Interlocking floor system with barbs for retaining covering

Abstract

A flooring system includes multiple polymeric panels that are interlocked into a floor system and then covered with a material such as carpet and artificial turf. A top surface of the polymeric panels includes barbs to hold the material from moving laterally during use.

Description

FIELD

The present invention relates to flooring. More particularly, it refers to features of interlocking polymeric panels for improving drainage and supporting a covering material, the panels forming a floor surface or under laying surface.

BACKGROUND

Surface coverings, such as carpet, linoleum, wood flooring, rubberized flooring system, and tile, need to be laid over a base that will support the surface covering. Commonly, surface coverings are laid over a base of plywood or cement. These base materials are expensive to install, and once installed are difficult to remove. Recreational surfaces frequently need to be moved to different locations because the same site may be used for different activities, such as an ice rink converted to a basketball court or concert stage. A need exists for an inexpensive, easily movable base surface as a stand-alone floor surface or for use in conjunction with multiple surface coverings.

US Pub. No. 2005-0028475-A1 to Barlow describes an “Interlocked Base and an Overlaying Surface Covering,” and is hereby incorporated by reference.

What is needed is an inexpensive, easily movable base surface that supports surface covering materials such as artificial turf, keeping the materials from sliding across the surface and loosing position.

SUMMARY

A flooring system includes multiple polymeric panels that are interlocked, into a floor system and then covered with a covering material such as artificial turf. A top surface of the polymeric panels includes barbs to hold the material from moving laterally during use.

In one embodiment, an interlocked floor system is disclosed including multiple polymeric panels, each molded as an integral body having a planar top surface and a grid structure supporting the top surface and multiple interlocking side surfaces. Each interlocking side surface has upwardly and downwardly facing steps. At least one of the downwardly facing steps has a convex projection on a bottom surface and at least one of the upwardly facing steps has a concave mating dimple on an upper surface. An over hang ledge is formed as an extension of the planar top surface, thereby forming a cavity between the over hang ledge and the upper surface of the upwardly facing step. An under hang ledge is formed in a top surface of the downwardly facing step allowing the downward facing step of a first panel to fit within the cavity of a second panel. A plurality of barbs point upwardly along the planar top surface and interface with a layer of material placed on top of the top planar surface, thereby maintaining position of the material upon the planar top surface. The steps of the side surfaces of the first panel interlock to complementary steps of the second panel, etc.

In another embodiment, an interlocked floor is disclosed including multiple polymeric panels molded as an integral body and having a planar top surface and at least one interlocking side surface. Each of the interlocking side surfaces has upwardly and downwardly facing steps. At least one of the downwardly facing steps has an interlock on a bottom surface and at least one of the upwardly facing steps has a mating interlock on an upper surface. An over hang ledge extends from the planar top surface and forms a cavity between the over hang ledge and the upper surface of the upwardly facing step. An under hang ledge is formed in a top surface of the downwardly facing step allowing for the downward facing step of a first panel to fit within the cavity of a second panel. The top planar surface of the panels is textured (barbed) for maintaining a layer of material such as artificial turf or carpeting in place on the top planar surface, thereby reducing lateral movement of the material with respect to the planar top surface of the multiple polymeric panels. The steps of the side surfaces of the first panel interlock with complementary steps of the second panel, etc.

In another embodiment, a flooring system is disclosed including a multiplicity of one piece sectional molded polymeric panels, each having at least one downwardly facing step and at least one upwardly facing step on a side surface and each having a planar top surface, and a grid structure supporting the top surface. At least one of the downwardly facing steps has a convex projection on a bottom surface and at least one of the upwardly facing steps has a concave mating dimple on an upper surface. An over hang ledge is formed as an extension of the planar top surface forming a cavity between the over hang ledge and the upper surface of the upwardly facing step. An under hang ledge formed in a top surface of the downwardly facing step allowing for the downward facing step of a first panel to snuggly fit within the cavity of a second panel. The top planar surface of the multiple polymeric panels has a surface texture that increases friction and/or reduces lateral movement of a material placed on top of the top planar surface. The steps of the side surfaces of the first panel interlock to complementary steps of the second panel, etc.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention can be best understood by those having ordinary skill in the art by reference to the following detailed description when considered in conjunction with the accompanying drawings in which:

FIG. 1 is a top perspective view of a molded polymeric panel employed to form the interlocked base or floor system.

FIG. 2 is a top perspective view of two adjacent polymeric panels of FIG. 1 ready to be interlocked together at their edges.

FIG. 3 is a top perspective view of two adjacent polymeric panels of FIG. 1 interlocked together at their edges.

FIG. 4 is a top perspective view of two adjacent polymeric panels of FIG. 1 and flat-edged border panels ready to be interlocked together at their edges.

FIG. 5 is a top perspective view of two adjacent polymeric panels of FIG. 1 and flat-edged border panels interlocked together at their edges.

FIG. 6 is a top perspective view of two adjacent polymeric panels of FIG. 1 and round-edged border panels interlocked together at their edges.

FIG. 7 is a bottom perspective view of a molded polymeric panel shown in FIG. 1.

FIG. 8 is a cross-section along line 8-8 of FIG. 3 showing the adjacent polymeric edges in the panels interlocked together.

FIG. 8A is a cross-section along line 8A-8A of FIG. 3 showing the adjacent polymeric edges in the panels interlocked together and held to the subsurface with a spike or screw.

