Letter Cubes are a versatile building block system comprised of a series of three-dimensional fonts made with metal, plastic, ceramic, glass and other materials that magnetically, with knobs, hooks, snaps and tubes (and combinations of these and other interfaces) assemble into walls, buildings and other structures that communicate messages (Letter Cubes are referred to herein as the “Invention”).
Rudimentary three-dimensional fonts have served as toys that children play with.
Ceramic tiles have been used on buildings to communicate messages while not being a building block system of their own.
The Invention is a building block system that empowers builders to make architectural statements with their buildings while making verbal statements with their buildings at the same time.
With a system of tubes within the font building blocks builders can lay wires, pipes, air ducts and transport building materials while also inserting additional reinforcement beams or beams that lock blocks together.
The font building blocks are stable when stacked on, or next to, each other to form words and sentences that also build objects, toys and buildings.
The Invention can be hollow, allowing the pieces to float.
The Invention comes in a box that is itself a building block that can be assembled and disassembled, thereby eliminating packaging waste.
BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS
FIG. 1 is upper case and lower-case letters “a” that also form equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIGS. 2 through 26 are the remaining letters in the alphabet (letters “b” through “z” that have the same features as the letter “a” in FIG. 1.
FIG. 27 is upper case “A,” “J” and “R” that also form equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIG. 28 is upper case “A,” “M,” “S,” and the number “2” that also form equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIG. 29 is upper case “B,” “C” and “D” that also form equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIG. 30 is upper case “B,” “P” and “E” that also form equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIG. 31 is upper case “K” and “E” that also form equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIG. 32 is upper case “L,” “M,” “N,” and “Z” that also form equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIG. 33 is upper case “C,” “O” and “Q” that also form equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIG. 34 is upper case “H,” “T” and “Y” that also form equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIG. 35 is upper case “Z,” “N” and a blank surface (that serves as a space between letters of different words) that also form equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIG. 36 is upper case “C,” “O” and the number “2” that also form equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIG. 37 is upper case “U,” “V” and “X” that also form equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIG. 38 is the number “O” in equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIGS. 39 through 47 follow the same logic as FIG. 38 except for numbers 2 through 9.
FIG. 48 is a six-sided equilateral cube with rounded corners whose sides also form each of the six numbers on a dice (i.e., numbers zero through six).
FIG. 49 is also a six-sided equilateral cube, but with pointed corners, whose sides also form each of the six numbers on a dice (i.e., numbers zero through six).
FIG. 50 is the punctuation symbols “!” “)” and “˜” in equilateral cubes that are stable building blocks with recesses for magnets and smooth surfaces.
FIG. 51 is the punctuation symbols “!” “(” and “−” in equilateral cubes that are stable building blocks with recesses for magnets and smooth surfaces.
FIG. 52 is the punctuation symbols “$” “?” and “−” in equilateral cubes that are stable building blocks with recesses for magnets and smooth surfaces.
FIG. 53 is the punctuation symbols “!” “?” and “˜” in equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIG. 54 is the punctuation symbols “!” “$” “˜” and “−” in equilateral cubes that are stable building blocks with recesses for magnets and smooth surfaces.
FIG. 55 is the punctuation symbols “%” “&” and “<” in equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIG. 56 is the punctuation symbols “.” “%” and “>” in equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIG. 57 is the punctuation symbols “{circumflex over ( )}” “,” and “&” in equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIG. 58 is the punctuation symbols “%” “>” “{circumflex over ( )}” and “,” in equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIG. 59 is the punctuation symbols “(” “+” and “=” in equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIG. 60 is the punctuation symbols “!” “?” and “˜” in equilateral cubes that are stable building blocks with male and female knob interfaces, recesses for magnets and smooth surfaces.
FIGS. 61 through 69 are punctuation symbols that follow the same building-block logic as the punctuation symbols in FIGS. 50 through 33.
FIG. 70A is a hollow knob that can unite two pieces that have female knob interfaces.
FIG. 70B is a top view of FIG. 70A.
FIG. 70C is a side profile view of FIG. 70A.
FIG. 71A is a curved hollow knob that can unite two pieces that have female knob interfaces.
