1. The Field of the Invention
The present invention relates to toy building sets, particularly building sets including a plurality of blocks to be indirectly magnetically and/or frictionally coupled together.
2. The Relevant Technology
Various building sets have been used by children and others for decades for amusement and learning. Sets of blocks include a plurality of variously configured blocks that allow a user to stack the blocks on top of one another in order to form various structures or buildings. Stacking configurations that can be achieved are often limited as a result of gravity.
Other building sets have provided magnets sealed within blocks (e.g., U.S. Publication No. 2010/0242250), and multi-shaped non-metallic bodies employing disc shaped magnets so that two adjacent bodies may be magnetically connected together (e.g., U.S. Pat. Nos. 6,749,480 and 5,746,638). U.S. Pat. No. 7,413,493 describes toy magnetic building blocks including a block, a casing affixed to the block, and a magnet within the casing. The magnet allows connections to be made with other similar blocks. One embodiment may also include connectors with a collar to mechanically augment magnetic coupling of the blocks, in which narrowed ends of each block are received within opposite halves of the collar.
Such building systems are severely limited in their ability to build relatively realistic building structures such as those employing post and beam construction in which elongate blocks can be secured to one another in an erector like configuration, but in which connections can be more easily achieved (e.g., by a child between about 4 to about 8). As such, even with existing magnetic building systems, there remain difficulties to be overcome.
To further clarify the above a more particular description of the disclosure will be rendered by reference to specific examples that are illustrated in the appended drawings. It is appreciated that these drawings depict only typical examples and are therefore not to be considered limiting. The examples will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:
Together with the following description, the figures demonstrate non-limiting features of exemplary devices and methods. The same reference numerals in different drawings represent similar, though not necessarily identical, elements.
The present invention is directed to building sets including a plurality of blocks and a plurality of clips configured to frictionally engage one or more of the blocks. The clips include a magnet enclosed within the clip, which facilitates coupling of various blocks (e.g., elongate “post” and “beam” type blocks) together (with a clip in between) in various configurations not possible when stacking blocks alone (e.g., arches, bridges, trusses, eaves, girders, posts, beams, and other structures and buildings) as a result of the strength of the magnetic coupling. The system allows connection of non-magnetic bodies (i.e., the blocks) into simulated life-like structures such as those noted above through the use of magnetically coupling clips that frictionally engage the blocks. In addition, because the connection between the block and clip is friction based, a high degree of freedom is available in placement of the clips (e.g., anywhere along a side, end, or face of a block, as the case may be for a given clip).
As shown in
The building set 100 further includes a plurality of clips 110 configured to engage a thickness of one or more of the blocks. In one embodiment, the clip might engage a thickness of multiple blocks stacked together. Exemplary clip 110 may include a base 112 including a floor 114 against which a surface of a block may be inserted during frictional engagement, and first and second extensions 116, 118 extending upwardly from base 112. Extensions 116, 118 define a channel 120 therebetween and which may be open at a top end adjacent top ends of extensions 116, 118. Channel 120 may also be open at either end, adjacent lateral ends of extensions 116, 118, and floor 114. Channel 120 advantageously has a width that is substantially equal (and slightly less than) the thickness of the block that is receivable and to be frictionally retained within channel 120. For example, the thickness between faces 104a and 104b of illustrated block 102 may be substantially equal to the width of channel 120, between extensions 116, 118 so that the extensions may frictionally retain block 102 when inserted into channel 120. In another embodiment, a clip may be configured with a width of channel 120 that is substantially equal to the thickness between first and second sides 106a and 106b (i.e., to straddle this wider dimension of rectangular block 102).
In addition, it will be readily apparent that clip 110 may be positioned in a variety of locations along side 106a, 106b, or ends 108a, 108b to straddle the thickness between faces 104a and 104b. In other words, attachment of clip 110 to block 102 is not limited to only a single, or even a small number of locations, but may be slid to an infinite number of positions anywhere along sides 106a, 106b, or ends 108a, 108b. This characteristic provides an increased freedom in building that is not possible with fixed connection systems, in which connection is only possible at a single (or small number of) predetermined location(s).