FIG. 9 is a top perspective view of a molded polymeric panel with straight interface edges employed to form the interlocked base or floor system.

FIG. 10 is a top perspective view of two adjacent polymeric panels of FIG. 9 interlocked together at their edges.

FIG. 11 is a cross-section along line 11-11 of FIG. 10 showing the adjacent polymeric edges in the panels interlocked together.

FIG. 12 is a top perspective view of four adjacent polymeric panels of FIG. 1 interlocked together at their edges.

FIG. 13 is a top perspective view of four adjacent polymeric panels with curved outer edges interlocked together at their edges.

FIG. 14 is a top perspective view of four adjacent polymeric panels of FIG. 13 interlocked together at their edges enclosed within a border.

FIG. 15A is a top perspective view of polymeric panels customized to form a sidewalk, ready to be interlocked together at their edges.

FIG. 15B is a top perspective view of polymeric panels with flat interfacing edges customized to form a sidewalk, ready to be interlocked together at their edges.

FIG. 16A is a top perspective view of polymeric panels of FIG. 15A customized to form a sidewalk, interlocked together at their edges.

FIG. 16B is a top perspective view of polymeric panels of FIG. 15B with flat interfacing edges customized to form a sidewalk, interlocked together at their edges.

FIG. 17 is a top perspective view of polymeric panels of FIG. 9 with a brick-face decorative top.

FIG. 18 is a top perspective view of multiple polymeric panels of FIG. 17 along with end-caps, all having a brick-face decorative top and ready to be interlocked.

FIG. 19 is a top perspective view of multiple interlocked polymeric panels of FIG. 17 with end-caps, all having a brick-face decorative top.

FIG. 20 is a top perspective view of polymeric panels of FIG. 9 with a safety top.

FIG. 21 is a top perspective view of multiple interlocked polymeric panels of FIG. 20 with a safety top.

FIG. 22 is a first flow chart of a method of installing the surface.

FIG. 23 is a second flow chart of a method of installing the surface.

FIG. 24 is a third flow chart of a method of installing the surface.

FIG. 25 is a fourth flow chart of a method of installing the surface of the present invention.

FIG. 26 is a fifth flow chart of a method of installing the surface.

FIG. 27 illustrates a top perspective view of a molded polymeric panel with improved top surface interface.

FIG. 28 illustrates a cross sectional view of a molded polymeric panel with improved top surface interface along cut lines 27-27.

FIG. 29 illustrates a bottom perspective view of a molded polymeric panel shown in FIG. 27 with drainage standoffs installed.

FIG. 30 illustrates detailed perspective view the drainage standoffs showing how it is installed onto the polymeric panel.

DETAILED DESCRIPTION

Throughout the following detailed description the same reference numerals refer to the same elements in all figures.

Referring to FIGS. 1, 2, 8 and 8A, panels 100/102 join together to form an interlocked series of panels arranged to be mechanically interlocked together. Each panel 10 has a planar top surface 11 and each panel 10 has upward facing steps 14 and downward facing steps 22. At least one of the downward facing steps 22 contains a downwardly pointing convex projection 24 on their lower surfaces as shown in FIG. 8. At least one of the upward facing steps 14 contains a concave mating dimple 18 on their upper surface. An under hang ledge 20 is provided to allow the downward facing steps 22 to be inserted with the under hang ledge 20 sliding into a cavity formed between the upward facing steps 14 and an overhang ledge 12, thereby engaging the convex projections 24 with concave dimples 18. The overhang ledge is a continuation of the planar top surface 11 of the panel 10. Such an interlock mechanism helps adjacent panels retain planar alignment while providing a tight mechanical interlock.

In embodiments with panels that have more than one pair of steps, it is preferred to configure the panels 10 as shown alternating the upward facing steps with the downward facing steps and with the outer steps 14/22 having the mating convex projections 24 and concave mating dimples 18. In an alternate embodiment, the upward facing steps are in a different order and do not alternate with the downward facing steps.

In some embodiments where the panels are smaller, a single pair of steps 14/22 is sufficient. In some embodiments where the panels are larger, several pair of steps 14/22 is included and more than one pair of steps includes the mating convex projections 24 and concave mating dimples 18.

The panels 10 can be disengaged by pulling them apart. In a preferred embodiment, the top planar surface 11 of the panel 10 is molded as an integral rigid body with the grid structure 25 shown in FIG. 7. In some embodiments, the top planar surface 11 is coated with a surface material such as carpet, linoleum, vinyl, wood, synthetic wood, ceramic tile, plastic tile, artificial turf, etc. In some embodiments, the top planar surface 11 is not coated and an area cover is affixed after the planar panels 10 are installed.

In some embodiments, one or more of the upwardly facing steps 14 include a secondary countersunk hole 16 for accepting an anchor fastener such as a screw or spike 40 without interfering with the interlocking action. It can be seen in FIG. 8A that the screw or spike 40 can hold the polymeric panels 100/102 to a sub floor or the ground.

Additionally, in some embodiments, a wire chase 50 is cut or molded into the sub structure of the panels 10 to permit a wire to run between the panels 10 and a sub floor (not shown). Although called a wire chase 50, this cut or opening molded into the sub structure of the panels 10 also provides for a drainage path in generally horizontal directions.

The molded integral rigid body with grid structure 25 is made from molded filled or non-filled polymers or any other suitable material including rubber, recycled rubber or any rubber-like material. The polymers can include polypropylene, structural urethane foams or other suitable commercially available polyolefins. The rubber can include structural foam and processed recycled automobile tires mixed in a bonding agent.

