A ceiling system, comprising at least two elongate carriers, configured to support at least one ceiling panel; at least one elongate beam; and at least two connecting brackets; wherein each elongate carrier is supported at one or more suspension locations; each elongate beam is coupled to at least two elongate carriers by a respective connecting bracket; and the connecting brackets are coupled to the elongate carriers by a push-fit connection.

A ceiling system, comprising at least two elongate carriers, configured to support at least one ceiling panel; at least one elongate beam; and at least two connecting brackets; wherein each elongate carrier is supported at one or more suspension locations; each elongate beam is coupled to at least two elongate carriers by a respective connecting bracket; and the connecting brackets are coupled to the elongate carriers by a push-fit connection.

The present disclosure relates generally to a connection clip for securing a panel to a support grid, for example, suitable for securing a wood grille panel to a ceiling grid. The present disclosure relates more particularly to a connection clip including a body having a base with a width extending between opposing first and second lateral edges and first and second arms extending upward respectively from the first and second lateral edges of the base so as to form a cavity configured to receive a structural cross member of the panel. Engagement lips extend laterally inward from an upper end of each arm and are configured to grip respective first and second flanges of a grid member of the support grid so as to secure the panel to the grid member. Each of the first and second engagement lips span a substantial majority of the depth of the connection clip.

The present disclosure relates generally to cladding that forms an architectural surface, for example, suitable for forming a ceiling. The present disclosure relates more particularly to a cladding system including a plurality of flexible grid members arranged so as to form a grid that extends in at least two dimensions and includes grid cells that are delimited by the flexible grid members and a plurality of panels supported by the grid. At least a first portion of the panels are arranged so as to form an architectural surface.

The present disclosure relates generally to cladding that forms an architectural surface, for example, suitable for forming a ceiling. The present disclosure relates more particularly to a cladding system including a plurality of flexible grid members arranged so as to form a grid that extends in at least two dimensions and includes grid cells that are delimited by the flexible grid members and a plurality of panels supported by the grid. At least a first portion of the panels are arranged so as to form an architectural surface.

Disclosed is a precursor for a clip and a clip formed by the precursor. The clip is configured for mounting a furring channel to a load-bearing member and is a generally U-shaped member having a pair of sidewalls, each of which includes a pair of tabs projecting therefrom. The clip is arranged to receive the load-bearing member between its sidewalls, such that the tabs can be snap-fit under inwardly directed flanges of the furring channel. Also disclosed is a method of forming the clip from the precursor, by bending portions of the precursor to form the sidewalls of the clip, and a method for mounting a furring channel onto a load-bearing member using the clip.

Disclosed is a precursor for a clip and a clip formed by the precursor. The clip is configured for mounting a furring channel to a load-bearing member and is a generally U-shaped member having a pair of sidewalls, each of which includes a pair of tabs projecting therefrom. The clip is arranged to receive the load-bearing member between its sidewalls, such that the tabs can be snap-fit under inwardly directed flanges of the furring channel. Also disclosed is a method of forming the clip from the precursor, by bending portions of the precursor to form the sidewalls of the clip, and a method for mounting a furring channel onto a load-bearing member using the clip.

The present invention relates to a functional ceiling coupling structure and its construction method. For this purpose, the ceiling coupling structure of the present invention includes a ceiling member; a fully threaded bolt, a top end of which is fixed to the ceiling member; and a carrying bar fixture coupled to a bottom end of the fully threaded bolt in order to accommodate a carrying bar. A height adjustable member having screw threads formed around an inner circumference of the height adjustable member is coupled to a lower part of the fully threaded bolt, and the carrying bar fixture is coupled to the height adjustable member, so as to adjust a relative height of the carrying bar fixture. As a result, the height of the carrying bar can be flexibly adjusted to thus achieve efficient construction of the ceiling structure.

Disclosed is a precursor for a clip and a clip formed by the precursor. The clip is configured for mounting a furring channel to a load-bearing member and is a generally U-shaped member having a pair of sidewalls, each of which includes a pair of tabs projecting therefrom. The clip is arranged to receive the load-bearing member between its sidewalls, such that the tabs can be snap-fit under inwardly directed flanges of the furring channel. Also disclosed is a method of forming the clip from the precursor, by bending portions of the precursor to form the sidewalls of the clip, and a method for mounting a furring channel onto a load-bearing member using the clip.

Disclosed is a precursor for a clip and a clip formed by the precursor. The clip is configured for mounting a furring channel to a load-bearing member and is a generally U-shaped member having a pair of sidewalls, each of which includes a pair of tabs projecting therefrom. The clip is arranged to receive the load-bearing member between its sidewalls, such that the tabs can be snap-fit under inwardly directed flanges of the furring channel. Also disclosed is a method of forming the clip from the precursor, by bending portions of the precursor to form the sidewalls of the clip, and a method for mounting a furring channel onto a load-bearing member using the clip.