INTERLOCKING MODULAR FLOOR TILE
Field of the Invention The present invention relates to the field of modular floor tiles and modular floor tile systems, such as the modular floor tile systems that are installed on an existing floor. The present invention also relates to a connection system for modular floor tiles. The present invention further relates to a free standing modular mat system comprising at least two mats, or tiles.
Background of the Invention Modular floor tiles are often used as components on the construction of a flooring system. The system may be designed as a floor covering for an entire room, or a floor covering for a section if a room. The typical floor system components may be manufactured from, for example, semi-rigid, plasticized, virgin polyvinyl chloride, virgin/reclaimed polyvinyl chloride mixtures, or compression molded rubber. The floor system is suitable to withstand inclement weather, harsh environments, heavy traffic, and resist damage when exposed to harsh chemicals. Primary uses for the modular floor tiles of the present invention include providing lateral support, and providing comfort and reduction of fatigue during walking or standing. Various types of modular floor tiles have increased in popularity due to their versatility.
A free-standing modular floor mat system typically provides a non-slip modular system that optionally is self-draining and has multiple configuration capabilities. Another demand often placed on work environments is that floor mats need to be easily configured and re-configured in the plane of a floor.
Prior art connectors for mat systems have used separate multiple com ectors for attaching one modular mat to another. These separate comiectors have not worked well in practice because they get lost or make alignment between adjacent mats difficult during reinstallations after lifting the modular mats out of the system. The conventional modular floor tiles are not adjustable size-wise, which limit their usefulness with respect to custom sizes. Some prior art floor tile provide connection devices around the periphery of the tile. In those tiles, a secure connection may be sacrificed where the tile must be trimmed. That is, modular tile systems built with these tiles do not provide a secure fitting if trimmed to adjust size. Other prior art mats have required separate connectors, which limit their versatility. These systems have disadvantages because the comiectors may get lost or make proper alignment between adj cent mats difficult during installation or reinstallation. An example of an existing modular floor mat system is U.S. Patent Number 6,505,444, to Jolmson. The '444 patent discloses a free standing modular mat system for creating various selectable combinations of mat configurations by using first and second mats having parallel ribs on the bottom and parallel spaced ribs on the top at right angles to the bottom ribs, and having top and bottom connectors having inter-engaging mating grooves. U.S. Patent Number 5,630,304, to Austin, discloses a quadrilateral floor tile having a downward sloping edge. Two of the sides are formed with integral interlocking strips, with a cavity positioned to mate with a corresponding male connecting member of a neighboring tile. U.S. Patent Number 5,950,378, to Counsel et al., discloses a modular floor tile that may be used to construct athletic playing surfaces including basketball courts and tennis courts. These
tiles comprise a top member made of relatively hard material and a bottom member made from resilient, impact absorbing material. Theses tiles comprise coupling loops about the periphery of the tile that engage posts, also located along the periphery of the tile. U.S. Patent Number 5,907,934 to Austin discloses an interlocking floor tile in the form of a right triangle, with each side having a row of female cavities located adjacent the sides and positioned to mate with a corresponding male connecting member of a neighboring tile. U.S. Patent Number 4,930,286 to Kotler discloses a modular tile for interlocking with other similar tiles that comprises a plastic support grid having a rectangular configuration bounded by a perimeter wall and including a repeating pattern of intersecting cross members with interstitial openings formed in-between. In this tile there are a plurality of support legs coupled to a base side of the cross junctions in general perpendicular orientation. Interlock structure is coupled to and extends outward from the perimeter wall to enable removable attachment with other modular tiles of similar design. U.S. Patent Application Publication Number 2002/0119275 to Williamson discloses a mat system wherein the mats are comprises of a plurality if individual tiles that interlock along complementary edge portions.
Objects and Summary of the Invention One object of the present invention is to provide modular floor tile that can easily be modified to cover a floor of any size or shape, but still cooperatively interlock with another tile of the present invention.