Referring to FIGS. 2 and 3, two adjacent polymeric panels 10 of FIG. 1 are shown prior to being interlocked together (FIG. 2) and shown interlocked (FIG. 3). The panels 100/102 are pushed together until the concave dimples 18 mate with the convex dimples 24.

In some embodiments, for added stability, a spike or screw 40 is inserted into a secondary recessed bore 16 below one of both of the recessed dimples 18.

In FIG. 4, two adjacent polymeric panels 100/102 of FIG. 2 are shown prior to being interlocked and shown interlocked in FIG. 5. In this embodiment, the panels 100/102 mate with edge panels 106 and corner panels 104. The edge panels 106 and corner panels 104 have flat or smooth outward facing edges and the same interlock mechanism as the polymeric panels 100/102. The panels 100/102/104/106 are pushed together until the concave dimples 18 mate with the convex dimples 24.

Referring to FIG. 6, two adjacent polymeric panels 100/102 of FIG. 1 are interlocked with and round-edged border panels 114/116. The border panels 114/116 of this embodiment have straight (116) or curved edges (114) that taper away from the two polymeric panels 100/102 so as to reduce the chances of tripping over an abrupt edge. In this embodiment, there are side parts 116 that have the same interlock mechanism as the polymeric panels 100/102 to mate directly with the polymeric panels 100/102. The corner parts 114 mate with the side parts 116 in a similar fashion.

FIG. 7 shows a bottom perspective view of a molded polymeric panel 10 with a rigid grid structure 25. It is preferred to fabricate the panels with such a grid structure 25, providing strength and durability while keeping weight and material content to a minimum. It is anticipated that other substructures can be substituted without veering from the present invention, including a solid base, honeycombs, etc. In some embodiments, a wire chase 50 is provided to permit running wires, cables and/or drainage between the polymeric panels 10 and a sub floor (not shown). The wire chase 50 is a series of openings allowing a wire and/or liquids (e.g. water) to pass under the grid structure 25 of the polymeric panels 10 without creating unevenness, bumps or damage to the wire.

Referring to FIGS. 9, 10 and 11, panels 150 of a second embodiment join together to form an interlocked series of panels. In this embodiment, the overhang ledge 32 is extended outward from the panel 150 to form a straight edge. Therefore, when joined with other panels 150/152, the interface edge 154 is straight. In this embodiment, the under hang ledge 20 runs the full length of the downward facing step 22. Each panel 150 has upright facing steps 14 and downward facing steps 22. At least one of the downward facing steps 22 contains a downwardly pointing convex projection 24 on lower surface 22. At least one of the upward facing steps 14 contains a mating concave dimple 18 on its upper surface, as shown in FIG. 11. The overhang ledge 32 as shown in FIG. 11 extends outwardly to approximately the same point as the upward facing step 14. The adjacent panels 150/152 are slid together, inserting the downward facing steps 22 between the upward facing steps 14 and the overhang ledge 32, thereby engaging convex projections 24 with concave dimples 18. FIG. 10 shows two panels 150/152 interlocked. The interlock mechanism including the steps, cavities, convex protrusions and concave mating dimples help adjacent panels retain smooth planar alignment with each other in addition to a tight mechanical interlock.

The panels 150/152 can be disengaged by pulling them apart. In a preferred embodiment, the top planar surface 11 of the panel 150 is molded as an integral rigid body with the grid structure 25 shown in FIG. 7.

In embodiments with panels that have more than one pair of steps, it is preferred to configure the panels 150 as shown with the outer steps 14/22 having the mating convex projections 24 and concave mating dimples 18. In some embodiments where the panels are smaller, a single pair of steps 14/22 is sufficient. In some embodiments where the panels are larger, several pair of steps 14/22 is included and more than one pair of steps includes the mating convex projections 24 and concave mating dimples 18.

As in the previous embodiments, the molded integral rigid body with grid structure 25 is made from molded filled or non-filled polymers or any other suitable material including rubber, recycled rubber or any rubber-like material. The polymers can include polypropylene, structural urethane foams or other suitable commercially available polyolefins. The rubber can include processed, recycled automobile tires mixed in a bonding agent.

FIG. 12 shows four adjacent polymeric panels 100/102/108/109 of FIG. 1 interlocked together as described in FIGS. 10 and 11.

FIG. 13 shows four adjacent polymeric panels with curved outer edges 120/122/128/129 interlocked together as described above. These panels 120/122/128/129 are either fabricated with smooth or curved outer edges or are cut to shape during installation.

FIG. 14 shows four adjacent polymeric panels with curved outer edges 120/122/128/129 interlocked together as described above enclosed within a border 130. The border 130 is, for example, a molded border shaped to the contour of the outer edges of the curved panels 120/122/128/129, or an area of sand, dirt or concrete that is backfilled around the panels 120/122/128/129 as in a patio arrangement.

FIG. 15A shows the basic interlock mechanism of FIG. 1 with polymeric panels 101/141/143 customized to form a sidewalk. These panels 101/141/143 have the interlock mechanism of the present invention at one side or two opposing sides and have smooth straight or curved edges on the remaining sides. Multiple panels 101/141/143 can be arranged to provide various lengths and configurations of walkways or sidewalks.

