This relates generally to floor tiles, and more particularly to modular floor tiles with multiple level support systems.
Floor tiles have traditionally been used for many different purposes, including both aesthetic and utilitarian purposes. For example, floor tiles of a particular color may be used to accentuate an object displayed on top of the tiles. Alternatively, floor tiles may be used to simply protect the surface beneath the tiles from various forms of damage. Floor tiles typically comprise individual panels that are placed on the ground either permanently or temporarily depending on the application. A permanent application may involve adhering the tiles to the floor in some way, whereas a temporary application would simply involve setting the tiles on the floor. Some floor tiles can be interconnected to one another to cover large floor areas such as a garage, an office, or a show floor. Other interconnected tile systems are used as dance floors and sports court surfaces.
However, typical interconnected tile systems are rigid and unforgiving. Short and long term use of modular floors for sports activities and dance can result in discomfort to the users. Conventional interconnected tile systems absorb little, if any, of the impact associated with walking, running, jumping, and dancing. Consequently, some users may experience pain or discomfort of the joints when using the interconnected tile systems. Therefore, there is a need for modular interconnected tile systems that include features that provide a more comfortable, useful surface.
Some embodiments address the above-described needs and others. In one of many possible embodiments, a modular floor tile is provided. The modular floor tile comprises a top surface, a plurality of edge surfaces, an interlocking mechanism for attachment to adjacent tiles, and a support system comprising multiple levels of support. In one embodiment, at least one of the multiple levels of support comprises a first resilient level, and another of the multiple levels of support comprises a first rigid level. In one embodiment, the first resilient level comprises a plurality of inserts disposed under the top surface. In one embodiment, the first resilient level comprises a plurality of interconnected elastomeric removable inserts nested under the top surface. In one embodiment, each of the plurality of inserts comprises a length equal to or greater than a height of the plurality of edge surfaces. In one embodiment, the plurality of inserts each comprise a generally cylindrical post. In one embodiment, the at least one insert comprises a base and a post extending from the base. According to one embodiment, the top surface comprises a solid surface.
In one embodiment of the modular floor tile, the first rigid level of the multiple levels of support comprises a first set of support legs having a first length extending from the top surface, and the multiple levels of support comprise a second rigid level comprising a second set of support legs having a second length, the second length being shorter than the first length. In one embodiment, the first and second sets of support legs are arranged in an alternating pattern comprising a first leg of the first length, a group of three to four legs of the second length, and the resilient level comprises a plurality of inserts nested in the group of three to four legs. The resilient level may extend in length beyond the first and second rigid levels. In one embodiment, the first resilient level comprises a plate of multiple inserts interconnected by a webbing, the plate shaped substantially the same as the top surface.
In one embodiment of the modular floor tile, the top surface comprises an open surface. The open surface comprising a pattern of gaps, and the first resilient level comprises a plurality of elastomeric inserts with a length greater than a height of the edge surfaces, each of the plurality of inserts comprising a base and a post extending from the base. The post is sized small enough to pass through one of the gaps, and the base is sized large enough to resist passage through one of the gaps. In one embodiment, each of the plurality of elastomeric inserts comprises a post straddling the open surface at the gaps.
In one embodiment of the modular floor tile, the interlocking mechanism comprises a plurality of lipped loops disposed in at least one of the plurality of edge surfaces, and a plurality of locking tab assemblies disposed in at least one of the plurality of edge surfaces. Each of the plurality of locking tab assemblies comprises a center post and flanking hooks.
One embodiment provides an apparatus comprising a modular floor. The modular floor comprises a plurality of interlocking tiles connected to one another. Each of the plurality of interlocking tiles comprises a top surface and a plurality of support levels under the top surface. The plurality of support levels comprises at least one rigid level and at least one flexible level extending beyond the at least one rigid level. In one embodiment, at least one flexible level comprises a plurality of elastomeric inserts, and each of the plurality of interlocking tiles comprises a bottom, the bottom including a plurality of receivers sized to hold one of the plurality of elastomeric inserts.