Another object of the present invention is to provide a tile that is easily modified to various sizes, yet interlocks with another tile of the present invention, and provides friction and cushion to a user of the tile. Another object of the present invention is to provide a method of modifying an interlocking floor tile by shearing or cutting a portion of the tile, with the tile still having interlockability with another tile of the present invention on the sheared side of the tile. Another object of the present invention is to provide a modular tile system that can be adjusted in size, but maintain interlockability with like tiles of the present invention on all sides of the adjusted tile. It is a further object of the present invention to provide a modular floor tile that is suitable as a floor covering by absorbing lateral forces and offering traction, but is adjustable in size while maintaining interlockability with like tiles of the present invention. One embodiment of the present invention is an interlocking, modular floor tile that comprises a planar member defined by a perimeter having four sides and a top surface, a plurality of downwardly projecting support legs of common length dispersed pattern- wise inside the perimeter of the planar member and coupled with the top surface, and at least one female interlocking connector element that extends outside the perimeter of the planar member for receiving a support leg of a like tile and thereby forming an interlock with the like tile. Another embodiment of the present invention is a modular floor tile for interconnecting with similar modular floor tiles that comprises a support grid defined by a perimeter having four sides, a plurality of support legs of common length that are dispersed pattern- wise inside the perimeter and being coupled to the grid, and a plurality of female interlocking connector
elements that extend outside the perimeter for receiving a support leg. The support grid may comprise intersecting cross members and may comprise a top surface. Another embodiment of the present invention is a modular tile system of interlocking floor tiles that comprises at least two interlocked tiles, with said at least two interlocked tiles having a planar member that is defined by a perimeter having four sides and a width, the planar member having support legs of common length that are coupled to the planar member and pattern- wise dispersed within the perimeter of the planar member; and at least one interlock coupling device that extends beyond said perimeter and snugly receiving a support leg of a second tile, forming a continuous, generally uniform displacement gap between the perimeters of adjacent tiles. In typical embodiments, the displacement gap is minimal, or there may be a uniform, snug fit. Another embodiment of the present invention is transition tile (or border tile) for a modular tile system that comprises a tile having a perimeter defined by a top surface, first, second, third, and forth side; a female connector extending beyond the perimeter of the first side of the perimeter; and support legs coupled with the top surface and dispersed pattern- wise from the first side to an opposite third side to receive a female member of a corresponding transition tile to form a snug interlock. Another embodiment of the present invention is a method of constructing an interlocking tile floor covering. This embodiment comprises the steps of selecting at least two floor tiles with a planar member defined by a perimeter having four sides, a plurality of support legs of common length dispersed pattern- wise and coupled with the planar member, at least one female interlocking connector element that extends outside the perimeter of the planar member for receiving a support leg and thereby forming an interlock; interlocking said tiles by coupling the
female comiectors with a corresponding support leg; trimming a floor tile to correspond with the desired area desired to be covered, thus forming a trimmed floor tile; and interlocking a support leg of the trimmed tile with a corresponding female interlocking connector of another tile.
Brief Description of the Drawings Figure 1 is a perspective view of the top side of a tile constructed in accordance with the present invention. This embodiment shows a pattern of ridges or elevations to increase friction on the top surface of the tile. Figure 2 is a perspective view of the bottom side of a tile constructed in accordance with the present invention. This embodiment shows support legs dispersed pattern- wise inside the perimeter of the tile and it shows a support grid. Figure 3 is a perspective view of the top side of a transition tile of the present invention. This embodiment can connect with a tile such as the one described in Figure 1. Figure 4 is a perspective view of the bottom side of the tile of Figure 3. It shows support legs coupled with the top surface and dispersed pattern- wise from a first side to an opposite side to receive a female member of a corresponding transition tile to form a snug interlock. Figure 5 is a perspective view of a transition tile and a tile constructed in accordance with the present invention as shown in Figure 1. In this figure, the female comiectors of the transition tile are in position to be received by the male connectors of the modular tile. Figure 6 is a top view of the transition tile of Figure 3. Figure 7 is a top view of the modular tile of Figure 1. Figure 8 is a bottom view that illustrates how multiple tiles of the present invention may be joined together to form a modular tile system. In this figure, two tiles, such as the ones shown
in Figures 1 or 2 are joined with a transition tile such as the one shown in Figure 3. The tiles form a continuous, generally uniform and snug displacement gap between the perimeters of adjacent tiles. Figure 9 shows a top view of a mat/tile/modular tile system of the present invention that incorporates multiple tiles such as those shown in Figure 1 and transition tiles such as those shown in Figure 3. In this embodiment, some of the transition tiles have been triimned to allow snug completion of the transition tile area around a generally rectangular modular tile floor system. Figure 10 is the bottom view of the system show in Figure 9. Figure 11 shows a transition tile that is cut or trimmed to allow completion of a tile system. In the embodiment depicted in this figure, the shorter of the two pieces may be used for an interior corner and the longer piece may be used for an outside corner. Figure 12 shows a transition tile that has been cut or trimmed at an opposite angle as the one shown in Figure 11. Figure 13 shows a bottom view of a mat system of the present invention with a trimmed tile that can be interlocked with an assembly of tiles and transition tiles of the present invention. Figure 14 is a top view of the tile assembly or system of Figure 13. Figure 15 shows a bottom view of a partial tile assembly that is ready to be complete by trimmed modular tiles of the present invention and trimmed transition tiles of the present invention. Figure 16 is a bottom view of a completed interlocking tile system or assembly of the present invention.