FIG. 15B shows the basic interlock mechanism of FIG. 9 with polymeric panels 151/161/163 customized to form a sidewalk with straight interface lines. These panels 151/161/163 have the interlock mechanism of the second embodiment of the present invention (FIG. 9) at one side or two opposing sides and have smooth straight or curved edges on the remaining sides. Multiple panels 151/161/163 can be arranged to provide various lengths and configurations of walkways or sidewalks.

FIG. 16A shows the panels 101/141/143 of FIG. 15A interlocked together at their edges.

FIG. 16B shows the panels 151/161/163 of FIG. 15B interlocked together at their edges.

FIG. 17 shows the polymeric panels of FIG. 9 with a brick-face decorative top 170. The panels of the present invention are deployable with a plain surface, with a decorative surface as in FIG. 17 or with a covering surface such as carpet, linoleum, vinyl, wood, synthetic wood, tile or artificial turf. FIG. 17 shows a brick-shaped top, one example of the many different decorative tops that are possible with the present invention. It is equally viable to affix a brick façade and grout on top of a panel with a plain, planar surface to achieve a similar look and shape with the feel of real brick.

FIG. 18 shows multiple polymeric panels 170 of FIG. 17 along with end-caps 172/174, all having a molded brick-face decorative top and ready to be interlocked. The end-caps 172/174 utilize the same system to interlock.

FIG. 19 shows the multiple polymeric panels 170 and end-caps 172/174 of FIG. 17 interlocked, forming a patio or deck.

FIG. 20 shows a polymeric panel of FIG. 9 with a safety top having molded projections 182 pointing upward from a top surface. The safety projections 182 are molded into the panel 180 or molded separately and affixed to the top surface of the panel 180 during manufacturing or installation. If the safety surface is molded into the top surface of the panel 180, it is preferred that the panel and/or the safety surface be molded from a non-skid material such as rubber or a rubber-like material. In some embodiments, drain holes 184 are provided to reduce rain-water build-up.

FIG. 21 shows four interlocked polymeric panels of FIG. 20 with molded projections 182 pointing upward. As shown, when many panels 180 form a safety surface in an area subject to rain or sprinkling, the optional drain holes 184 help prevent water build-up on the top surface.

In one embodiment, interlocked panels 10 with a synthetic grass covering can be used on driving ranges or practice facility for a golf ball hitting area. The configuration of interlocked panels 10 can be longitudinal, squared, rectangular or other geometric or irregular shape, and can be used, for example, outdoors over grass, dirt or sand or indoors over concrete, ice or plywood or as a substitute for a concrete or plywood base. The interlocked panels 10 can be covered with commercially available surfaces, such as SPORT COURT™ athletic floor tiles, hardwood flooring, synthetic wood floor, carpet or linoleum that are easily installed over the interlocked panels and can be removed and reassembled at alternate locations.

Referring to FIG. 22, a first flow chart of a method of installing the surface of the present invention is described. The first step is to remove a percentage of the existing surface 194. Next, a more suitable material is back-filled 196 to create firmness when compacted and to improved drainage. Typical field installations require between 6 inches and 18 inches of earth removal depending on drainage and frost heave. The depth of excavation required is decided by the installer and the soil engineers.

The field profile and surface is then prepared 204 as required by the site engineer. For example, the field is crowned, as in typical American football or leveled as in a typical soccer field. The preparation includes any needed water pitch and drainage such as perimeter drain collection areas, underground collection containers or straight percolation into the ground. The site engineers typically design the field profile and surface for rain water management.

Once the field profile has been achieved, the area is compacted 206. The compacting 206 produces a firm, smooth area.

Next, a material is laid on the prepared earth 208 and secured to the ground 209 with spikes. Typically, this material is either a pervious or non-pervious geo textile and is determined based on the installation site soils, environmental characteristics and methodology of storm water management.

Next, the interlocked panels 10 of the present invention are installed. This installation includes joining the interlocking interlocked panels 10 of the present invention 210, optionally inserting gap spacers 211 creating a predetermined, gap width between the interlocked panels 10 to allow for the proper expansion and contraction that is typical with the selected polymers. Other methods of creating a predetermined gap width between the interlock panels 10 are anticipated including using any object of suitable size to urge the interlock panels 10 apart, for example, a screw driver, etc. If a tapered edge is required, the joining of the interlocking panels 10 includes joining of tapered edge interlocked panels 10 along the outermost edge, thereby creating a slight ramp up to the interlocked panels 10. Other interlocked panels 10 with various edge configurations are anticipated as well.

Note that the interlocked panels 10 allow water to pass either through drainage holes 184 (see FIGS. 20 and 20) or through the gaps between the interlocked panels 10. Water beneath the interlocked, panels 10 is permitted to move laterally (approximately horizontally) beneath the interlocked panels 10 through the wire chases 50 in the bottom ribs of the interlocked panels 10.

The outside perimeter interlocked panels 10 are optionally screwed together using fasteners such as self-tapping screws 212. The fasteners are left slightly loose to allow for expansion.

Next, if spikes are needed, the spikes 40 (see FIGS. 2 and 3) are driven (installed) 214 through the existing screw holes 18 along the outside perimeter of the interlocked panels 10. The spikes, for example, are made from stainless steel, plastic or other suitable material. It is recommend, but not required, to install a spike every 3 to 4 interlocked panel 10. When used, the spikes 40 reduce movement of the interlocked panels 10 within the confines of the interlocked panel system and prevent expansion of the overall size during heating/cooling.

Next, the spacers are removed 216.