One aspect provides a method of making a modular floor. The method comprises providing an interlocking modular tile having a top surface and a bottom plane parallel to and spaced from the top surface, inserting a plurality of resilient inserts into associated nests opposite of the top surface, and protruding the plurality of resilient inserts beyond the bottom plane. In one aspect, the top surface comprises a solid top surface, and the inserting further comprises contacting an underside of the top surface with the plurality of resilient inserts. In one aspect, inserting comprises inserting the resilient inserts as a single, interconnected unit of inserts. In one aspect, inserting further comprises fitting the plurality of resilient inserts into a nest by an interference fit. In one aspect, the top surface comprises an open surface, and inserting comprises pressing the plurality of resilient inserts through associated gaps in the first open surface in a first direction.
In one aspect of the method, the plurality of resilient inserts comprise a first support level. In one aspect, the method further comprises providing a second, rigid support level flush with the bottom plane, and providing a third, rigid support level between the bottom plane and the top surface.
One aspect provides a method of making a modular tile comprising forming a tile body having a solid top surface, providing a plurality of elastomeric inserts having a length at least as great as a height of the tile body, and pressing the plurality of elastomeric inserts into nests under the solid top surface. In one aspect, providing a plurality of elastomeric inserts comprises providing an interconnected webbing of the elastomeric inserts.
According to at least one embodiment, a modular floor tile may comprise a top surface layer, a plurality of edge surfaces, an interlocking mechanism for attachment to adjacent tiles, and a support system. The support system may comprise a first rigid level and at least one resilient support member disposed under the top surface layer, the at least one resilient support member extending to a distance further from the top surface layer than the first rigid level, wherein the at least one resilient support member is compressible toward the top surface layer.
According to an additional embodiment, an apparatus may comprise a modular floor, the modular floor comprising a plurality of interlocking tiles connected to one another. Each of the plurality of interlocking tiles may comprise a top surface layer and a plurality of edge surfaces. Each of the plurality of interlocking tiles may also comprise a plurality of support levels under the top surface layer, the plurality of support levels comprising at least one rigid level and at least one resilient support member disposed under the top surface layer, wherein the at least one resilient support member may be compressible toward the top surface layer.
According to various aspects, a method of forming a modular floor may comprise providing an interlocking modular tile having a top surface layer, a bottom plane substantially parallel to and spaced from the top surface layer, and a first rigid support level flush with the bottom plane. The method may further comprise inserting a plurality of resilient inserts into associated nests adjacent to the top surface layer such that the plurality of resilient inserts protrude beyond the bottom plane.
The foregoing features and advantages, together with other features and advantages, will become more apparent when referring to the following specification, claims and accompanying drawings.
The accompanying drawings illustrate various embodiments and are a part of the specification. The illustrated embodiments are merely examples and do not limit the claims.
Throughout the drawings, identical reference numbers designate similar, but not necessarily identical, elements.
As mentioned above, typical modular flooring comprises solid or open top surfaces that tend to be slippery. The slippery surfaces compromise the footing of users, especially sports court users that tend to start and stop abruptly. The typical modular floor offers less than ideal traction to dance, sport, pedestrian, and other traffic. The principles described herein present methods and apparatus that provide better traction and more flexibility than previous flooring systems. However, the application of the principles described herein is not limited to the specific embodiments shown. The principles described herein may be used with any flooring system. Moreover, although certain embodiments shown incorporate multiple novel features, the features may be independent and need not all be used together in a single embodiment. Tiles and flooring systems according to principles described herein may comprise any number of the features presented. Therefore, while the description below is directed primarily to interlocking plastic modular floors, the methods and apparatus are only limited by the appended claims.
