The present disclosure pertains to toys and, more particularly, to the design, building, and sharing of a modular toy block system employing a universal snapping modular block system.
Various modular block toys exist such as the LEGO® brick owned by the LEGO Group, Nanoblocks®, Snap Cubes®, and Click-A-Brick®, not to mention an international plethora of LEGO brick knock-offs
Existing block systems that employ snapping cubes specifically do not snap on all faces unit-to-unit contiguously, which results in a faulty amalgamated model that is weakly bound together physically. Pins, rods, and other connectors are also employed in existing cubic modular toys. A non-contiguous snapping system is a problem if the user wants to create something that is sturdy and does not fall apart (especially for larger creations) and that is easily expanded in all directions in a consistent design and structurally sound manner. On the other side of the market, LEGO bricks and Nanoblock blocks do not operate out of a contiguous cubic system and instead snap top-to-bottom, with unique pieces such as “plates” to facilitate lateral expansion of a model. Similarly, other brands rely on pins, rods, clips or other snapping components to lock.
The present disclosure is directed to a modular toy that utilizes physical snapping and locking modular block toys.
In accordance with one aspect of the present disclosure, a modular block toy is provided that includes a male cubic unit piece having a plurality of faces with a male node extending from each respective face of the plurality of faces, and a female cubic unit piece having a plurality of faces and corners formed by three intersecting faces, the female piece having a female component formed on a respective face of each of the plurality of faces that is sized and shaped to receive a respective male node from the male cubic unit piece with an interference fit, thereby enabling the female piece and the male piece to be connected together using any side of the female piece and any side of the male piece.
In accordance with another aspect of the present disclosure, all of the male nodes are of the same size and shape.
In accordance with yet a further aspect of the present disclosure, the male cubic unit piece has the male node centered on each respective face of the male piece, and wherein the female piece has a protuberance formed on each corner to extend onto each face adjacent to the respective corner to define the female component as a cross-shaped channel.
In accordance with still yet another aspect of the present disclosure, the male cubic unit piece has the male node centered on the respective face, and wherein the female piece has a protuberance formed on each corner to extend onto each face adjacent to the respective corner to define the female component as a T-shaped channel.
In accordance with another aspect of the present disclosure, the male cubic unit piece has the male node centered on the respective face, and wherein the female piece has a protuberance formed on each corner to extend onto each face adjacent to the respective corner to define the female component as at least one channel on each face of the female piece.
In accordance with a further aspect of the present disclosure, the male cubic unit piece and the female piece are sized to be manipulated by the human hand such that a male piece can be held in one hand and a female piece held in the other hand, and through manipulation of the two hands, the two pieces can be connected together, or the female component has one of a snapping bump, ramp, and groove that creates an interlock between a respective mating male node and female component when connected together in a flush face-to-face manner, or the male node and the female component each have one of a snapping bump, ramp and groove that creates an interlock between a respective mating male node and female component when connected together in a flush face-to-face manner, or any combination of the foregoing.
In accordance with another implementation of the present disclosure, a modular block system is provided that includes a first block having a plurality of faces and a projection extending from each face, and a second block having an interior block with a plurality of faces that form a plurality of corners, the second block having a plurality of protuberances that define at least one channel on a respective face, each channel sized and shaped to receive a projection from the first block with an interference fit that allows for connecting the second block to any one of the faces on the first block.
In accordance with another aspect of the present disclosure, a kit is provided that includes a plurality of first blocks, each first block having a plurality of faces and a projection extending from each face, and a plurality of second blocks, each second block having an interior block with a plurality of faces that form a plurality of corners, the second block having a plurality of protuberances that define at least one channel on a respective face, each channel sized and shaped to receive a projection from the first block with an interference fit that allows for connecting the second block to any one of the faces on the first block.
In accordance with another aspect of the present disclosure, the first blocks have the first projection centered on the respective face, and the second blocks have a protuberance formed on each corner to extend onto each face adjacent to the respective corner and connect with two adjacent protuberances to define a single channel on each face of the second blocks, thereby enabling the first blocks and the second blocks to be connected together using any side of the first blocks and the second blocks, and further enabling additional contiguous connection of additional first and second blocks indefinitely in any direction.