Next, a sheet of synthetic turf is now rolled out 218 on to the interlocked panels 10. There are many types of turf such as polypropylene, polyethylene, nylon or combinations thereof. The synthetic turf typically includes a backing system, but this is not required. Some backing systems have anti slip backing while others do not. If multiple sheets of synthetic turf are needed, the sheets of synthetic turf are seamed together 220 using existing methods such as sewing, hook and loop connections, hot melt glue, tape and seam cloth, and chemical glues.

Once the sheet(s) of synthetic turf have been rolled out and seamed together, the edges of the sheet(s) of synthetic turf are disposed 222. If desired, the edges of the sheet(s) of synthetic turf are left as a loose lay installation. Alternately, the edges of the sheet(s) of synthetic turf are buried the ground around the perimeter of the field, typically buried in around 6 inches of ground (e.g., soil, pebbles, etc.)

If needed, the sheet(s) of synthetic turf are affixed 224 to the interlocked panels 10. The preferred method of affixing is to wait for the sheet(s) of synthetic turf to acclimate 224 to the weather (typically 24 hours but any amount of time is anticipated, including one second), then stretching 226 the synthetic turf to make it flat then securing 228 the synthetic turf to the interlocked panels 10 along the perimeter. It is preferred to install staples though the synthetic turf and into the interlocked panels 10, preferably with a pneumatic stapler or other staple device. It is preferred to staple at intervals of every several inches around the perimeter working from one side of the field to the other while pulling the synthetic turf tight as progress is made.

If needed, after the synthetic turf is installed, the field is in-filled 230 to create ballast in the synthetic turf. Accepted methods of infilling include sand, rubber infill, rubber coated sand or combinations. Other infill products are anticipated in the present invention.

Referring to FIG. 23, a second flow chart of a method of installing the surface of the present invention is described. The vegetation on the existing area such as an existing grass field is eliminated 200. This is done as known in the industry including, but not limited to, killing the vegetation with a weed-killing agent or scalping the vegetation down to the dirt level.

Once the vegetation has been eliminated, any low areas are filled and any high areas are reduced to the level of the adjoining area 202.

The field profile and surface is then prepared 204 as required by the site engineer. For example, the field is crowned, as in typical American football or leveled as in a typical soccer field. The preparation includes any needed water pitch and drainage such as perimeter drain collection areas, underground collection containers or straight percolation into the ground. The site engineers typically design the field profile and surface for rain water management.

Once the field, profile has been achieved, the area is compacted 206. The compacting 206 produces a firm, smooth area.

Next, a material is laid on the prepared earth 208 and secured to the ground with spikes 209. Typically, this material is either a pervious or non-pervious geo textile and is determined based on the installation site soils, environmental characteristics and methodology of storm water management.

Next, the interlocked panels 10 of the present invention are installed. This installation includes joining the interlocking interlocked panels 10 of the present invention 210 and optionally inserting gap spacers 211 creating a predetermined gap width between the interlocked, panels 10 to allow for the proper expansion and contraction that is typical with the selected polymers. Note, other methods of creating such a gap are known as described previously. If a tapered edge is required, the joining of the interlocking panels 10 includes joining of tapered edge interlocked panels 10 along the outermost edge, thereby creating a slight ramp up to the interlocked panels 10. Other interlocked panels 10 with various edge configurations are anticipated as well.

Note that the interlocked panels 10 allow water to pass either through drainage holes 184 (see FIGS. 20 and 21) or through the gaps between the interlocked panels 10. Water beneath the interlocked, panels 10 is permitted to move laterally (approximately horizontally) beneath the interlocked panels 10 through the wire chases 50 in the bottom ribs of the interlocked panels 10.

The outside perimeter interlocked panels 10 are optionally screwed together 212 using fasteners such as self-tapping screws. The fasteners are left slightly loose to allow for expansion.

Next, if spikes 40 (see FIGS. 2 and 3) are needed, the spikes 40 are driven/installed 214 through the existing screw holes 18 along the outside perimeter of the interlocked panels 10. It is recommend, but not required, to install a spike 40 every 3 to 4 interlocked panel 10. When used, the spikes reduce movement of the interlocked panels 10 within the confines of the interlocked panel system and prevent expansion of the overall size during heating/cooling.

Next, the spacers are removed 216.

Next, a sheet of synthetic turf is now rolled out 218 on to the interlocked panels 10. There are many types of turf such as polypropylene, poly ethylene, nylon or combinations thereof. The synthetic turf typically includes a backing system. Some backing systems have anti slip backing while others do not. If multiple sheets of synthetic turf are needed, the sheets of synthetic turf are seamed together 220 using existing methods such as sewing, hook and loop connections, hot melt glue, tape and seam cloth, and chemical glues.

Once the sheet(s) of synthetic turf have been rolled out 218 and seamed together 220, the edges of the sheet(s) of synthetic turf are disposed 222. If desired, the edges of the sheet(s) of synthetic turf are left as a loose lay installation. Alternately, the edges of the sheet(s) of synthetic turf are buried the ground around the perimeter of the field, typically buried in around 6 inches of ground (e.g., soil, pebbles, etc.)

If needed, the sheet(s) of synthetic turf are affixed to the interlocked panels 10. The preferred method of affixing is to wait 224 for the sheet(s) of synthetic turf to acclimate to the weather (typically 24 hours but any amount of time is anticipated including one second), then stretching 226 the synthetic turf to make it flat then securing 228 the synthetic turf to the interlocked panels 10 along the perimeter. It is preferred to install staples though the synthetic turf and into the interlocked panels 10, preferably with a pneumatic stapler or other staple device. It is preferred to staple at intervals of every several inches around the perimeter working from one side of the field to the other while pulling the synthetic turf tight as progress is made.