As used throughout the claims and specification, the term “modular” refers to objects of regular or standardized units or dimensions, as to provide multiple components for assembly of flexible arrangements and uses. “Resilient” means capable of returning to an original shape or position, as after having been compressed; rebounds readily. “Rigid” means stiff or substantially lacking flexibility. However, a “rigid” support system may flex or compress somewhat under a load, although to a lesser degree than a “resilient” support system. A “post” is a support or structure that tends to be vertical. A “top” surface of a modular tile refers to the exposed surface when the tile is placed on a support, or the designated surface for stepping on, driving on, supporting objects, etc. An “insert” is an object at least partially inserted or intended for insertion relative to another object. A “post” may be cylindrical, but is not necessarily so. The words “including” and “having,” as used in the specification, including the claims, have the same meaning as the word “comprising.”
Referring now to the drawings,
The modular tile 100 of
Each of the holes 102 in the open surface 104 is receptive of an insert 105. However, it is not necessary for every hole 102 to include an insert 105. For example,
The insert 105 may comprise a resilient material, which may be an elastomer such as rubber and may include many different shapes. For example, as shown in
As shown in
Continuing to refer to
The protruding inserts 105 advantageously provide traction and comfort to users of the modular tile 100. As mentioned above, the inserts 105 may be elastomeric, and soft elastomeric materials such as rubber and santoprene provide excellent traction for users. The inserts 105 are compressible as well, providing a comfortable surface for users to walk across. The number of inserts 105 used with the modular tile 100 may be varied according to preference. Moreover, as described below, the modular tile 100 includes an interlocking mechanism for attachment to adjacent tiles. Therefore, multiple modular tiles 100 may be interlocked to create a floor of any size and shape. One embodiment of an interlocking mechanism is described in the following paragraphs.
The modular tile 100 includes a plurality of side edges, which, according to the embodiment of
Each of the plurality of loops 114 is receptive of a mating locking tab assembly 116 from an adjacent modular tile. According to the embodiment of
Referring now to
In addition, although the prongs 132 of the flanking hooks 120 provide a double lock against disconnection of the adjacent modular tiles 100, they permit sliding lateral displacement between the adjacent modular tiles 100. A predetermined amount of sliding lateral displacement between the adjacent modular tiles 100 may be controlled, for example, by the depth D of the center post 118, in combination with the depth D′ (
However, although some embodiments facilitate lateral displacement between interlocked modular tiles, a complete floor may tend to look sloppy and misaligned in some configurations. Therefore, according to some embodiments, adjacent modular tiles may be biased or spring loaded to a specific, generally equal spacing therebetween. Referring to
Each of the modular tiles 100 includes a support system under the top open surface 104. According to some aspects, the support system comprises a multiple-tier suspension system. One embodiment of the multiple-tier suspension system is illustrated in
The spacing of the first set of support legs 152 facilitates vertical flexing or springing of each of the modular tiles 100. That is to say, as a load is applied to one or more of the modular tiles 100, 102 on the first open surface 104, the first open surface 104 “gives” or tends to flex somewhat, until the second set of support legs 154 contacts the ground. In addition, the inserts 105 tend to compress as they are stepped on. Accordingly, application of the principles described herein may result in a comfortable spring-like modular floor.
The modular tile 100 described above, along with a plurality of additional similar or identical modular tiles, may be arranged in any configuration to create a floor. For example, as shown in
For many uses of the modular tiles 100, including the sports court floor 160, traction can be important. Therefore, nonslip inserts 105 (
Referring again to
Referring next to
Unlike the inserts 105 illustrated above, the full-length inserts 205 may be substantially equal in length to, or slightly longer than, the side walls 106-112. Therefore, the full-length inserts 205, when assembled in the floor tile 100 and setting on a support surface, cannot fall out of the holes 102. The full length inserts 205 contact the ground or other support surface and extend though the open surface 104 in the floor tile 100.
The full-length inserts 205 may comprise a resilient material, which may be an elastomer such as rubber, or it may comprise plastic or other non-slip materials. The full-length insert 205 may include many different shapes. For example, as shown in
The full-length inserts 205 may be inserted from the bottom of the modular tile 100. As shown in
As shown in
Continuing to refer to
In one embodiment, the protruding full-length inserts 205 provide traction to users of the modular tile 100. As mentioned above, the full-length inserts 205 may be elastomeric, and soft elastomeric materials such as rubber and santoprene provide excellent traction for users. The full-length inserts 205 may be compressible as well, providing an addition level of support and a comfortable surface for users to walk across. Some embodiments of the insert 105 and the full-length insert 205, however, may be rigid. The number of full-length inserts 205 used with the modular tile 100 may be varied according to preference. Moreover, as described above, the modular tile 100 includes an interlocking mechanism for attachment to adjacent tiles. Therefore, multiple modular tiles 100 may be interlocked to create a floor of any size and shape.