In one aspect of the present disclosure, a universal modular block system is provided that enables the design and construction of physical block models with the system units (also known as pieces or cubic units). The core system building block is the cubic unit as illustrated in
The single-channel mode includes other implementations described herein, and the design of snapping and interlock mechanisms for such implementations, such as shown in
The ability of the two variant pieces to universally connect on all sides allows the design and construction of models or block creations using the pieces only, achieving complete continuity in the design and build of the model without the need of connectors, rods, clips or other snapping components. As further described herein, the snapping and locking moment (male to female, and female to male) is achieved through a designed “squeeze” or “interference” under which the female piece holds and locks the male piece on the particular side being connected once the two pieces are snapped together. The implementation is further described herein, and each snapping mode is shown in
As will be readily appreciated from the foregoing, a snapping block toy is provided that includes a female and a male cubic unit piece wherein all sides of the female piece, including the snapping and interlock design, are identical, and all sides of the male piece, including the snapping and interlock design, are identical, thereby enabling the female piece and the male piece to be snapped together using any side of the female piece or male piece. Additionally, the block designs further enable construction of models or creations with such pieces that can be contiguously built out indefinitely in any direction.
Moreover, the snapping block toy further provides the advantage of multiple piece size scales manageable by the human hand, multiple male-to-female interference snapping mechanisms including flat flush interlocking surfaces, convex and concave flush interlocking surfaces, and the aforementioned interlocking surface faces accompanied by snapping bumps, ramps, and grooves on either the male or female snapping face, all of which can snap and interlock together using any of the six faces of the male and female cubic pieces.
In addition, the implementations of the present disclosure enable the use of electronics and circuitry piece integration, including, without limitation, basic conductor pieces, pieces that illuminate, pieces that sense various physical data such as light, sound, temperature, and smell, as well as pieces that communicate data via wireless routers, pieces that communicate data via Bluetooth, pieces that take photos or video, and servomotor pieces that enable movement.
As will be further appreciated from the foregoing, the present disclosure provides for completely contiguous cubic snapping in all directions. The universal snapping unit cube such as disclosed herein allows for an unprecedented degree of representational resolution and design options for modeling ideas and for creative exploration. A universal snapping system disclosed herein solves both problems described above at once—firstly, because all faces are snapped between adjacent units, the model will be sturdy and complete at all scales; and secondly, the user does not have to rely on unique pieces or separate snapping or connecting components to expand their model outward in any direction.
The foregoing and other features and advantages of the present disclosure will be more readily appreciated as the same become better understood from the following detailed description when taken in conjunction with the accompanying drawings, wherein:
In the following description, certain specific details are set forth in order to provide a thorough understanding of various disclosed implementations. However, one skilled in the relevant art will recognize that implementations may be practiced without one or more of these specific details, or with other methods, components, materials, etc. In other instances, well-known structures or components or both associated with modular blocks, interlocking block and puzzle pieces, computers, microprocessors, personal communication devices, tables, and the like have not been shown or described in order to avoid unnecessarily obscuring descriptions of the various implementations of the present disclosure.
Unless the context requires otherwise, throughout the specification and claims that follow, the word “comprise” and variations thereof, such as “comprises” and “comprising” are to be construed in an open inclusive sense, that is, as “including, but not limited to.” The foregoing applies equally to the words “including” and “having.”
Reference throughout this description to “one implementation” or “an implementation” means that a particular feature, structure, or characteristic described in connection with the implementation is included in at least one implementation. Thus, the appearance of the phrases “in one implementation” or “in an implementation” in various places throughout the specification are not necessarily all referring to the same implementation. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more implementations. In addition the words “channel” and “groove” are used interchangeably throughout.
The figures are provided (a) to further describe the present disclosure, (b) to show certain implementations or permutations of the present disclosure, and (c) to show enablement, function, and use thereof. However, the figures are not visually to scale, although annotated dimensions on certain embodiments or permutations are true to form. It is to be understood that the description herein and the accompanying figures describe certain implementations, versions, and permutations of the present disclosure and are not intended to be exclusive.
Summary of Universal Snapping Modular Block System
The universal snapping modular block system component of the present disclosure is based upon a cubic base unit shown in
With respect to each of the female unit design modes, the female unit cube is designed with an identical female connection design on all six sides. The male unit cube is designed with an identical male connection design on all six sides such that the male unit cube snaps and locks together side to side with any of the different female cube units. (See
The universal snapping modular block system includes several varying design modes, each of which employs essentially the same two-variant system. As shown in
The design of the female unit is in three design modes. The first design mode is referred to herein as the “cross-channel” mode as shown in
Referring initially to
The toy 30 and system 32 also include a female cubic unit piece 50 having a plurality of faces 52 and corners 53 (shown in phantom) formed by three intersecting faces 52. A female component in the form of at least one channel 54 is located on a respective face 52 of each of the plurality of faces that is sized and shaped to receive a respective male node 44 from the male cubic unit piece 40, preferably with an interference fit, thereby enabling the female piece 50 and the male piece 40 to be removably connected together using any side or face 52 of the female piece 50 and any side or face 42 of the male piece 40. Ideally the interference fit is such that it enables manual assembly and disassembly by the human hand.