FIG. 71B is a side view of FIG. 71A.
FIG. 71C is another side view of FIG. 71A.
FIG. 71D is a bottom view of FIG. 71A.
FIG. 72A is a piece with six knobs sticking out, each at perpendicular angles to the other knobs.
FIG. 72B is another view of FIG. 72A.
FIG. 72C is a side profile view of FIG. 72A.
FIG. 73A is a knob on a surface that can make a female knob interface look smoother.
FIG. 73B is a side profile view of FIG. 73A.
FIG. 73C is a view of the bottom of FIG. 73A.
FIG. 74 is a pole that goes through the hollow male and female knobs on the other pieces to reinforce or to hold them together.
FIG. 75A is a square with a female knob interface that can go on top of male knobs to make them look smoother.
FIG. 75B is a profile view from the top of FIG. 75A.
FIG. 76A is similar to FIG. 75A except it is built with less material because the edges are rounded.
FIG. 76B is a top profile view of FIG. 76A.
FIG. 77A is similar to FIG. 75A except it has lower height.
FIG. 77B is a top profile view of FIG. 77A.
FIG. 78A is a side profile view of FIG. 78B.
FIG. 78B is a female knob interface with a spherical and pointed surface on two ends of the piece.
FIG. 79A is a female knob interface with a spherical top that extends down to a square base.
FIG. 79B is a bottom view of FIG. 79A.
FIG. 79C is a profile view from a side of FIG. 79A.
FIG. 80A is a side profile view of FIG. 80B.
FIG. 80B is similar to FIG. 79A except it is a male knob.
FIG. 81A is similar to FIG. 78A except the surface is fully spherical and is not pointed.
FIG. 81B is a top view of FIG. 81A.
FIG. 82A is a side profile view of FIG. 82B.
FIG. 82B is similar to FIG. 81A except it is a male knob.
FIG. 83A is a female knob piece with a conical pointed top.
FIG. 83B is a bottom view of FIG. 83A.
FIG. 84A is another view of FIG. 84B. FIGS. 84A through 116A are additional basic building blocks with male and female knobs that assemble into structures of basic shapes like spheres, slanted or curved sides, etc.
FIG. 84B is a basic building block with one or more male knobs.
FIG. 85A is a basic building block with a male and female knob.
FIG. 85B is another view of FIG. 85A.
FIG. 86A is a basic building block with female knobs.
FIG. 86B is another view of FIG. 86A.
FIG. 87A is a basic building block with female knobs.
FIG. 87B is another view of FIG. 87A.
FIG. 88A is a basic building block with female knobs.
FIG. 88B is another view of FIG. 88A.
FIG. 89A is a basic building block with female knobs.
FIG. 89B is another view of FIG. 89A.
FIG. 90A is a basic building block with female knobs.
FIG. 90B is another view of FIG. 90A.
FIG. 91A is a basic building block with male and female knobs. FIGS. 91A-116B are basic building blocks with male and female knobs.
FIG. 91B is another view of FIG. 91A.
FIG. 92A is a basic building block with male knobs.
FIG. 92B is a profile view from the side of FIG. 91A.
FIG. 93A is a basic building block with male and female knobs.
FIG. 93B is another view of FIG. 93A.
FIG. 94A is a basic building block with male and female knobs.
FIG. 94B is a side profile view of FIG. 94A.
FIG. 95A is a basic building block with female knobs.
FIG. 95B is a side profile view of FIG. 95A.
FIG. 96A is a basic building block with a male knob.
FIG. 96B is another view of FIG. 96A.
FIG. 96C is another view of FIG. 96B.
FIG. 97A is a basic building block with male and female knobs.
FIG. 97B is another view of FIG. 97A.
FIG. 98 is a basic building block with female knobs.
FIG. 99A is a basic building block with male and female knobs.
FIG. 99B is a side profile view of FIG. 99A.
FIG. 100 is a basic building block with male knobs.
FIG. 101A is a basic building block with hollow male knobs.
FIG. 101B is a side profile view of FIG. 101A.
FIG. 102A is a basic building block with female knobs.
FIG. 102B is another view of FIG. 102A.