Another embodiment is disclosed in
The modular floor tile 300 of
As mentioned above, the full-length inserts 205 comprise a resilient material, which may be an elastomer such as rubber, or they may comprise plastic or other materials. The full-length inserts 205 may include any shape. For example, as shown in
The first resilient level 370 of support comprising the plurality of full length inserts 205 tends to comfortably compress under a load as illustrated in
In one embodiment, at least one other of the multiple levels of support comprises a first generally rigid level 376. The first rigid level 376 may comprise the first set of generally rigid primary support legs 152 having the first length. The first rigid level 376 may coincide with the bottom plane 372. The first set of support legs 152 may each comprise the split or fork leg as shown in
In some embodiments, the modular floor tile 300 includes another support level. For example, the multiple levels of support may comprise a second generally rigid level 378. The second generally rigid level 378 may comprise the second set of generally rigid support legs 154 having the second length. The second set of support legs 154 may comprise clusters of three or four legs. The second length of the second set of support legs 154 is shorter than the first length of the first set of support legs 152. Therefore, absent a load sufficient to overcome the supporting capability of the first set of generally rigid support legs 152, only the first or second levels 370, 376 contact the ground. In the embodiment of
Accordingly, application of the principles described herein may result in another especially comfortable spring-like modular floor with multiple layers of support. In one embodiment, there are at least three separate layers of support, but there may be as few as two and as many as four or more. It will be understood that the top surface 304 need not be solid as shown in
As discussed above, the full length inserts 205 may be removably inserted into the modular tile 300. In some embodiments, however, the full length inserts 205 or another resilient support level are part of a one-piece, unitary tile.
Each of the plurality of loops 414 may be receptive of a mating locking tab assembly 416 from an adjacent modular floor tile. According to the embodiments of
According to certain embodiments, adjacent modular floor tiles 400 may be biased or spring loaded to a specific, generally equal spacing. For example, one or more of the side walls 406, 408, 410, and 412 may include one or more biasing members such as spring fingers 434 disposed therein. Spring fingers 434 may tend to bear against adjacent side walls of adjacent modular floor tiles 400, aligning modular floor tiles in a floor to a substantially equal spacing, while also permitting lateral displacement upon the application of a sufficient lateral force.
Each of modular floor tiles 400 may include a support system under top surface layer 404. According to various embodiments, the support system may comprise a multiple-tier suspension system. According to additional embodiments, modular floor tile 400 may comprise one or more inserts or resilient support members 405 forming a first resilient level. Resilient support members 405 may comprise a resilient material, which may be an elastomer such as rubber, silicone, a polymer, and/or any other suitable elastomeric material and may include many different shapes. Additionally, resilient support member 405 may be compressible under various forces, including various forces applied to top surface layer 404.
Each of resilient support members 405 may be substantially equal in length to, or slightly longer than, the edge surfaces 406, 408, 410 and/or 412 (see also,
The first resilient level of support, which includes a plurality of resilient support members 405, may comfortably compress under a load (see, e.g.,
Additionally, resilient support members 405 may frictionally engage a ground surface or other suitable surface, preventing and/or reducing movement of one or more modular floor tiles 400. Resilient support members 405 may be formed from various materials suitable for increasing the traction of modular floor tiles 400 relative to various ground or other surfaces. Additionally, resilient support members 405 may be configured to provide additional traction in wet and/or dry condition.