In the implementation shown in
Also shown in
It will be appreciated that in use, the male node 44 may be placed at any location along the groove 54, providing countless variations in the shapes that can be created with these two pieces.
In
Hence, in this implementation, representative L-shaped protuberance 66a has a first corner 56a piece that is connected to an adjacent second corner piece 56b by a lower connector 67, and the second corner piece 56b is connected to the third corner piece 56c by an upper connector 68. The lower connector 67 is sized and shaped to be flush with a top face 52c to form the elongate groove 62a, and further to extend onto a side face 52b to form a projecting wall that defines a terminal wall for a corresponding shorter groove 64a on the side face 52b. Similarly, the upper wall or connector 68 forms a projecting wall on the top adjacent face 52c that defines a terminal wall for another shorter groove 64b on the top face 52c, and it is flush with an adjacent face (not shown) to form a portion of a respective elongate groove (not shown) in the manner as described above with respect to elongate groove 62a.
In this implementation, the system 32 illustrated at the bottom of
In
In a similar fashion, a second or lower groove 70b is formed on the bottom face of the female piece 50. As shown in
As depicted in
One use of the toy 30 is shown in
The T-channel and the single-channel versions of the toy 30 are shown in
In
In accordance with another implementation of the present disclosure, the protuberances on the female pieces and the nodes on the male pieces are designed and formed to have a more secure engagement. Representative implementations of several designs are depicted in the accompanying figures and are described in more detail below. It is to be understand that these are only a few non-limiting examples, and other configurations are possible. In addition, design variations in the size and shape of the female and male pieces, as well as the various geometric shapes that may be chosen for the protuberances, projections, nodes, channels, and grooves, are possible that may be chosen for aesthetic purposes unrelated to the function thereof, including symmetry, balance, and radius of curvature, to name a few.
In
More particularly, the male node 112 has beveled faces 114 on each of its four corners that are substantially parallel to the respective distal face 108 on the female piece 100. The size of these distal and beveled faces 108, 114 will depend on the amount of overlapping area 116 to be provided between the protuberances 104 and the male node 112.
An alternative design is shown in
With respect to
The variations in the female pieces described above can be applied to the T-channel and single-channel implementations, which are shown in
Similarly, in
Referring next to
In
As will be appreciated from the foregoing, the interference lock nodes on the female piece, combined with the plasticity of the material of the pieces, are designed to allow the male pieces (i.e., the nodes on the male pieces) to slide together with the female piece past the interlock nodes on either side of the locked position on the female piece into the locked position. In other words, the plasticity (or malleability) of the material allows the transient piece to slide past any interlocking bump, ramp, or snap onto the other piece by deflecting or compressing the male and female interlock nodes sufficiently to allow the piece to pass, and then once in place, the rebound of the material allows the male and female interlock nodes to return to their original shape (or a slightly compressed or squeezed state) with a remaining interference rebound pressure between the female interlock edges and the male node edges, thereby locking (i.e., squeezing) the male piece in place.
Various designs in which this squeeze are accomplished for each two-variant piece mode as described above. The size of the interlock nodes and degree of interference can be varied depending on (a) the plasticity and malleability of the material related to the resistance, deflection, compression, and rebound of the material, (b) the desired resistance and snapping effort when snapping pieces together, and (c) the degree of locking moment preferred once the pieces are locked in place.
In the single-channel flat design described above (
The design and mechanics of the single-channel ramped flat female piece (
As mentioned above, the male node 312 can also be perpendicularly inserted directly into the center of the channel 306, bypassing the sliding action, taking the 2.667 mm wide and long square male node and snapping it directly into the female channel, which measures 2.567 mm in the center, facilitating the same 0.100 mm interference squeeze lock in the end. A single-channel ramped flat piece design with 0.100 mm interference between the male and female locking features is a non-limiting variation as explained above.
Features Common to All Two Variant Modes
With reference to the three two-variant modes (cross-channel, T-channel, and single-channel), all two-variant pieces snap and lock together, male to female or female to male, as illustrated and described herein. Once in the locked position, the two pieces may be unlocked and unsnapped by sliding them in the opposite reverse direction, or by sliding them apart in one of the other potential directions allowed by the channels on the female pieces. The multiple directions in which the male pieces and female pieces may be snapped together (i.e., inserted together) are shown in
This is to say that there are no dead ends in the user buildout of a model using the two individual cubic base unit male and female pieces with any of the three two-variant piece modes, being unrestrained by adjacent pieces, and snapped and locked together piece side to piece side in any one of the described different directions. On both the male piece nodes and the female piece channels, all edges can be slightly rounded to facilitate the snapping action and effort. The design of the male piece nodes and the female pieces can also accommodate and include bumps of various shapes as part of the snapping action in order to better establish and confirm the centered locking position. The bumps could be on the male piece nodes or on the female piece channels or possibly on both.