If needed, after the synthetic turf is installed, the field is in-filled 230 to create ballast in the synthetic turf. Accepted methods of infilling include sand, rubber infill, rubber coated sand or combinations. Other infill products are anticipated in the present invention.

Referring to FIG. 24, a third flow chart of a method of installing the surface of the present invention is described. In installations of athletic courts, often the top layer of the interlocking panels 10 is the final surface. The interlocked panels 10 are the finished surface (unless the client chooses to cover the court with, for example, a synthetic grass suitable for tennis or lawn bowling). In some embodiments, storm water management techniques are not needed since proper water drainage is often provided by the slope and pitch of the sub grade.

The first step is to remove a percentage of the existing surface 194. Next, a more suitable material is back-filled 196 to create firmness when compacted and improved drainage. Typical field installations require between 6 inches and 18 inches of earth removal depending on drainage and frost heave. The depth of excavation required is decided by the installer and the soil engineers.

The field profile and surface is then prepared 204 as required by the site engineer. For example, the field is crowned, as in typical American football or leveled as in a typical soccer field. The preparation includes any needed water pitch and drainage such as perimeter drain collection areas, underground collection containers or straight percolation into the ground. The site engineers typically design the field profile and surface for rain water management.

Once the field profile has been achieved, the area is compacted 206. The compacting 206 produces a firm, smooth area.

Next, a material is laid on the prepared earth 208 and secured to the ground with spikes 209. Typically, this material is either a pervious or non-pervious geo textile and is determined, based on the installation site soils, environmental characteristics and methodology of storm water management.

Next, the interlocked panels 10 of the present invention are installed. This installation includes joining 210 the interlocking interlocked panels 10 of the present invention, optionally inserting 211 gap spacers (or spacing with a tool) having a predetermined gap width between the interlocked panels 10 to allow for the proper expansion and contraction that is typical with the selected polymers. If a tapered edge is required, the joining of the interlocking panels 10 includes joining of tapered edge interlocked panels 10 along the outermost edge, thereby creating a slight ramp up to the interlocked panels 10. Other interlocked panels 10 with various edge configurations are anticipated as well.

Note that the interlocked panels 10 allow water to pass either through drainage holes or through the gaps between the interlocked panels 10. Water beneath the interlocked panels 10 is permitted to move laterally (approximately horizontally) beneath the interlocked panels 10 through the wire chases 50 in the bottom ribs of the interlocked panels 10.

The outside perimeter interlocked panels 10 are optionally screwed together using fasteners such as self-tapping screws 212. The fasteners are left slightly loose to allow for expansion.

Next, if spikes 40 (see FIGS. 2 and 3) are needed, the spikes 40 (e.g., stainless steel spikes) are driven/installed 214 through the existing screw holes 18 along the outside perimeter of the interlocked panels 10. It is recommend, but not required, to install a spike 40 every 3 to 4 interlocked panel 10. When used, the spikes 40 reduce movement of the interlocked panels 10 within the confines of the interlocked panel system and prevent expansion of the overall size during heating/cooling.

Finally, if inserted, the spacers are removed 216.

Referring to FIG. 25, a fourth flow chart of a method of installing the surface of the present invention for walkways and patios is described. Walkway and patio, residential and commercial installations start with eliminating vegetation 250 either using a vegetation killer or mowing to the earth level. It is preferred to avoid breaking the surface.

Next, fill material such as decomposed granite or limestone road screening material is added 252 to fill any low areas.

Next, the entire area is compacted 254, creating a firm smooth area. The area need not be level or flat but it is preferred that the area be smooth so the interlocked panels 10 rest evenly on the sub base.

Next, the area is covered 256 with a material to reduce weeds and create additional stability for the interlocked panels 10.

Next, the interlocked panels 10 are prepared 258, if needed, by cutting them to shape (e.g., to create custom designs or use the transition edges to create a ramp down to the existing grade) and the interlocking panels 10 are joined 260 and placed on the surface 262. If desired or needed, the interlocking panels 10 are held together with fasteners as previously described and, if desired, spikes 40 are installed to hold the interlocking panels 10 in place.

If desired, backfill 264 around the interlocking panels 10 up to the top of the panels to create the illusion the entire structure is built in to the ground.

The above description has described specific structural details in applying the invention. However, it will be within one having skill in the art to make modifications without departing from the spirit and scope of the underlying inventive concept of this interlock panel. The invention is not limited to the structure described and includes such modifications as are substantially equivalent to the elements of the interlock panels with or without a surface covering.

Referring to FIG. 26, a fifth flow chart of a method of installing the surface of the present invention is described. This method is useful for installing over existing hard surfaces such as concrete, asphalt and wood such as an existing tennis court or a roof.

The interlocked panels 10 of the present invention are installed over the existing surface. This installation includes joining the interlocking interlocked panels 10 of the present invention 210, optionally inserting gap spacers 211 creating a predetermined gap width between the interlocked panels 10 to allow for the proper expansion and contraction that is typical with the selected polymers. Other methods of creating a predetermined gap width between the interlock panels 10 are anticipated including using any object of suitable size to urge the interlock panels 10 apart, for example, a screw driver, etc. If a tapered edge is required, the joining of the interlocking panels 10 includes joining of tapered edge interlocked panels 10 along the outermost edge, thereby creating a slight ramp up to the interlocked panels 10. Other interlocked panels 10 with various edge configurations are anticipated as well.