In addition to the frictional retaining engagement provided by extensions 116 and 118 of clip 110, clip 110 further includes a magnet enclosed therein (e.g., within base 112) so that base 112 of clip 110 may be coupled to the base of another clip when the enclosed magnets are positioned close to one another. Of course, a magnet may be enclosed elsewhere within clip (e.g., within one or more of extensions 116, 118) to provide magnetic coupling between any portion of two clips including encased magnets. This frictional engagement and magnetic engagement configuration allows blocks to be stacked or positioned adjacent to one another, typically with clips disposed in between, providing a much more robust connection between the blocks than is possible with simple stacking.
For example, blocks may be cantilevered much like a house of cards, while clips positioned in between individual blocks provide a much stronger connection throughout the entire structure. For example, it may be possible to lift such a structure off a floor or other supporting surface, while it maintains its structural integrity. In order to provide even better structural integrity, the building structure may include clips frictionally engaged on blocks at the bottom of the structure, adjacent the floor or other supporting surface, while the supporting surface comprises a magnetically attractable pad or building surface to which the clips (and thus the super-structure thereabove) are strongly magnetically coupled.
Also shown in
As described, each clip includes a magnet 122 encased within base 112 of clip 110, 110a. Besides the difference in the configuration of exterior bottom surface 124,
As shown in
Strongly magnetic rare earth neodymium and/or samarium-cobalt magnets are particularly preferred, although other types of magnets (e.g., AlNiCo magnets, ceramic magnets, and/or ferrite magnets) may also be used. Permanent magnets are preferred.
Although a particular configuration of a star-like clip is shown in
In a broad context of one embodiment, the various clip configurations may include a pair of substantially parallel extensions configured to receive and frictionally retain a thickness of a block, while the clip further includes a magnet within a base (and/or even the extensions) of the clip in order to magnetically couple the magnet of the clip to another magnet, or to a magnetically attractable material (e.g., to a metal box top or other magnetically attractable pad that can act as a building base).
In one embodiment, the building set may be packaged within a metallic box, in which the box lid may be used as such a building base to providing magnetic coupling to the magnetic clips.
The clips may be formed of plastic or any other suitable material (e.g., plastic, wood, metal, carbon fiber, etc.). They may be formed by injection molding, machining, or other suitable technique. The magnet(s) within each clip are advantageously encased within the plastic or other material so as to prevent them from falling out or otherwise becoming dislodged. In one embodiment, the clips are not formed of wood to prevent such an issue (although perhaps a wooden clip could include a magnet encased therein in which an access hole used to place the magnet is back filled with glue, composite, epoxy, etc. Various techniques of inserting one or more magnets into a block are disclosed in U.S. Publication No. 2010/0242250, herein incorporated by reference. Such techniques could be adapted for providing a magnet within any clip according to the present invention. In addition, in one embodiment, one or more of the provided blocks may include a magnet encased therein, although in one embodiment, no magnets are provided within the blocks, rather the magnets are frictionally connected to the blocks through use of the clips. In one embodiment, the clips may be formed by bonding two halves about the magnet(s) (e.g., through sonic bonding).
In one embodiment, blocks may include any of various features incorporated therein. For example, the Figures show blocks shaped as stairs, walls, including windows, etc. Other configurations will also be apparent to one of skill in the art in light of the present disclosure. For example, a block may include a pulley incorporated into the block so that a width of the block may be engaged within a given clip, allowing the pulley (or other feature) to be indirectly coupled to the clip.
The blocks may be formed of any suitable material (wood, plastic, metal, carbon fiber, composite material, etc.). In one embodiment, the blocks are formed of wood or a plastic or composite material resembling wood.
Another contemplated embodiment of a building set may include a plurality of elongate rods, or straight sided (e.g., square or rectangular) blocks or sticks that include a rounded bulb-shaped enlarged end (or such enlargements at two or more ends). Each rounded end would house a magnet enclosed within the bulb. The magnet within the enclosing bulb may be pivotable, like a ball joint to allow it to pivot as needed to correctly orient magnetic poles. Attached pictures illustrate the concept with q-tips including rubber cement at their enlarged rounded ends to simulate placement of such magnets. Such building structures could be connected in myriad ways because the enlarged tip (or at least the magnet housed therein) can rotate as much as about 360°. Sticks or rods of varying length could be provided, which can be magnetically coupled to one another. Such elongate rods could be used in conjunction with the previously described embodiments, or separately, without the need for clips to connect adjacent blocks.