FIG. 103A is a basic building block with female knobs.
FIG. 103B is another view of FIG. 103A.
FIG. 104A is a basic building block with female knobs.
FIG. 104B is another view of FIG. 104A.
FIG. 105A is a basic building block with one or more male female knobs.
FIG. 105B is another view of FIG. 105A.
FIG. 106A is a basic building block with female knobs.
FIG. 106B is another view of FIG. 106A.
FIG. 107A is a basic building block with female knobs.
FIG. 107B is another view of FIG. 107A.
FIG. 108A is a basic building block with male knobs.
FIG. 108B is another view of FIG. 108A.
FIG. 108C is a view of the back side of FIG. 108A.
FIG. 109A is a basic building block with a female knob.
FIG. 109B is a basic building block with a male knob.
FIG. 110A is a basic building block with female knobs.
FIG. 110B is another view of FIG. 110A.
FIG. 111A is a basic building block with female knobs.
FIG. 111B is another view of FIG. 111A.
FIG. 112A is a basic building block with female knobs.
FIG. 112B is another view of FIG. 112A.
FIG. 113A is a basic building block with male knobs.
FIG. 113B is another view of FIG. 113A.
FIG. 114A is a basic building block with male knobs.
FIG. 114B is another view of FIG. 114A.
FIG. 115A is a basic building block with female knobs.
FIG. 115B is another view of FIG. 115A.
FIG. 116A is a basic building block with a male knob.
FIG. 116B is another view of FIG. 116A.
FIG. 117A is a stick with hollow cube protrusions that also have a dovetail shape.
FIG. 117B is a profile view from aside of FIG. 117A.
FIG. 118A is demonstration of how FIG. 117A fits into itself reversibly in a perpendicular arrangement (FIG. 118A) and in horizontal arrangements in an off-set manner (FIG. 118B) and in a fully aligned manner (FIG. 118C).
FIG. 118B is a demonstration of how FIG. 117A fits into itself in a horizontal arrangement in an off-set manner.
FIG. 118C is a demonstration of how FIG. 117A fits into itself in a fully aligned manner.
FIG. 119A is a building block with female knobs. FIGS. 119 through 131 are male and female knob building blocks in a mostly cylindrical shape.
FIG. 119B is another view of FIG. 119A.
FIG. 120A is a building block with female knobs.
FIG. 120B is a profile view from an end of FIG. 120A.
FIG. 121A is a building block with female knobs.
FIG. 121B is a profile view from an end of FIG. 121A.
FIG. 122A is a building block with female knobs.
FIG. 122B is a profile view from an end of FIG. 122A.
FIG. 123A is a building block with female knobs.
FIG. 123B is a different view of FIG. 123A.
FIG. 124A is a building block with female knobs.
FIG. 124B is a different view of FIG. 124A.
FIG. 125A is a is a building block with a male knob and female knobs.
FIG. 125B is a different view of FIG. 125A.
FIG. 126A is a building block with female knobs.
FIG. 126B is a different view of FIG. 126A.
FIG. 126C is a different view of FIG. 126A.
FIG. 127A is a building block with a male and female knob.
FIG. 127B is a profile view from the side of FIG. 127A.
FIG. 127C is a view from the bottom of FIG. 127A.
FIG. 127D is a view from the top of FIG. 127A.
FIG. 127E is another view from the bottom of FIG. 127A.
FIG. 128A is a building block with a male and female knob.
FIG. 128B is a close-up view of the male knob on FIG. 128A.
FIG. 129A is a building block with male knobs.
FIG. 129B is another view of FIG. 129A.
FIG. 130A is a building block with a male and female knob.
FIG. 130B is another view of FIG. 130A.
FIG. 131A is a building block with male knobs.
FIG. 131B is another view of FIG. 131A.
FIGS. 132A through 138A are cylinder cubes (their height is the same as their diameter) that efficiently build three dimensional shapes by fitting into itself with knobs, hooks and screws.
FIG. 132A is a top side view of a cylinder cube.
FIG. 132B is a side profile view of FIG. 132A.
FIG. 133A is another cylinder cube.
FIG. 133B is another view of FIG. 133A.