Figure 17 is a top view of a completed tile system or assembly of the present invention that has a non-rectangular general shape. The tiles and transition tiles of this embodiment have been trimmed in order to provide said shape. Figure 18 is a bottom of view of the tile assembly of Figure 17. Figure 19 shows a perspective bottom view of the tile assembly of Figure 17. Figure 20 shows a perspective view of a top surface part of a grid that defines a pattern of apertures. This embodiment may be more suitable for use during wet conditions, since the apertures allow water to drain from the surface of the tile.
Detailed Description of the Invention For the purposes of this disclosure, a "mat" or "tile" shall be defined as a covering for the floor or ground. The terms should encompass those covering that have borders around the perimeter edges and also encompass those coverings in which the perimeter has been modified for installation into a recessed area in the floor such as a mat holding well. The term "male" refers to pin or peg-type components. The term "female" refers to the components that have a socket or lug-type compartment that is sized and spaced to accommodate the "male" component. The "male" and "female" components are complimentary to one another in the sense that the "male" components may be securely inserted into the "female" components in a way that provides a mechanism for holding adjacent tiles to one another, as well as holding tiles to adjacent border strips (i.e. transition tiles). As described herein, "male" components may be used to assist in providing vertical support to the mat, whether coupled to a "female" component of an adjacent tile or not. Typically, all male components provide some type of vertical support to the mat.
A typical tile of the present invention may be manufactured by injection or compression molding, and typically comprise a thermoplastic material such as flexible or semi-rigid polyvinyl chloride or thermoplastic elastomer. Additionally a thermosetting plastic such as rubber may be used. Basically any material that is semi-rigid, semi-flexible, or elastomeric (e.g., flexible PVC, thermoplastic elastomers) that are capable of being inj ection molded can be used. Additionally, thermosetting rubbers and thermosetting elastomers capable of being compression molded can be used. The plastic or rubber should exhibit some degree of conformability so as to provide comfortable footing and facilitate trimming and mating of the tiles. Additionally, the material should exhibit a reasonable degree of structural integrity so as to support personnel and light industrial traffic. One of ordinary skill in the art can chose a material based on many desired characteristics of the resulting tile. For example, a material may be that is resistant to oils, greases, weak solvents, and chemicals typical of an industrial environment. A material may b chosen to exhibit a reasonably high coefficient of friction so as to reduce the risk of slipping. Additionally, embodiments of the present invention may also be conditioned to withstand inclement weather or other harsh environments, heavy traffic, and to resist damage when exposed to harsh chemicals. Example of the tiles of the present invention may be constructed using the material of prior art rubber mats described herein, as long as the use of such material will not negatively affect objects of the present invention. In certain embodiments, the material used to manufacture the tiles of the present invention is resilient and impact-absorbing. Additionally, the tiles of the present invention can be modified to include carpet strips, abrasive traction strips, absorption strips, abrasion traction coating, or the like.
As stated above, one embodiment of the present invention is an interlocking, modular floor tile that comprises a planar member defined by a perimeter having four sides and a top surface. Figures 1 and 2 shows such an interlocking, modular floor tile 10. The embodiment shown in Figure 1 comprises a pattern of ridges or elevations 12 to increase friction on the surface, in this case the top surface, of the tile. However, these ridges and various top surface designs are optional and are not known to be critical. In embodiments of the present invention, the top planar surface, may comprise a friction promoting surface coated thereon, as well as or in place of ridges and/or apertures. As shown in Figure 2, this embodiment comprises a plurality of downward projecting support legs 15 which are dispersed pattern-wise inside the perimeter of the tile 10 and coupled with the top surface 11. Female interlocking connectors 20 that extend outside the perimeter of the planar member/modular floor tile 10 are shown. These female interlocking connector elements receive a support leg 15 of a like tile and thereby form an interlock with the like tile. The planar member 10 of this embodiment further comprises a support grid 17, which in this embodiment comprises cross member supports that extend inward from the perimeter and join at cross junctions along a common plane. These cross members 17 may form various patterns about the perimeter of the tile and function to assist in providing vertical support and strength to the tile. Circular supports can be seen in this embodiment as well. In embodiments of the present invention, the top surface 11 may comprise any number of patterns of holes to allow the passage of air or a liquid. These tiles are especially suitable for wet working environments. See Figure 20, which depicts an embodiment where the top surface 11 may defines apertures 13 to allow passage of air or a liquid through the tile.
