A tile system for use on a grid of a suspended ceiling comprises a plurality of tiles, each said tile having a main body having an exposed side and a concealed side, the exposed side defining a main surface, the concealed side defining a rear plane, and four side surfaces between the exposed side and the concealed side of the main body, wherein two of the four side surfaces have at least one tongue in the rear plane, and two other of the four side surfaces have at least one groove open to the rear plane. Fasteners, such as clips, are configured for attaching the tongues of one of the tiles to upside-down T channels of the grid, such that the rear plane of the tile is against a downwardly facing surface of the T channels of the grid. The tiles are arranged such that, for a pair of the tiles side by side and sharing a same channel, one of the tiles has its at least one tongue connected to the channel by said fasteners, and the other of the tiles has its at least one groove receiving the at least one tongue of the adjacent tile. A method of installation is also provided.

A masonry veneer support assembly for mounting masonry veneer to supporting wall structure has a shelf angle, and first and second shelf angle mounting brackets. Each shelf angle mounting bracket has an upwardly extending back that mounts to the supporting wall structure, and a web extending forwardly away from the wall structure. The web has first and second shelf angle mounting seats formed therein. The first shelf angle mounting seat is upwardly spaced from the second shelf angle mounting seat. Hangers in the form of two-part separable brackets are provided to permit masonry veneer to be mounted underneath the shelf angle, thereby concealing it from view.

A wall system comprising a frame and one or more panels removably attached to the frame, wherein the one or more panels are positioned over one or more cutouts of the frame to form a substantially coplanar surface.

A wall system comprising a frame and one or more panels removably attached to the frame, wherein the one or more panels are positioned over one or more cutouts of the frame to form a substantially coplanar surface.

An architectural finish element operable to be placed adjacent similar architectural finish elements to form a finished surface on an architectural structure includes a body formed of a rock-based composite material comprising a low density solid particle additive, a plurality of unitary real stone veneer elements bonded to the body in courses extending in a first direction and in a random non-repetitive pattern, the real stone veneer elements having respective face surfaces generally lying in a plane to form an overall face surface of the architectural finish element. The low density solid particle additive is provided in an amount suitable to cause the architectural finish element to have a density of between about 10 to 15 pounds per square foot. The architectural finishing element may be mounted by mounting a portion of a body of at least one dual architectural finish element support to a surface of an architectural structure.

An architectural finish element operable to be placed adjacent similar architectural finish elements to form a finished surface on an architectural structure includes a body formed of a rock-based composite material comprising a low density solid particle additive, a plurality of unitary real stone veneer elements bonded to the body in courses extending in a first direction and in a random non-repetitive pattern, the real stone veneer elements having respective face surfaces generally lying in a plane to form an overall face surface of the architectural finish element. The low density solid particle additive is provided in an amount suitable to cause the architectural finish element to have a density of between about 10 to 15 pounds per square foot. The architectural finishing element may be mounted by mounting a portion of a body of at least one dual architectural finish element support to a surface of an architectural structure.

A fiber enforced sheet for use as a wall or floor covering which comprises of adhered thin bricks bonded to a fiber-reinforced, backing layer. Thin brick is adhered to the fiber enforced sheet. The fiber enforced backing increases strength and rigidity to the thin brick during handling, and installation permits the thin bricks to be adhered to proper specification and spacing to be cut using ordinary tile or thin brick tools.

A fiber enforced sheet for use as a wall or floor covering which comprises of adhered thin bricks bonded to a fiber-reinforced, backing layer. Thin brick is adhered to the fiber enforced sheet. The fiber enforced backing increases strength and rigidity to the thin brick during handling, and installation permits the thin bricks to be adhered to proper specification and spacing to be cut using ordinary tile or thin brick tools.

A wallboard panel support may include a base support member having two upwardly extending sidewalls which receive the lower end of the wallboard panel and space the lower end of the wallboard panel above a floor of a building. A method for installing a wallboard panel in a building may include attaching a wallboard panel support to the lower end of a wallboard panel, moving the wallboard panel attached to the wallboard panel support to a location in a building adjacent a stud, placing the wallboard panel against the stud, and securing the wallboard panel to the stud.

A wallboard panel support may include a base support member having two upwardly extending sidewalls which receive the lower end of the wallboard panel and space the lower end of the wallboard panel above a floor of a building. A method for installing a wallboard panel in a building may include attaching a wallboard panel support to the lower end of a wallboard panel, moving the wallboard panel attached to the wallboard panel support to a location in a building adjacent a stud, placing the wallboard panel against the stud, and securing the wallboard panel to the stud.