FIG. 134A is a cylinder cube.
FIG. 134B is another view of FIG. 134A.
FIG. 135A is a profile view of FIG. 135B.
FIG. 135B is another cylinder cube.
FIG. 136A is a close-up view of the hook on FIG. 136B.
FIG. 136B is a cylinder cube with a hook at the front.
FIG. 137A is another cylinder cube.
FIG. 137B is another view of FIG. 137A.
FIG. 137C is a close-up view of the left side of FIG. 137A.
FIG. 137D is another view of FIG. 137A.
FIG. 137E is a view of an end of FIG. 137A.
FIG. 137F is another view of an end of FIG. 137A.
FIG. 138A is a panel with a knob on it that gives constructions made with cylinders in FIGS. 132A through 138A flatter surfaces.
FIG. 138B is a profile view from the bottom of FIG. 138A.
FIG. 139A is a profile view of a side of FIG. 139B. FIGS. 139A through 191A are basic building blocks with the same general features as those in FIGS. 70A through 116A except that they are mostly eight times larger by being twice the length, height and depth as the objects in FIGS. 70A through 116A.
FIG. 139B is a basic building block.
FIG. 140A is a profile view of FIG. 140B.
FIG. 140B is another basic building block.
FIG. 141A is a profile view of FIG. 141B.
FIG. 141B is another basic building block.
FIG. 142A is another basic building block.
FIG. 142B is another view of FIG. 142A.
FIG. 143A is another basic building block.
FIG. 143B is another view of FIG. 143A.
FIG. 143C is another view of FIG. 143A.
FIG. 144A is another basic building block.
FIG. 144B is a profile view from the side of FIG. 144A.
FIG. 145A is another basic building block.
FIG. 145B is a profile view of FIG. 145A.
FIG. 146A is another basic building block.
FIG. 146B is a near-profile view of FIG. 146A.
FIG. 147A is another basic building block.
FIG. 147B is another view of FIG. 147A.
FIG. 148A is a basic building block.
FIG. 148B is another view of FIG. 148A.
FIG. 149A is a basic building block.
FIG. 149B is another view of FIG. 149A.
FIG. 150A is a basic building block.
FIG. 150B is another view of FIG. 150A.
FIG. 151A is a basic building block.
FIG. 151B is another view of FIG. 151A.
FIG. 152A is a basic building block.
FIG. 152B is another view of FIG. 152A.
FIG. 153A is a basic building block.
FIG. 153B is another view of FIG. 153A.
FIG. 154A is a basic building block.
FIG. 154B is a profile view of FIG. 154A.
FIG. 155A is a basic building block.
FIG. 155B is a profile view of an open side of FIG. 155A.
FIG. 156A is a basic building block.
FIG. 156B is a profile view of an open side of FIG. 156A.
FIG. 157A is a basic building block.
FIG. 157B is another view of FIG. 157A.
FIG. 158A is a basic building block.
FIG. 158B is another view of FIG. 158A.
FIG. 159A is a basic building block.
FIG. 159B is another view of FIG. 159A.
FIG. 160A is a basic building block.
FIG. 160B is another view of FIG. 160A.
FIG. 161A is a basic building block.
FIG. 161B is another view of FIG. 161A.
FIG. 162A is a basic building block.
FIG. 162B is another view of FIG. 162A
FIG. 162C is a side profile view of FIG. 162A.
FIG. 163A is a basic building block.
FIG. 163B is another view of FIG. 163A.
FIG. 163C is a side profile view of FIG. 163A.
FIG. 164A is a basic building block.
FIG. 164B is another view of FIG. 164A.
FIG. 164C is a side profile view of FIG. 164A.
FIG. 165A is a basic building block.
FIG. 165B is another view of FIG. 165A.
FIG. 165C is another view of FIG. 165A.
FIG. 166A is a cylinder for building. FIGS. 166A through 191A are cylinders that serve as transport conduits for smaller pieces to move through the system to enable objects and structures to be built from within the object itself.
FIG. 166B is another view of FIG. 166A.
FIG. 166C is a profile view from the side of FIG. 166A.
FIG. 167A is a cylinder for building.
FIG. 167B is another view of FIG. 167A.
