The present invention provides a method for constructing an access floor by using unmanned robot, the method comprising: a first step (S100) of constructing an installation frame (10) and a peripheral slab (60) formed on the periphery of the installation frame; a second step (S200) of positioning the unmanned robot on the peripheral slab (60); and a third step (S300) of coupling a floor (30) to the installation frame (10) by the unmanned robot while moving along the peripheral slab (60). According to the present invention, an automated robot can install a mat and floor in place of a worker performing dangerous floor installation work, so as to prevent the occurrence of workplace safety accidents. Furthermore, through the installation of a mat and floor by the robot, floor installation location selection and leveling work can be quickly performed, so as to reduce the construction costs and shorten the construction period.

The invention relates to a paver supporting apparatus. The paver supporting apparatus has a pedestal with a top plate. A modular grid is positioned on the top plate and has a ballast receiving opening and a ballast is located in the ballast receiving opening.

A modular platform system includes a plurality of tiles, legs, beams, and brackets. Peripheries of the tiles and top surfaces of the beams are configured so that the tiles can snap on to the beams, allowing for easy creation of a platform. The beams, legs, and brackets are all configured so that the beams and legs are easily connected together for platform system creation.

A modular raised floor module and raised floor systems constructed therefrom are disclosed. The raised floor module comprising a base floor and a top floor, with a plurality of support pedestals disposed between the base floor and a top floor, wherein the plurality of support pedestals are configured for supporting and leveling the base floor above a bearing surface and for supporting the top floor at a spaced apart relation over the base floor, thereby forming a service space extending between a top face of the base floor and a bottom face of the top floor. The raised floor modules are articulable to one another along their neighboring edges. The base floor can be configured with an inclined surface for draining liquids within the service space towards a liquid collecting portion, for removing liquids from the service space.

A paver supporting apparatus is provided and includes a pedestal and a modular grid. The pedestal includes a top plate with a plate extender and a plurality of male lock pins positioned around a circumference of the top plate. The modular grid is positioned and secured on the top plate such that the top plate supports the modular grid in an elevated position and connects with one of the plurality of male lock pins. The modular grid includes a lattice extending generally between perimeter edges of the modular grid and defining a plurality of lattice.

Disclosed is a section bar and a support system for raised floors including the section bar. In particular, the section bar is particularly shaped and the presence of this section bar makes the support system fast and simple to assemble.

A pedestal/stand for raised floors can be applied on a number of heads of supports for raised floors. The pedestal/stand may include at least one beam. The beam is of a contoured type and includes at least one zone for interlocking mechanical association with the number of heads of the supports.

Exemplary implementations of a braced flooring tray support system comprise a braced pedestal subsystem and one or more trays. The braced pedestal subsystem may include several pedestals rigidly interconnected by several brace elements. The pedestals may include position-adjustable brace interface elements having vertical fins or an annular flange projecting radially. The tray corners are supported by respective pedestals. The brace elements may have an opposing pair of pedestal interface portions which include a fin-receiving or flange-receiving slot, and a pair of pin alignment apertures intersecting the slot. Brace fasteners configured to be manually installed in and removed from the pedestal interface portions. Each brace fastener may include a pair of fastener pins configured to extend through respective pin alignment apertures and respective attachment apertures when the brace fastener is installed. The fastener pins may include a detent portion configured to releasably secure the installation without requiring any threaded engagement.

A floor frame includes at least two spaced longitudinal support strips and at least one lateral support strip. Each longitudinal support strip has longitudinal upper and lower portions and a pair of longitudinal side walls. A shoulder is designed on at least one of the pair longitudinal side walls and located between the longitudinal upper and lower portions. Two shoulders of the two longitudinal support strips are opposite to each other. The lateral support strip includes lateral upper and lower portions and a pair of lateral side walls. Two ends of the lateral support strip are placed on the two shoulders of the longitudinal support strips, respectively. A plurality of longitudinal and lateral support strips constitutes a grid-type structure under the distribution of longitudinal and lateral directions to provide the placement and fixation of a plurality of floor panels.

A modular platform system includes a plurality of tiles, legs, beams, and brackets. Peripheries of the tiles and top surfaces of the beams are configured so that the tiles can snap on to the beams, allowing for easy creation of a platform. The beams, legs, and brackets are all configured so that the beams and legs are easily connected together for platform system creation.