A floor structure system may have a hub. A beam connector may be connected to the hub. At least one pin may be located on the hub. The pin may be adapted to connect with a rod extending generally transverse the pin direction. The rod may have an aperture adapted to receive the at least one pin. The system may also have a beam attached to the beam connector.

A convertible floor panel assembly incorporates a metal wire mesh subfloor and a polymer deck overlying the wire mesh subfloor. A plurality of alignment heads project from an underside of the polymer deck, and are designed to extend through respective mesh openings defined by the wire mesh subfloor. A plurality of panel retainers engage respective alignment heads, and are adapted for removably attaching the wire mesh subfloor and the polymer deck together. The floor panel assembly is thereby convertible between a substantially open-surface sound permeable safety structure and a continuous solid-surface structure for increased floor load capacity.

A convertible floor panel assembly incorporates a metal wire mesh subfloor and a polymer deck overlying the wire mesh subfloor. A plurality of alignment heads project from an underside of the polymer deck, and are designed to extend through respective mesh openings defined by the wire mesh subfloor. A plurality of panel retainers engage respective alignment heads, and are adapted for removably attaching the wire mesh subfloor and the polymer deck together. The floor panel assembly is thereby convertible between a substantially open-surface sound permeable safety structure and a continuous solid-surface structure for increased floor load capacity.

A deployable mobile stage system including a remote mobile computing device which acts as a controller. The mobile computing device can be any basic personal computing device such as a smart phone, tablet computer, laptop, or proprietary control unit. The mobile computing device interfaces wirelessly with a receiver unit located on the mobile stage. The receiver unit relays commands to a hydraulic system which then commands various valves to open and/or close, thereby transforming the mobile stage from a first, deployed position to a second, transport position or back.

A deployable mobile stage system including a remote mobile computing device which acts as a controller. The mobile computing device can be any basic personal computing device such as a smart phone, tablet computer, laptop, or proprietary control unit. The mobile computing device interfaces wirelessly with a receiver unit located on the mobile stage. The receiver unit relays commands to a hydraulic system which then commands various valves to open and/or close, thereby transforming the mobile stage from a first, deployed position to a second, transport position or back.

A rostrum support structure comprising a plurality of frame units (10, 20, 30, 40, 50) which can be stacked with respect to one another, at least one support member being provided for directly supporting at least two of the frame units when stacked so that they can be lifted together. The at least one support member is preferably in the form of a flat plate.

A rostrum support structure comprising a plurality of frame units (10, 20, 30, 40, 50) which can be stacked with respect to one another, at least one support member being provided for directly supporting at least two of the frame units when stacked so that they can be lifted together. The at least one support member is preferably in the form of a flat plate.

An elevated flooring system includes floor modules each having first and second module surfaces and module ribs. First module surfaces may be solid or include holes for drainage. Module ribs provide structural support and define at least one module receiving space accessible from the second module surface. Block(s) include extensions protruding from a first block surface and are dimensioned to fit within a corresponding module receiving space. Each block includes block ribs providing support and defining at least one block receiving space accessible from a second block surface. Interfacing member(s) include a body correspondingly dimensioned to fit within a block receiving space and leg(s) extending from the body and dimensioned to fit within a hole on a first module surface. Floor modules may be joined adjacently and interfacing members, blocks and floor modules are stackable to provide a modular and customizable flooring system of different and varying heights.

An elevated flooring system includes floor modules each having first and second module surfaces and module ribs. First module surfaces may be solid or include holes for drainage. Module ribs provide structural support and define at least one module receiving space accessible from the second module surface. Block(s) include extensions protruding from a first block surface and are dimensioned to fit within a corresponding module receiving space. Each block includes block ribs providing support and defining at least one block receiving space accessible from a second block surface. Interfacing member(s) include a body correspondingly dimensioned to fit within a block receiving space and leg(s) extending from the body and dimensioned to fit within a hole on a first module surface. Floor modules may be joined adjacently and interfacing members, blocks and floor modules are stackable to provide a modular and customizable flooring system of different and varying heights.

A deployable mobile stage system with an automatic leveling system. A remote controlling device interfaces with an internal controller of the mobile stage for transforming the stage from a transport position to a deployed position. Multiple level sensors provide feedback to the controller of the stage to automatically level the stage using jacks and outriggers hydraulically or mechanically controlled by the controller. The level sensors could be 3-axis sensors which provide level data to the CPU of the internal controller, which then forms determinations as to which jacks to raise or lower, when, and at what rate.