Moreover, resilient support members 405 may be configured such that they are removably secured to modular floor tiles 400. Accordingly, resilient support member 405 may enable relatively easy and cost efficient repair of modular floor tiles 400. For example, resilient support members 405 may be easily removed and replaced in existing sports courts or other surfaces comprising modular floor tiles 400. Additionally, the removable and/or replaceable resilient support members may enable relatively easy and cost efficient customization of modular floor tiles 400. For example, various types of modular floor tiles 400 having various characteristics, such as varying traction and resiliency, may be provided by merely providing resilient support members 405 in modular floor tiles 400 having varying characteristic.
Further, resilient support members 405 may provide modular floor tiles 400 with noise dampening characteristics. For example, resilient support members 405 may prevent relatively rigid portions of modular floor tiles 400 from contacting a ground surface or other surface under modular floor tiles 400. In additional embodiments, resilient support members 405 may reduce excessive noise by slowing the rate at which a portion of a modular floor tile 400 approaches a ground surface or other surface under the tile, thereby lessening the impact force with which modular floor tile 400 contacts the ground surface or other surface.
The spacing of primary and/or secondary support legs positioned under top surface layer 404 (see, e.g., first set of support legs 152 and second set of support legs 154 in
Each of the modular floor tiles 500 may include a support system under the top surface layer 404. According to some aspects, the support system may comprise a multiple-tier suspension system, such as a two-tier suspension system (see, e.g., two-tier suspension system 150 in
According to at least one embodiment, resilient support members 405 may be nested in a group of three, four, or more support legs 452, 454. According to various embodiments, the first set of support legs 452 and/or the second set of support legs 454 may comprise a receiver 415, as illustrated in
According to at least one embodiment, as illustrated in
Support member end surface 487 may be located adjacent to a ground, floor, or other surface when a modular floor tile 400, 500 comprising support member 405 is placed on the ground or floor surface. According to various embodiments, support member end surface 487 may lay substantially flush with an adjacent ground surface when modular floor tile 400, 500 is placed on the ground surface. In additional embodiments, support member end surface 487 may abut and/or conform to a shape of a surface that it faces. In addition, seating portion 493 may be configured such that it is positioned adjacent to an underside of top surface layer 404 when resilient support member 405 is positioned within receiver 415. According to various embodiments, seating portion 493 may have a shape that is complimentary to a shape of a portion of an underside of top surface layer 404, such as, for example, recess 417.
As illustrated in
For example, as illustrated in
Resilient support member 405 may also include one or more perimeter portions in addition first perimeter portion 489, second perimeter portion 490, and third perimeter portion 491. Additional perimeter portions may extend to varying diameters or radial distances respective to support member axis 492. Additional perimeter portions may also extend to diameters or radial distances that are the same as or different than first diameter R1, second diameter R2, and/or third diameter R3. An undulating shape of resilient support member 405, in which first perimeter portion 489, second perimeter portion 490, third perimeter portion 491, and/or additional perimeter portions are formed to varying diameters or radial distances respective to support member axis 492, may facilitate compression and/or rebound of resilient support member 405 in response to a force. For example, the undulating shape of resilient support member 405 described above may enable more stable compression and/or rebound of resilient support member 405 in response to various forces acting on modular floor tile 400, 500. The undulating shape of resilient support member 405 may also facilitate securement of resilient support member in modular floor tile 400, 500, such as, for example, in receiver 415 as described above. The undulating shape may additionally enable greater compressibility of resilient support member 405 and/or may enable greater customizability of resilient support member 405 to suit various sport court requirements.
As additionally shown in
According to at least one embodiment, support member cavity 488 and/or cavity opening 494 may be configured to help seat and/or couple resilient support member 405 to an underside of top surface layer 404. For example, cavity opening 494 of support member cavity 488 may be formed to a shape that is complementary to protrusion 419 and/or recess 417 in the underside of top surface layer 404 (see, e.g.,
Additionally, as illustrated in
Resilient support member 605 may also have a generally undulating surface. For example, resilient support member 605 may be formed to a generally elongated shape having an undulating surface, wherein a radial distance of a surface of resilient support member 605 relative to support member axis 692 varies at different points along the support member surface respective to support member axis 692. In addition, resilient support member 605 may have one or more substantially rectangular shaped perimeter portions. For example, first perimeter portion 689, second perimeter portion 690, and/or third perimeter portion 691 may each be substantially rectangular and/or square in shape.