Clip 310 includes a central body 330 and a plurality of channels 320 disposed so as to extend from central body 330. Although four channels are illustrated, it will be understood that more or fewer channels may be provided (e.g., 2, 3, 5, 6, etc.). While each channel 320 is illustrated as being configured with equal width, it will be understood that one or more of the channels may have a different width than another of the channels. In addition, while all channels are shown to be oriented in a particular orientation, it will be understood that one or more of the channels may be differently oriented (e.g., transverse). For example,
Each channel 320 of clip 310 includes a base 312 disposed on central body 330. Each base 312 defines an interior floor surface 314 of each channel 320. The sides of each channel 320 are bounded by extensions 316 and 318, which are substantially parallel to each other. In an embodiment, the interior surfaces of each extension within channel 320 may be formed of planar surfaces, without any protrusions formed thereon, as shown. In other embodiments, one or more protrusions (e.g., apexes) may be formed thereon. Floor surface 314 may be a single planar surface, as shown. As described above, a thickness defined between opposed faces, sides, or ends of one or more blocks is receivable within any of channels 320. The width of channel 320 is substantially equal to the thickness of the corresponding block that is retainably engaged within a given channel.
As will be apparent from the disclosure and drawings, the described configuration allows the block to be rotated within the channel to form a variety of desired angles between the floor of the channel and a side or end of the block inserted into the channel.
As seen in
Central body 330 and channels 320 may advantageously be configured to provide independence between the plurality of included channels. For example, insertion of a block into one channel does not substantially interfere with the ability of another channel of the clip 310 to retain a block with substantially the same retention force that would be provided if only a single channel had a block received therein. Some similar toy coupler configurations within the prior art suffer from lack of independence between individual coupling mechanisms of the device. For example, when a second block or piece is inserted within a second coupler mechanism, it may cause a first already inserted block or piece to fall out or be retained with a substantially reduced retention force (i.e., so that it may easily fall out if bumped or jarred). The ability to provide independence to each channel is particularly advantageous, as it allows any or all of the channels to be employed without risk that the structure will become unstable as a result of weakened retention force for the frictionally engaging channels.
Independence is provided through a combination of features of the central body, the channels themselves, and the material from which the clip is formed. For example, the clip may be injection molded from a relatively rigid plastic material such as polycarbonate. Rigidity of the material from which the clip is formed aids in providing the desired independence. Furthermore, the central body 330 may include a plurality of stabilizing ribs 332 extending outwardly from the cylindrical wall bounding central hole 328 towards a portion 334 of extensions 316 and 318 that extend beyond base 312. The clip may include ribs that are substantially equally spaced between channels 320, so that the clip includes an equal number of ribs 332 and channels 320. Ribs 332 aid in preventing stresses and forces applied to extensions 316 and 318 from being transferred from one channel to the extensions of another channel of clip 310 when a block is retained within a given channel 320.
Central body 330 may further include a plurality of flanges 336 centrally disposed between base 312 of channel 320, portions 334 of extensions 316 and 318, ribs 332, and the cylindrical wall of hole 328. The flange 336 may fill the area of space shown in
Depending on the tolerances achieved during manufacture, the four distinct differently angled surfaces may be somewhat muddled as a result of shrinkage of the plastic or other material during manufacture or other reasons. For example, a finished manufactured product may be readily observed to include at least two portions. For example, a proximal portion (e.g., corresponding to portions 338 and 340) may overall provide an angle relative to the floor that is less than 90°, while a more distal portion (e.g., corresponding to portion 342 and perhaps 344) provides an angle relative to floor 314 that is at least 90°. Such is visible in
The width of channel 320 may thus vary somewhat according to location within the channel 320. For example, the width of channel 320 adjacent floor 314 may measure somewhat larger than the thickness of a block to be engaged within channel 320. Channel width may progressively narrower through the portion of channel 320 corresponding to portion 340 (as portions 340 on each side of channel 320 are “pinch” angled). The width of channel 320 corresponding to distal portion 344 may quickly be somewhat larger (as a result of its outward flare) than the thickness of the block (e.g., similar to portion 338). As a result, substantially all of the frictionally engaging retention force for retaining a block within channel 320 may be provided along portion 342.
In one embodiment, portion 342 may account for about 35% to about 45% (e.g., about 40%) of the depth of channel 320. In one embodiment, the channel may have a length that is substantially equal to a dimension of a corresponding dimension of one or more of the blocks (e.g., about 23 mm). Width of channel 320 along corresponding to portions 338 may measure 0.310 inch, while the width at the opening of channel corresponding to portions 344 may measure 0.294 inch. For example, the width may narrow by about 1% to about 10% over the channel width (e.g., about 5%).
