A securing member includes a fixing portion having a reference surface and fixing holes, a main bulging portion having a contact surface that comes into contact with first to fourth exterior members, a supporting portion, upper and lower engagement portions attached to the supporting portion, a lower bulging portion, and an erected portion that projects from the lower bulging portion and that is disposed on a center line of the fixing portion between the first and third exterior members. One of the fixing holes that is closest to the center line is displaced from the center line. The fixing holes are arranged asymmetrically about the center line. A first length by which the main bulging portion bulges is greater than a second length by which the lower bulging portion bulges. The length from the reference surface to the front end of the erected portion is greater than the first length.

A leveling shim (1) for building is described, comprising a plastic plate (2), coupling means and through holes. The coupling means comprise flexible coupling means (5) able to be housed in at least one cavity (6) of the plate (2), and at least one coupling through hole (4).

A facade panel screw for the optimized fastening of facade panel elements on a substructure has a head with very large diameter D.sub.K, a substantially cylinder cross-sectional shaft, which is at least partially provided with a thread (nominal diameter D.sub.S) and a conical tip comprising a tip angle γ. The thread extends continuously from the shaft to the tip. It is characterizing that the tip angle γ is 45°+/−10°, the thread is embodied at least in a two-threaded manner, the head diameter D.sub.K is embodied at least twice as large as the nominal diameter D.sub.S; and the facade panel screw does not have a drill tip. Such a facade panel screw is used in a fastening arrangement, which comprises a load-bearing component (substructure) and a facade panel. Due to its design, the facade panel screw is able to simplify the fastening of the facade panel and to at least partially correct an inclined positioning in response to the installation.

Composite panels and methods of use and manufacturing are described herein. The composite panels may comprise a foam composite and one or more layers of a facing material. The foam composite may have a density less than or equal to 20 pcf, and the layer(s) of facing material, e.g., inorganic facing material, may have a thickness of 1/16 inch to 1 inch covering at least the front surface of the foam composite.

A wall panel may have a rigid layer, a first insulation layer made from a two-part rigid urethane pour foam, and a second insulation layer made from a phase change material. The first insulation layer may be chemically bonded to the rigid layer and may also be bonded to the phase change layer. The first insulation layer may be positioned between the second insulation layer and the rigid layer. The rigid layer may be a finished surface or a veneer layer may be applied to the rigid layer.

A wall panel may have a rigid layer, a first insulation layer made from a two-part rigid urethane pour foam, and a second insulation layer made from a phase change material. The first insulation layer may be chemically bonded to the rigid layer and may also be bonded to the phase change layer. The first insulation layer may be positioned between the second insulation layer and the rigid layer. The rigid layer may be a finished surface or a veneer layer may be applied to the rigid layer.

A system for retaining a position of an architectural fin relative to a structure. The fin is generally planar and defines an edge. The system includes a first mounting bracket configured to retain the architectural fin. The first mounting bracket comprises a first element having laterally opposed surfaces configured to receive the architectural fin therebetween and to apply a compression force to the laterally opposed surfaces of the architectural fin. A second element connected to the first element so that the first element is rotatable relative to the second element about an axis of rotation of the first mounting bracket. The second element has a base for fixing the first mounting bracket relative to the structure. The first mounting bracket is configured to enable rotation of the architectural fin relative to the structure about the axis of rotation of the first mounting bracket.

A wall or ceiling panel, which, on one side edge, comprises a male coupling part and, on an opposite side edge, comprises a female coupling part. The male coupling part comprises a tongue and the female coupling part comprises a groove. The groove is bordered by a front lip and a rear lip, with the characteristic that the panel forms a ceiling-high wall panel and/or has a length of at least 2400 mm.

The invention is related to a method of manufacturing a wall panel and a wall panel system. The method includes: forming a glass-fiber reinforced rigid magnesium oxide layer including the steps of: pouring or injecting a slurry of uncured magnesium oxide into a mold, embedding glass fiber reinforcing material therein, and curing the magnesium oxide to obtain the glass-fiber reinforced rigid magnesium oxide layer having a first side and a second side; applying, to the second side of the rigid magnesium oxide layer, an insulation layer, the insulation layer comprising a foam; and applying to the first side of the rigid layer a veneer layer.

The invention is related to a method of manufacturing a wall panel and a wall panel system. The method includes forming a glass-fiber reinforced cementitious layer including the steps of: pouring or injecting a slurry of uncured cementitious product into a mold, embedding glass fiber reinforcing material therein, and curing the cementitious product to obtain a cured cementitious product having a first side and a second side; and applying, to the second side of the cured cementitious product, an insulation layer, the insulation layer comprising a foam.