FIG. 167C is a side profile view of FIG. 167A.
FIG. 167D is another view of FIG. 167A.
FIG. 168A is a transport cylinder.
FIG. 168B is a side view of FIG. 168A.
FIG. 168C is another view of FIG. 168A.
FIG. 169A is a transport cylinder.
FIG. 169B is a profile view from an open end of FIG. 169A.
FIG. 170A is a transport cylinder.
FIG. 170B is a profile view from the side of FIG. 170A.
FIG. 171A is a transport cylinder.
FIG. 171B is a profile view of FIG. 171A.
FIG. 172A is a transport cylinder.
FIG. 172B is a profile view of FIG. 172A.
FIG. 173A is a transport cylinder.
FIG. 173B is a profile view of FIG. 173A.
FIG. 174A is a transport cylinder.
FIG. 174B is another view of FIG. 174A.
FIG. 174C is a profile view from an open side of FIG. 174A.
FIG. 175A is a cylinder transport.
FIG. 175B is a profile view from an open side of FIG. 175A.
FIG. 176A is a transport cylinder.
FIG. 176B is a profile view from an open end of FIG. 176A.
FIG. 176C is another view of FIG. 176A.
FIG. 177A is a cylinder transport.
FIG. 177B is another view of FIG. 177A.
FIG. 178A is a cylinder transport.
FIG. 178B is another view of FIG. 178A.
FIG. 178C is another view of FIG. 178A.
FIG. 179A is a profile view of an open side of FIG. 179B.
FIG. 179B is a cylinder transport.
FIG. 180A is a profile view of an open side of FIG. 180B.
FIG. 180B is another transport cylinder.
FIG. 181A is a transport cylinder.
FIG. 181B is another view of FIG. 181A.
FIG. 181C is another view of FIG. 181A.
FIG. 181D is a profile view from a side of FIG. 181A.
FIG. 181E is a profile view from the side of a modified FIG. 181A.
FIG. 182A is a profile view from an open side of FIG. 182B.
FIG. 182B is another cylinder transport.
FIG. 183A is a profile view of the side of FIG. 183B.
FIG. 183B is a cylinder transport.
FIG. 184A is a profile view from a side of FIG. 184B.
FIG. 184B is a transport cylinder.
FIG. 185A is a profile view from a side of FIG. 185B.
FIG. 185B is a transport cylinder interface.
FIG. 186A is a profile view of FIG. 186B.
FIG. 186B is a transport cylinder interface.
FIG. 187A is a transport cylinder interface.
FIG. 187B is another view of FIG. 187A.
FIG. 188A is a profile view of FIG. 188B.
FIG. 188B is a cylinder interface.
FIG. 189A is a basic building block.
FIG. 189B is another view of FIG. 189A.
FIG. 190A is a basic building block.
FIG. 190B is another view of FIG. 190A.
FIG. 191A is a basic building block.
FIG. 191B is another view of FIG. 191A.
FIGS. 192A and 193A are longer versions of the prior pieces that form a beam to assemble structures with more stability.
FIG. 192A is a basic beam building block.
FIG. 192B is a profile view of FIG. 192A.
FIG. 193A is a basic beam building block.
FIG. 193B is another view of FIG. 193A.
FIG. 193C is a profile view of FIG. 193A.
FIG. 193D is another view of FIG. 193A.
FIG. 194A is a profile view of FIG. 194B.
FIG. 194B is like FIGS. 192A and 193A except it has a hook on the end that hooks on to female knob openings to have more grip when building structures.
FIGS. 195A through 205A are beams, panels, rounded corners and related pieces that assemble into a box that carries the rest of the pieces of the Invention.
FIG. 195A is a profile view of FIG. 195B.
FIG. 195B is a rounded corner.
FIG. 195C is another view of FIG. 195B.
FIG. 196A is a beam that assembles into a box.
FIG. 196B is a view from an end of FIG. 196A.
FIG. 197A is a close-up view of an end of FIG. 197B.
FIG. 197B is a profile view of a beam.
FIG. 198A is a profile view of a beam.
FIG. 198B is a close-up view of an end of FIG. 198A.
FIG. 199A is a profile view of a panel.