According to additional embodiments, as illustrated in
Resilient support member 705 may also have a generally undulating surface. For example, resilient support member 705 may be formed to a generally elongated shape having an undulating surface, wherein a radial distance of a surface of resilient support member 705 relative to support member axis 792 varies at different points along the support member surface respective to support member axis 792. In addition, resilient support member 705 may have one or more substantially triangular shaped perimeter portions. For example, first perimeter portion 789, second perimeter portion 790, and/or third perimeter portion 791 may each be substantially triangular in shape.
The preceding description has been provided to enable others skilled in the art to best utilize various aspects of the exemplary embodiments described herein. This exemplary description is not intended to be exhaustive or to be limited to any precise form disclosed. Many modifications and variations are possible without departing from the spirit and scope of the instant disclosure. It is desired that the embodiments described herein be considered in all respects illustrative and not restrictive and that reference be made to the appended claims and their equivalents for determining the scope of the instant disclosure.
Unless otherwise noted, the terms “a” or “an,” as used in the specification and claims, are to be construed as meaning “at least one of.” In addition, for ease of use, the words “including” and “having,” as used in the specification and claims, are interchangeable with and have the same meaning as the word “comprising.”
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Recreation Management, advertisements for Taraflex Sports Flooring, Aacer Flooring, LLC, Action Floor Systems, Aeson Flooring Systems, Centaur Floor Systems, LLC, Swiss Flex, Sport Court International, p. 127; advertisements for Mitchell Rubber Products, Fitness Flooring, Summit Flexible Products, Premier Court, p. 218; advertisement for Aacer Flooring, p. 221; advertisements for SportMaster Sport Surfaces and Swiss Flex, p. 227; advertisement for Sport Court, p. 229; Dec. 2004. |
Grassroots Motosports, advertisement for RaceDeck, p. 61; Article, “Floored—Two Ways to Make Your Shop Floor Look Beautiful,” pp. 125-126, Mar. 2002. |
Athletic Business, advertisement for Dri-Dek, p. 55; advertisements for Rubber Products and Multi-Play Sports Flooring, p. 139; advertisement for Fitness Flooring, p. 167; advertisement for Mateflex, p. 233; advertisements for Centaur Floor Systems and Flex Court, p. 250; advertisement for Athletic Surface Systems (Sports Court), pp. 281-284; Feb. 2006. |
Club Management, advertisement for Duragrid, p. 161; Apr. 2002. |
Athletic Business, advertisement for Sport Court, p. 39; advertisement for Dri-Dek, p. 49; advertisement for VersaCourt, p. 93; Sep. 2004. |
Recreation Management, advertisement for Sport Court, p. 9; advertisement for Dri-Dek, p. 21; May/Jun. 2005. |
Athletic Business, advertisement for Dri-Dek, p. 16; advertisement for SpiderTile, p. 20; advertisement for Mateflex, p. 69; advertisements for Premier Tiles, Prestige Enterprises International, Inc., Rhino Sports, and Robbins Sports Surfaces, p. 139; advertisements for SpiderCourt Inc., Sport Court Inc., and Sport Floors, Inc., p. 141; Apr. 2003. |
Institutional Flooring, Competitive Information, Sport Court, Jan. 2004. |
Advertisement for IceCourt XS, prior to Jun. 16, 2010. |
Brochure for Mateflex, 8 pages, prior to Jun. 16, 2010. |
Number | Date | Country | |
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20140237916 A1 | Aug 2014 | US |
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Parent | 12252168 | Oct 2008 | US |
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Parent | 13784673 | Mar 2013 | US |
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Parent | 12945195 | Nov 2010 | US |
Child | 13784673 | US |
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Parent | 11379109 | Apr 2006 | US |
Child | 12252168 | US | |
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Child | 11379109 | US | |
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Child | 11291002 | US |