In addition to providing independence between the various channels of the clip 310, the retaining force provided by each channel and a given block is preferably relatively strong, so as to prevent a block from falling out of a channel inadvertently. Of course, the retaining force provided requires that the dimension of the block to be retained be sized for use with the friction retaining channel. Where the dimensions are approximately equal, so that the block is frictionally retained within channel 320, the features described above (e.g., pinching configuration of the interior surfaces of channel 320, structural ribs 332 and flanges 336, selection of a rigid plastic such as polycarbonate) provide a retaining force so that from about 1 lb to about 5 lbs of pull out force is required to pull a block that engages substantially all of the length of the channel out of the channel.
In other words, where the block is sized smaller than the channel length, or only half or a portion of the block dimension is engaged within the channel, (so that a plurality of blocks may be received within the same respective channel at the same time), or the block is only partially inserted into the channel while still being retained therein, which capabilities will be apparent from the drawings, the actual retention force will be less for that particular configuration, although the retaining force available when the channel length is fully engaged will be 1 lb to about 5 lbs. In another embodiment, the provided retaining force is from about 2 lbs to about 4 lbs of pull out force to pull the block out of the channel.
In testing the pull out force, 6 blocks of approximately equal size and shape (as shown in the photograph of the wheeled vehicle in the provisional application) were fully inserted within the illustrated clips and were pulled out. A fish scale was used to measure the weight or force required to achieve pull out. The results as shown in Table I below.
It was observed that although the blocks were all approximately equally sized 8 mm×23 mm×118 mm, minor variances within the block dimension engaging the channel (i.e., 8 mm) have an effect on the retention force. For example, block 4 was observed to be somewhat thinner than the nominal 8 mm dimension, resulting in its lower retention values. Still, the retention value of 2 lbs will typically be sufficient for contemplated use. The particular configuration described in conjunction with
Photographic
Such connectivity between a block 102 and a channel 320 is not binary—either “snapped” into a corresponding receptacle or not. Because the system is not binary, this allows the building set to provide unique and different building characteristics such as partial or full engagement, ability to rotate the block to any angle relative to the floor of the connection channel, the ability to connect the block into the channel at any location along the length or ends of the block (i.e., “connect anywhere”), the ability to place multiple clips onto a length of the block, and the ability to retain multiple blocks into a single channel, etc.
It must be noted that, as used in this specification and the appended claims, the singular forms “a,” “an” and “the” include plural referents unless the context clearly dictates otherwise.
The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.
The present application is a continuation of U.S. patent application Ser. No. 14/962,937 (now U.S. Pat. No. 9,399,177), which is a continuation-in-part of U.S. Design patent application Ser. No. 29/513,902, filed Jan. 6, 2015 (now U.S. Pat. No. D757,860), which is a continuation-in-part of U.S. patent application Ser. No. 13/612,383, filed Sep. 12, 2012 (now U.S. Pat. No. 8,968,046), which claims the benefit of U.S. Provisional Patent Application Ser. No. 61/546,912 filed Oct. 13, 2011, entitled BUILDING SETS INCLUDING BLOCKS AND MAGNETIC COUPLING CLIPS, and U.S. Provisional Patent Application Ser. No. 61/594,850 filed Feb. 3, 2012, entitled TOY COUPLERS INCLUDING A PLURALITY OF BLOCK RETAINING CHANNELS. U.S. patent application Ser. No. 14/962,937 is also a continuation-in-part of PCT Patent Application PCT/US2015/039226, filed Jul. 6, 2015, which claims the benefit of U.S. Provisional Patent Application 62/115,458, filed Feb. 12, 2015. Each of the foregoing patents and applications is herein incorporated by reference in its entirety.
Number | Date | Country | |
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61546912 | Oct 2011 | US | |
61594850 | Feb 2012 | US | |
62115458 | Feb 2015 | US |
Number | Date | Country | |
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Parent | 14962937 | Dec 2015 | US |
Child | 15216887 | US | |
Parent | PCT/US2015/039226 | Jul 2015 | US |
Child | 14962937 | US |
Number | Date | Country | |
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Parent | 29513902 | Jan 2015 | US |
Child | 14962937 | US | |
Parent | 13612383 | Sep 2012 | US |
Child | 29513902 | US |