Note that the interlocked panels 10 allow water to pass either through drainage holes 184 (see FIGS. 20 and 20) or through the gaps between the interlocked panels 10. Water beneath the interlocked panels 10 is permitted to move laterally (approximately horizontally) beneath the interlocked panels 10 through the wire chases 50 in the bottom ribs of the interlocked panels 10.

The outside perimeter interlocked panels 10 are optionally screwed together using fasteners such as self-tapping screws 212. The fasteners are left slightly loose to allow for expansion.

Next, if spikes are needed, the spikes 40 (see FIGS. 2 and 3) are driven (installed) 214 through the existing screw holes 18 along the outside perimeter of the interlocked panels 10. The spikes, for example, are made from stainless steel, plastic or other suitable material. It is recommend, but not required, to install a spike every 3 to 4 interlocked panel 10. When used, the spikes 40 reduce movement of the interlocked panels 10 within the confines of the interlocked panel system and prevent expansion of the overall size during heating/cooling.

Next, the spacers are removed 216.

Next, if desired, a sheet of synthetic turf is now rolled out 218 on to the interlocked panels 10. There are many types of turf such as polypropylene, polyethylene, nylon or combinations thereof. The synthetic turf typically includes a backing system, but this is not required. Some backing systems have anti slip backing while others do not. If multiple sheets of synthetic turf are needed, the sheets of synthetic turf are seamed together 220 using existing methods such as sewing, hook and loop connections, hot melt glue, tape and seam cloth, and chemical glues.

Once the sheet(s) of synthetic turf have been rolled out and seamed together, the edges of the sheet(s) of synthetic turf are disposed 222. If desired, the edges of the sheet(s) of synthetic turf are left as a loose lay installation. Alternately, the edges of the sheet(s) of synthetic turf are buried the ground around the perimeter of the field, typically buried in around 6 inches of ground (e.g., soil, pebbles, etc.)

If needed, the sheet(s) of synthetic turf are affixed 224 to the interlocked panels 10. The preferred method of affixing is to wait for the sheet(s) of synthetic turf to acclimate 224 to the weather (typically 24 hours but any amount of time is anticipated, including one second), then stretching 226 the synthetic turf to make it flat then securing 228 the synthetic turf to the interlocked panels 10 along the perimeter. It is preferred to install staples though the synthetic turf and into the interlocked panels 10, preferably with a pneumatic stapler or other staple device. It is preferred to staple at intervals of every several inches around the perimeter working from one side of the field to the other while pulling the synthetic turf tight as progress is made.

If needed, after the synthetic turf is installed, the field is in-filled 230 to create ballast in the synthetic turf. Accepted methods of infilling include sand, rubber infill, rubber coated sand or combinations. Other infill products are anticipated in the present invention.

Referring to FIGS. 27 and 28, a top perspective view and a cross sectional view of a molded polymeric panel with improved top surface interface is shown. One of the concerns when installing a planar material 23 (e.g. synthetic grass, artificial turf, carpet, foam padding, flooring, floor covering, indoor/outdoor floor covering, molded plastic sport tiles, wood, plastic floor tiles, ceramic tiles, pavers, a layer of brick, etc.) over polymeric panels (or other base materials such as foam pads, concrete or gravel) is the potential for the planar materials to slide. These planar materials 23 (e.g. synthetic turfs) are made with a variety of backings that are often times slippery resulting in shifting and sliding on the polymeric panels on which they installed (typically by loosely laying on top of the array of polymeric panels).

The polymeric panels 10A in FIGS. 27 and 28 have raised pointed barbs 19 elevated above the surface 11A of the polymeric molded panel 10A in a plurality of locations across the surface 11A of the top planer area of the panel 10A.

The planar material 23 is set on top of the polymeric panels 10A after they are installed (interlocked) and the barbs 19 contact the underside of the planar material 23 and, with some planar materials 23, the barbs 19 partially penetrate the under surface of the planar material 23. When pressure from, for example, foot traffic or vehicle traffic or any other downward load force comes in contact with the planar material 23 the barbs 19 provide a high coefficient of friction, reducing the lateral movement of the planar material 23 keeping the planar material 23 from sliding or shifting during, for example, athletic usage, foot traffic and vehicle traffic. The barbs 19 also increase friction, thereby decreasing the chance of slipping when walking on the polymeric panels 10A.

In some embodiments, the barbs 23 are set atop lands 17 that restrict, the depth at which the barbs 19 pierce the planar material 23. In addition, the lands 17 are set higher than the base surface 11A of the polymeric panels 10A, allowing water and other fluids to travel between the planar material 23 and the base surface 11A of the polymeric panels 10A, draining through a plurality of drain holes 21.

Although shown on polymeric panels 10A having a very specific means for interlocking, having alternating steps 14/22, over hang ledges 12 and under hang ledges 20, polymeric panels having barbs 23 and any means for interlocking is anticipated. For example, in another embodiment, interlocking polymeric panels with barbs 23 are interlocked by way of symmetrical keystone interlocks (not shown) or are interlocked by way of an adhesive (not shown).

