in accordance with these principles by those skilled in the art, without departing from the spirit and scope of the invention.

Claims

1. A slat puzzle comprising a plurality of slats, each slat comprising on at least part of a face adjacent to an edge thereof an image slice of a target image, wherein the slats are offset to reveal the image slices.

2. The slat puzzle ofclaim 1 further comprising:

a holder for holding the slats,

wherein elements of the target image elements are made visible by offsetting each of the slats against an adjacent slat, the offset being achieved by tilting each of the slats in the holder and wherein the slats are constrained by interaction between the slats and the holder, to tend to fall into essentially uniform tilt and spacing.

3. The slat puzzle ofclaim 2 wherein the holder comprises at least two parallel rails and at least one track; and wherein each of the slats is suspended on the rails and bears against the track, thereby determining the angle of repose of the slat.

4. The slat puzzle ofclaim 3 wherein the holder is an uncovered box, the top edges of two sides of the box being the rails, and the bottom of the box being the track.

5. The slat puzzle ofclaim 3 wherein each of the slats comprises at least two projections at opposite ends of an upper part of each of the slats; the projections resting upon the rails.

6. The slat puzzle ofclaim 5 wherein the projections are integral with the slat.

7. The slat puzzle ofclaim 5 wherein at least one of the projections extends beyond and at least partially over the rail, thereby defining a slot that is generally perpendicular to the upper edge of the slat.

8. The slat puzzle ofclaim 7 wherein the projections are integral with the slat.

9. The slat puzzle ofclaim 7 comprising at least one slot extending from each of two edges of the slat.

10. The slat puzzle ofclaim 9 comprising at least three slots extending from one edge of the slat.

11. A slat puzzle wherein each of the slats comprises at least two slots; the slots engaging with at least one rail, to enable each slat to be retained in at least two alternate longitudinal positions.

12. The puzzle ofclaim 1, wherein the image slices are extended generally perpendicular to the edges, along the faces of the slats.

13. A method of making a slat type picture puzzle, comprising the steps of:

a) preparing artwork for a target image;

b) dividing the target image into a plurality of slices;

c) extending each of said slices, generally perpendicular to its long axis; and

d) applying each of the extended slices to an edge and onto at least one face of a slat.

14. The method ofclaim 13, wherein each of the extended slices is applied to the slat by:

printing the extended slice onto a substrate; and

folding the substrate to form the slat.

15. The method ofclaim 13, wherein the succession of printed, extended image slices is irregular.

16. The method ofclaim 15, wherein successively printed, extended image slices are oppositely oriented in an irregular order.

17. The method ofclaim 15, wherein successively printed, extended image slices are irregularly out of sequence.

18. The method ofclaim 17, wherein substrate material is perforated between adjacent substrates.

19. A picture puzzle comprising:

a plurality of slats, each of the slats bearing on at least part of an edge a slice of a target image; wherein a typical slat comprises a substrate that is folded roughly parallel to the long axis of the extended image slice to form the edge of the slat bearing the slice.

20. The puzzle ofclaim 19, wherein a typical slat comprises a substrate that is folded roughly parallel to the long axis of the extended image slice; and wherein at least two folds form an edge of the slat.