The support legs 15 are positioned in the pattern such that the tile can be trimmed to a desired size and maintain connectability with female interlocking connectors 20 of a like tile 10. In certain embodiments, the support legs may be positioned such that the tile can be trimmed at approximately three-inch intervals and maintain connectability. This gives the tile of the present invention extreme versatility, size-wise, when being used as a modular tile system of various sizes and shapes. As can be seen in Figures 1 and 2, the female interlocking connector elements, or lugs, 20 are positioned on two sides of the perimeter of the planar member. Accordingly, the corresponding support legs, or male connectors, or pins 15 may be positioned at least on the opposite sides of the tiles. In certain embodiments, such as the one shown in Figures 1 and 2, the male connectors are dispersed throughout the entire area. Where the male connectors are dispersed throughout the entire area, they are preferably dispersed in a pattern that accommodates trimming the tile in multiple locations, and still having at least one male connector in place to engage a lug of an adjacent tile. The tiles 10 of the present invention may incorporate cut indicators perpendicular (or at other angles) from the perimeter to assist in trimming the tile. These cut indicators may be molded edges, grooves or nicks 19 in the support grid as shown in Figure 2 or they may be other type of indicia such as markings. In embodiments of the present invention, the support legs and/or support grid are ground- engaging to assist in providing vertical support to the grid and to the tile itself. The support legs and support grid are typically comprised of the same material as of the tile itself and are, in certain embodiments, resilient, impact-absorbing material.
The module tiles of the present invention maybe produced in multiple sizes. One advantage of the present invention is that multiple sizes may be used within the same modular tiles system, which may include edge pieces and corner pieces. Additionally, the modular tiles of the present invention may be cut or trimmed to enable proper fitting over the floor area to be covered. In embodiments, each side ranges from about 10" (inches) to about 30" (inches) in length. In other embodiments of the present invention, each side may range from about 15" (inches) to about 25" (inches) in length. The total dimension of the time is more dependent on the capability of the manufacturing equipment rather than the functionality of the tile. A manageable size that the inventors have determined works well as far as manufacturing and use are concerned is a time that is about 18" by about 18", not including lugs. The modular tile of the present invention, as depicted in the figures, shows the support legs positioned throughout the area of the tile. Embodiments of the present invention include those where such support legs are positioned in rows to allow communication with coreesponding female connectors of adjacent tiles. As depicted in the drawing, the female connectors appear on two sides of the tile. Corresponding support legs may appear on the opposite two sides of the tile, or may be positioned tlxroughout the perimeter of the tile to provide additional size flexibilities should the tile be trimmed and to provide additional vertical support to the tile. Figures 3, 4 and 6 show transition tiles or border tiles 25 of the present invention. These tiles are designed to communicate with the module tiles 10 such that the transition tiles finish a floor covering. These transition tiles have a perimeter defined by multiple surfaces and female connectors extending beyond the perimeter that may be used to couple with support legs to snugly combine two or more transition tiles together. As shown in Figure 4, which is a view of
the underside of a transition tile, support legs 15 are positioned to be received by the female comiectors 20 attaching to transition tiles as well as support legs designed to commmiicate with the female connectors of the modular tiles 10. In the embodiment depicted in Figures 3 and 4, the female comiectors that are adjacent to female comiectors of a second modular tile or transition tile may be trimmed or removed to allow the remaining male connector 15 to communicate with the female connector of an adjacent tile. This feature provides enhanced flexibility with respect to designing a modular tile system with multiple tiles and multiple transition tiles. The transition tiles may further comprise countersink holes that allow one to more permanently attach the modular tile system to a floor area. In additional embodiments, the transition tile is designed at an angle to provide a first height which is approximately equal to the height of a modular tile 10 and a second height that allows a smoother transition from the floor area that is covered to the height of the modular tile. The transition tiles of the present invention may comprise a support grid to provide additional vertical support to the transition tile, and the support grid may comprise diagonal cross members 18. These diagonal cross members may be used as trimming guides when finishing corners of a mat system. Multiple tiles of the present invention including optional transition tiles may be interlocked to provide modular tile systems. Figures 8-10 and 13-19 show completed or partially completed modular tile systems. Figure 8 shows a system with two modular tiles of the present invention and a transition tile 25. Figure 9 shows an embodiment with two tiles 10 of the present invention bordered completely with transition tiles 25. In this embodiment, transition tiles are trimmed along diagonal tiles to snugly complete the border.
Figures 13 - 16 show how a trimmed tile 10 and/or trimmed transition tiles 25 may be used to complete a modular tile system. Figures 17, 18 and 19 show how the modular tiles and transition tiles of the present invention may be used to form floor coverings of an irregular shape.
The invention thus being described, it is obvious that the same may be carried out in other specific ways than those herein set forth without departing from the spirit and essential characteristics of the invention. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive and all changes as would be obvious to one of ordinary skill in the art and within the meaning and equivalency ranges of the claims are intended to be embraced therein. Throughout this disclosure, various patents and publications are cited. All such patents and publications are incorporated herein by reference in their entirety. Finally, unless otherwise indicated, all numbers expressing quantities or sizes are to be understood as being modified in all instances by the term "about." Accordingly, unless indicated to the contrary, the numerical parameters set forth in the specification and claims are approximations that may vary depending upon the desired characteristic sought.