A floor tile is disclosed that includes a metal frame, a backing plate, and a plurality of tiles assembled to the metal frame and the backing plate. The metal frame defines a plurality of openings, and has a thickness T. The openings are separated by a plurality of connected strips that are coated with an anti-slip coating. The backing plate is attached to a bottom side of the metal frame. The plurality of tiles are each assembled into one of the plurality of openings with the backing plate supporting the tiles. The tiles have a height H that is less than T and have a top surface that is recessed below the anti-slip coating on the connected strips.

A floor tile is disclosed that includes a metal frame, a backing plate, and a plurality of tiles assembled to the metal frame and the backing plate. The metal frame defines a plurality of openings, and has a thickness T. The openings are separated by a plurality of connected strips that are coated with an anti-slip coating. The backing plate is attached to a bottom side of the metal frame. The plurality of tiles are each assembled into one of the plurality of openings with the backing plate supporting the tiles. The tiles have a height H that is less than T and have a top surface that is recessed below the anti-slip coating on the connected strips.

The present disclosure relates generally to surface panels for covering a building surface. The disclosure relates more particularly to a surface panel kit and system including a set of panels for attaching to a support structure. Each of the panels includes opposing ends, and each end includes one of a group of end configurations. A first end configuration is mateable with a first portion of the group and is unmateable with a second portion of the group, and a second end configuration is mateable with a third portion of the group and is unmateable with a fourth portion of the group. The set of panels includes at least three panel types including a first panel type with the first and second end configurations, a second panel type with the first and without the second end configurations, and a third panel type with the second and without the first end configurations.

The present disclosure relates generally to surface panels for covering a building surface. The disclosure relates more particularly to a surface panel kit and system including a set of panels for attaching to a support structure. Each of the panels includes opposing ends, and each end includes one of a group of end configurations. A first end configuration is mateable with a first portion of the group and is unmateable with a second portion of the group, and a second end configuration is mateable with a third portion of the group and is unmateable with a fourth portion of the group. The set of panels includes at least three panel types including a first panel type with the first and second end configurations, a second panel type with the first and without the second end configurations, and a third panel type with the second and without the first end configurations.

A floor tile is disclosed that includes a metal framework that supports a plurality of tiles. The metal framework defines recesses having a depth D that are separated by ridges. The ridges are coated with an anti-slip coating. The tiles are each assembled into one of the recesses. The tiles have a height H that is less than D and a top surface that is recessed below the anti-slip coating on the ridges. Methods for making and installing the floor tile are disclosed that includes the steps of applying an anti-slip coating to an upper surface of a metal framework. Assembling a plurality of tiles into the recesses. An adhesive is applied between the tiles and the recesses to secure the tiles with the top surface of the tiles being recessed relative to the ridges. The floor tile is installed on a floor with an adhesive.

A floor tile is disclosed that includes a metal framework that supports a plurality of tiles. The metal framework defines recesses having a depth D that are separated by ridges. The ridges are coated with an anti-slip coating. The tiles are each assembled into one of the recesses. The tiles have a height H that is less than D and a top surface that is recessed below the anti-slip coating on the ridges. Methods for making and installing the floor tile are disclosed that includes the steps of applying an anti-slip coating to an upper surface of a metal framework. Assembling a plurality of tiles into the recesses. An adhesive is applied between the tiles and the recesses to secure the tiles with the top surface of the tiles being recessed relative to the ridges. The floor tile is installed on a floor with an adhesive.

A structural element, including a base portion and a connecting central pin, has its base portion formed hallow, and having an internal reinforcement in the shape of WOW or MOM, to connect these elements with an insertable central pin so that the cross-section of the pin corresponds to the shape of the chamber between the reinforcements, when the upper surface of the structural element has longitudinal grooves, and is made from a modified polymer or elastomeric material comprising India rubber mixtures. The foundation is monomer ethylene propylene diene or natural rubber or styrene-butadiene rubber and/or combinations of the natural rubber/styrene-butadiene rubber, or thermoplastic elastomers, whose base is monomer ethylene-propylene-diene or polypropylene/monomer ethylene-propylene-diene or polyvinylchloride, or thermoplastic vulcanizates, whose base is monomer ethylene-propylene-diene and polyethylene or natural and/or synthetic rubber, modified by polyethylene or polypropylene.

A structural element, including a base portion and a connecting central pin, has its base portion formed hallow, and having an internal reinforcement in the shape of WOW or MOM, to connect these elements with an insertable central pin so that the cross-section of the pin corresponds to the shape of the chamber between the reinforcements, when the upper surface of the structural element has longitudinal grooves, and is made from a modified polymer or elastomeric material comprising India rubber mixtures. The foundation is monomer ethylene propylene diene or natural rubber or styrene-butadiene rubber and/or combinations of the natural rubber/styrene-butadiene rubber, or thermoplastic elastomers, whose base is monomer ethylene-propylene-diene or polypropylene/monomer ethylene-propylene-diene or polyvinylchloride, or thermoplastic vulcanizates, whose base is monomer ethylene-propylene-diene and polyethylene or natural and/or synthetic rubber, modified by polyethylene or polypropylene.

The disclosure relates to an outdoor flooring assembly for securing flooring trays to improve stability and wind uplift resistance. The flooring trays each include a plurality of securement mechanisms coupled to a bottom surface thereto, the securement mechanisms designed to interconnect with one another to securely retain adjacent trays together and minimize the risk that any individual tray is dislodged.

The disclosure relates to an outdoor flooring assembly for securing flooring trays to improve stability and wind uplift resistance. The flooring trays each include a plurality of securement mechanisms coupled to a bottom surface thereto, the securement mechanisms designed to interconnect with one another to securely retain adjacent trays together and minimize the risk that any individual tray is dislodged.