The dynamics of the universal snapping modular block system can function at any piece scale manageable by the human hand 388, as shown in
The single-channel insertion trajectories as represented in
Top face insertion of single-channel piece via three methods: (1a) perpendicular insertion, (2a) lateral slide-in, (3a) lateral slide-in.
SE face insertion of single-channel piece via three methods: (4a) perpendicular insertion, (5a) lateral slide-in, (6a) lateral slide-in.
SW face insertion of single-channel piece via three methods: (7a) perpendicular insertion, (8a) lateral slide-in, (9a) lateral slide-in.
Bottom face insertion of single-channel piece via three methods: (10a) perpendicular insertion, (11a) lateral slide-in, (12a) lateral slide-in.
NW face insertion of single-channel piece via three methods: (13a) perpendicular insertion, (14a) lateral slide-in, (18a) lateral slide-in.
NE face insertion of single-channel piece via three methods: (16a) perpendicular insertion, (17a) lateral slide-in, (18a) lateral slide-in.
The cross-channel insertion trajectories as represented in
Top face insertion of cross-channel piece via five methods: (1b) perpendicular insertion, (2b) lateral slide-in, (3b) lateral slide-in, (4b) lateral slide-in, (5b) lateral slide-in.
SE face insertion of cross-channel piece via five methods: (6b) perpendicular insertion, (7b) lateral slide-in, (8b) lateral slide-in, (9b) lateral slide-in, (10b) lateral slide-in.
SW face insertion of cross-channel piece via five methods: (11b) perpendicular insertion, (12b) lateral slide-in, (13b) lateral slide-in, (14b) lateral slide-in, (15b) lateral slide-in.
Bottom face insertion of cross-channel piece via five methods: (16b) perpendicular insertion, (17b) lateral slide-in, (18b) lateral slide-in, (19b) lateral slide-in, (20b) lateral slide-in.
NW face insertion of cross-channel piece via five methods: (21b) perpendicular insertion, (22b) lateral slide-in, (23b) lateral slide-in, (24b) lateral slide-in, (25b) lateral slide-in.
NE face insertion of cross-channel piece via five methods: (26b) perpendicular insertion, (27b) lateral slide-in, (28b) lateral slide-in, (29b) lateral slide-in, (30b) lateral slide-in.
The insertion options for the T-channel configuration are similar to the other pieces as described above. Because one of skill in this technology would understand from the foregoing description how to apply the foregoing options to the T-channel configuration, they will not be illustrated or described further herein.
Kits
The system and toy of the present disclosure can be commercialized in the form of a kit containing multiple male and female pieces. These complementary pieces can be sold in assortments of sizes or non-cubic shapes (described below) and with any number of desired pieces.
Non-Cubic Pieces:
The components of the present disclosure include an unlimited multitude of non-cubic piece designs to enable the design and construction of models at a highly creative and detailed level. Although most of these non-cubic pieces do not snap together in the same universal manner as the core cubic pieces, on a surface to surface connectivity basis they employ the same snapping action (i.e., male nodes, female grooves/channels, and locking moment) as the core cubic pieces.
Manufacturing and Material Implementation:
The universal snapping modular block system component of the present disclosure (i.e., the units or pieces) can be manufactured and produced through various processes including stereolithic printing, selective laser sintering, injection-molding, etc. Injection molding is a preferred process of choice as it is the most reliable and accurate production process for achieving the described dynamics of the components. The components are not restricted by material, as various substances enable the components' design, such as nylon. Flexible plastics such as ABS and similarly behaving materials are best. As noted above, the plasticity and malleability of the material (together with the design dimensions of the pieces) can be adjusted to establish the desired resistance, snapping effort and locking action of the pieces.
The various implementations described above can be combined to provide further implementations. Aspects of the present disclosure can be modified, if necessary to employ concepts of the various patents, applications, and publications discussed herein or to provide yet further implementations.
These and other changes can be made to the implementations in light of the above-detailed description. In general, in the following claims, the terms used should not be construed to limit the claims to the specific implementations disclosed in the specification and the claims, but should be construed to include all possible implementations along with the full scope of equivalents to which such claims are entitled. Accordingly, the claims are not limited by the disclosure.
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