Referring to FIGS. 29 and 30, a bottom perspective view of a molded polymeric panel shown in FIG. 27 with drainage standoffs 31 installed is shown. In installations on hard surfaces such as concrete, the drainage standoffs 31 lift the polymeric panels 10/10A off of the hard surface to increase drainage. The drainage standoffs 31 attach to the bottom grid structure 25 and raise the grid structure 25.

In FIG. 30, the drainage standoffs 31 are shown being installed onto the polymeric panel 10A. The drainage standoffs 31 have a raised area 33 that interfaces with the hard surface (not shown) and one or more legs 35 that press-fit onto the grid structure 25. Although shown having a specific shape, the drainage standoffs 31 are anticipated, to be in any shape as long as they attach to the grid structure 25 and hold the polymeric panels 10/10A a distance off of a solid floor.

Although shown on polymeric panels 10A having a very specific means for interlocking, having alternating steps 14/22, over hang ledges 12 and under hang ledges 20, it is anticipated that the standoffs 31 are useful for any polymeric panels having any means for interlocking. For example, in another embodiment, the standoffs 31 are installed in the grid system 25 of interlocking polymeric panels that are interlocked by way of symmetrical keystone interlocks (not shown) or that are interlocked by way of an adhesive (not shown).

Equivalent elements can be substituted for the ones set forth above such that they perform in substantially the same manner in substantially the same way for achieving substantially the same result.

It is believed that the system and method of the present invention and many of its attendant advantages will be understood by the foregoing description. It is also believed that it will be apparent that various changes may be made in the form, construction and arrangement of the components thereof without departing from the scope and spirit of the invention or without sacrificing all of its material advantages. The form herein before described being merely exemplary and explanatory embodiment thereof. It is the intention of the following claims to encompass and include such changes. For example, throughout the description, the convex projection is located on the bottom of the downward facing step and the concave dimple is located on the top of the upward facing step, but the present invention works equally as well with the convex projection located on the top of the upward facing step and the concave dimple on the bottom of the downward facing step.

Claims

1. An interlocked floor system comprising: multiple polymeric panels molded as an integral body having a planar top surface and a grid structure supporting the top surface and multiple interlocking side surfaces;each interlocking side surface having upwardly and downwardly facing steps, at least one of the downwardly facing steps have a convex projection on a bottom surface, at least one of the upwardly facing steps have a concave mating dimple on an upper surface;an over hang ledge formed as an extension of the planar top surface, thereby forming a cavity between the over hang ledge and the upper surface of each of the upwardly facing steps;an under hang ledge formed in a top surface of each of the downwardly facing steps allowing the downward facing steps of a first panel of the multiple polymeric panels to fit within the cavities of a second panel of the multiple polymeric panels; anda plurality of barbs, the barbs pointing upwardly along the planar top surface and the barbs interfacing with a layer of planar material placed on top of the top planar surface of the multiple polymeric panels, thereby maintaining a position of the planar material upon the planar top surface;whereas the steps of the side surfaces of the first of the multiple polymeric panels interlock to complementary steps of the second panel of the multiple polymeric panels.

2. The interlocked floor system according to claim 1, wherein the upwardly and downwardly facing steps alternate along the multiple interlocking side surfaces.

3. The interlocked floor system according to claim 1, wherein at least one side of at least one of the panels is flat.

4. The interlocked floor system according to claim 1, wherein at least one side of at least one of the panels is curved.

5. The interlocked floor system according to claim 1, further comprising a plurality of standoffs, each of the standoffs press fit onto the grid structure.

6. The interlocked floor system according to claim 1, wherein the planar material is artificial turf.

7. The interlocked floor system according to claim 1, wherein the planar material is selected from the group consisting of synthetic grass, artificial turf, carpet, foam padding, flooring, floor covering, indoor/outdoor floor covering, molded plastic sport tiles, wood, plastic floor tiles, ceramic tiles, pavers and a layer of brick.

8. An interlocked floor comprising: multiple polymeric panels molded as an integral body having a planar top surface and at least one interlocking side surfaces;each of the at least one interlocking side surfaces having upwardly and downwardly facing steps, at least one of the downwardly facing steps having a means to interlock on a bottom surface, at least one of the upwardly facing steps having a mating means to interlock on an upper surface;an over hang ledge extending from the planar top surface and forming a cavity between the over hang ledge and the upper surface of each of the upwardly facing steps;an under hang ledge formed in a top surface of each of the downwardly facing steps such that the downward facing step of a first panel of the multiple polymeric panels fits within the cavity of a second panel of the multiple polymeric panels; anda means for maintaining a layer of planar material in place on the top planar surface of the multiple polymeric panels, thereby reducing lateral movement of the planar material with respect to the planar top surface of the multiple polymeric panels;whereas the steps of the side surfaces of the first panel interlock with complementary steps of the second panel.

9. The interlocked floor according to claim 8, wherein the upwardly and downwardly facing steps alternate along the multiple interlocking side surfaces.

10. The interlocked floor according to claim 8, wherein at least one side of the panel is flat.

11. The interlocked, floor according to claim 8, wherein the means for maintaining the layer of planar material comprises a plurality of barbs, the barbs pointing upwardly along the planar top surface and the barbs interfacing with the layer of planar material, thereby reducing the lateral movement of the planar material with respect to the planar top surface of the multiple polymeric panels.

12. The interlocked floor according to claim 8, further comprising a plurality of standoffs, each of the standoffs press fit onto the grid structure.

13. The interlocked floor according to claim 8, wherein, the planar material is artificial turf.

14. The interlocked floor according to claim 8, wherein the planar material is carpet.