A fabric panel attaching system and methods of assembly and use are presented for attaching fabric panels to structural elements, such as building frames. In various embodiments, the fabric panel attachment system includes a keder rail fastened to support bar, which is attached to a structural profile, such as a building frame member. In some embodiments, the keder rail is fastened to a support bar with bolt and nut. One or more fabric panels are installed within channels of the keder rail. An alignment element may be used with a fastener to assist in aligning abutting sections of keder rail. In various embodiments, the fabric panel attachment system is secured to flat or curvilinear faces of the structural elements. In some embodiments, the fabric panel attachment system may secure directly to the structural element and not a support bar.

Building panels provided with a mechanical locking system including a tongue, at an edge of a first panel, cooperating with a tongue groove, at an edge of an adjacent second panel, for vertical locking of the building panels. The edge of the first panel is provided with a displacement groove, which is downwardly open, and includes an inner wall, an outer wall, and an upper wall. The tongue is formed out of the edge of the first panel. A resilient and displaceable and part of the tongue is displaceable into the displacement groove.

Building panels provided with a mechanical locking system including a tongue, at an edge of a first panel, cooperating with a tongue groove, at an edge of an adjacent second panel, for vertical locking of the building panels. The edge of the first panel is provided with a displacement groove, which is downwardly open, and includes an inner wall, an outer wall, and an upper wall. The tongue is formed out of the edge of the first panel. A resilient and displaceable and part of the tongue is displaceable into the displacement groove.

An integrated solar building product panel that may be integrated into an existing structure's building materials providing an esthetically pleasing appearance and structural integrity. The shock absorbing and vibration damping construction panel comprises at least one solar cell assembly supported by a bottom support component with a vibration damping component surrounding each solar cell assembly. A top transparent protective component is mounted on the vibration damping layer with a gap between the solar cell assembly for protecting each solar cell assembly, and transferring any impact forces to the vibration damping layer isolated from the solar cells. Accordingly, in response to a force applied to the top protective component, the top protective component is deformable up to the width of the gap, and the vibration damping component transfers the force to the compressible bottom support component.

A textured cladding element can be manufactured to approximate the aesthetic and functional properties or natural wood siding and/or shingles. The cladding element can comprise non-wood material, such as fiber cement. The cladding element can include a step and a recessed portion or cove which enables the element to have a relatively low thickness while also achieving a desirable drip edge and/or shadow line when multiple cladding elements are overlapping when installed in a finished product.

A textured cladding element can be manufactured to approximate the aesthetic and functional properties or natural wood siding and/or shingles. The cladding element can comprise non-wood material, such as fiber cement. The cladding element can include a step and a recessed portion or cove which enables the element to have a relatively low thickness while also achieving a desirable drip edge and/or shadow line when multiple cladding elements are overlapping when installed in a finished product.

A simulated brick includes a polymeric core member (20), a mesh layer (30) adhered to the core member, a basecoat layer (43) covering an entirety of the mesh layer, and a finish layer (46) covering an entirety of the basecoat layer. The core member, the mesh layer, the basecoat layer, and the finish layer together define a brick profile portion (11) having first and second lateral sides extending to a planar outer surface to define a first thickness, and an offset portion (12) extending from the first lateral side of the brick profile portion to a lateral end surface and having an outer surface defining a second thickness smaller than the first thickness, the brick profile portion and the offset portion together defining a planar rectangular base surface (16) extending from the second lateral side of the brick profile portion to the lateral end surface of the offset portion.

A simulated brick includes a polymeric core member (20), a mesh layer (30) adhered to the core member, a basecoat layer (43) covering an entirety of the mesh layer, and a finish layer (46) covering an entirety of the basecoat layer. The core member, the mesh layer, the basecoat layer, and the finish layer together define a brick profile portion (11) having first and second lateral sides extending to a planar outer surface to define a first thickness, and an offset portion (12) extending from the first lateral side of the brick profile portion to a lateral end surface and having an outer surface defining a second thickness smaller than the first thickness, the brick profile portion and the offset portion together defining a planar rectangular base surface (16) extending from the second lateral side of the brick profile portion to the lateral end surface of the offset portion.

A mineral-based floor panel including a mineral-based core, wherein the panel includes at least one groove. The at least one groove may be provided in a rear side of the panel. There is also disclosed other such mineral-based panels, such as a building panel, a wall panel, a ceiling panel or a furniture panel. There is also disclosed a method for forming such grooves in a mineral-based panel. Furthermore, there is disclosed a mineral-based panel including a mineral-based core and polymer-based lower layer(s) attached to the core. A locking system of the panel includes a strip extending horizontally beyond an upper portion of the panel, wherein at least a horizontal portion of the strip is entirely formed in the polymer-based lower layer(s).

A mineral-based floor panel including a mineral-based core, wherein the panel includes at least one groove. The at least one groove may be provided in a rear side of the panel. There is also disclosed other such mineral-based panels, such as a building panel, a wall panel, a ceiling panel or a furniture panel. There is also disclosed a method for forming such grooves in a mineral-based panel. Furthermore, there is disclosed a mineral-based panel including a mineral-based core and polymer-based lower layer(s) attached to the core. A locking system of the panel includes a strip extending horizontally beyond an upper portion of the panel, wherein at least a horizontal portion of the strip is entirely formed in the polymer-based lower layer(s).