FIG. 199B is another profile view of a panel.
FIG. 200 is a view of a panel.
FIG. 201A is a panel.
FIG. 201B is another view of FIG. 20I A.
FIG. 201C is a profile view from a side of FIG. 201A.
FIG. 202A is a piece that assembles into a box.
FIG. 202B is another view of FIG. 202A.
FIG. 203 is a pole that assembles into a box.
FIG. 204A is a panel that assembles into a box.
FIG. 204B is a profile view of FIG. 204A with a pole inserted to partially assemble into a box.
FIG. 205A is a profile view of a panel.
FIG. 205B is another profile view of FIG. 205.
FIGS. 206A-206X are different views of the box made from pieces in FIGS. 195A through 205A in various stages of assembly and use (the box can be secured shut, or its door can be opened).
FIG. 206A is a view of a partially assembled box.
FIG. 206B is a profile view of FIG. 206A.
FIG. 206C is a view of a partially assembled box.
FIG. 206D is a profile view of FIG. 206E
FIG. 206E is a view of a partially assembled box.
FIG. 206F is a view of the inside of a partially assembled box.
FIG. 206G is a close-up near profile view of a side of a partially assembled box.
FIG. 206H is a close-up view of a partially assembled box.
FIG. 206I is a close-up view of the inside and outside of a partially assembled box.
FIG. 206J is a close-up view of an inside corner of a partially assembled box.
FIG. 206K is another close-up view of an inside corner of a partially assembled box.
FIG. 206L is a view of FIG. 206K except with a panel closing a part of the box.
FIG. 206M is a profile view of the assembled box.
FIG. 206N is a view of a partially assembled box.
FIG. 206O is a close-up view of an outside part of the assembled box.
FIG. 206P is a profile view of the assembled box.
FIG. 206Q is a profile view of the assembled box.
FIG. 206R is a view of an assembled box with one panel partially open.
FIG. 206S is a view of a partially assembled box with a panel removed.
FIG. 206T is a view of an assembled box with a panel open.
FIG. 206U is a close-up view of FIG. 206T from a different angle.
FIG. 206V is a profile view of an assembled box.
FIG. 206W is a view of an assembled box.
FIG. 206X is another view of an assembled box.
FIGS. 207A-207G contain examples of how the cubes with letters can be assembled to form the phrase “LETTER CUBES” and how additional pieces can be used to extend and reinforce words (see, for example, FIG. 207E).
FIG. 207A is a profile view letters assembled to spell “LETTER CUBES.”
FIG. 207B is another view of FIG. 207A.
FIG. 207C is another view of FIG. 207A.
FIG. 207D is another view of FIG. 207A.
FIG. 207E is a close-up view of FIG. 207A with additional pieces.
FIG. 207F is a close-up profile view of FIG. 207A with the additional pieces shown in FIG. 207E.
FIG. 207G is a full view of the piece shown in FIG. 207F.
The Invention is a building system using rigid materials (like ceramics, glass and cast iron) and flexible materials (like rubber and plastic) to build structures that also have phrases in the building blocks.
The Invention is also a toy set that helps children learn the alphabet and learn how to spell and build things at the same time.
The Invention is a game set whose pieces can be arranged in three dimensions, which is a development beyond existing game sets that use only two dimensions. The Invention requires players to take into account balance and structural integrity as they build words vertically and horizontally.
Those knob holes, which when connected throughout the Invention comprise a lattice, are also conduits for reinforcement beams, wires, pipes, pieces that lock or latch pieces together, and for vehicles or tubes that carry additional pieces, goods, or people throughout structures.
Every piece also can be magnetized so that all surfaces (whether knobs or flat surfaces) can have positive charges on or near locations with positive protrusions on the pieces and negative charges on and near the places with indentations. With this combination of positive and negative charges, the system can be assembled magnetically, even if there are fully flat surfaces involved.
For example, when made of metal it can be placed face up on the floor to convey a message and to be a grate that provides traction, allows water to settle, and that can be a metal rug that people can clean their shoes on. Element 6 is a more bulky and more stable version of the simple font in element 1.
The box has a door that opens. It is made up of the panel with rounded edges that is FIG.