A low cost, lightweight, high strength, long lasting, crack resistant, monolithically formed composite structural material and the method of making the same in which the composite consists of a core constructed from lightweight, granulated scrap or waste plastic bonded together with a cementitious slurry binder. The core is covered on one or more of its sides with a high strength outer layer constructed of layers of non-woven fabric material impregnated with the same cementitous slurry binder with the fibers in the layers of non-woven fabric material forming a three-dimensional reinforcement matrix for the cementitous slurry. The composite of the core and covering is co-formed and cured monolithically with the cementitious slurry being continuous throughout the fibers of the layers of non-woven fabric and the core with the lightweight scrap or waste plastic serving as an aggregate for the core. The composite structural material can be molded or formed in various shapes and configurations for various purposes.

Decorative interior molding is molded from a slurry of gypsum, water, perlite, and a foaming agent. The slurry is surrounded by paper, cured, and dried.

A low cost, lightweight, high strength, long lasting, crack resistant, monolithically formed composite structural material and the method of making the same in which the composite consists of a core constructed from lightweight, granulated scrap or waste plastic bonded together with a relatively inexpensive cementitious slurry binder. The core is covered on one or more of its surfaces with a high strength outer layer constructed of layers of non-woven fabric material impregnated with a cementitious slurry binder having a different formulation than the core cementitious slurry binder to effectively bond with the fibers in the layers of non-woven fabric material to form a three-dimensional reinforcement matrix for the outer layer cementitious slurry binder. The composite of the core and covering is co-formed and cured monolithically with the outer layer cementitious slurry binder being continuous throughout the fibers of the layers of non-woven fabric and the core cementitious slurry being continuous throughout the waste plastic core material with the lightweight scrap or waste plastic serving as an aggregate for the core.

A lightweight insulating concrete composition includes a cementitious forming material and a lightweight aggregate combination of expanded vermiculite and expanded perlite, the weight ratio of one to the other not exceeding about 2:1. Preferably, the composition is about 4 parts by weight cementitious forming material and about 1 part by weight lightweight aggregate. The cementitious forming material may be a hydraulic binder and accelerator combination, and may be Portland cement, plaster of Paris, and terra alba, in a weight ratio of about 5:4:1, or calcium aluminate cement, and plaster of Paris, in a weight ratio of about 11:5. The composition may further include an air entraining admixture in an amount between about 0.5 and about 2.0 percent of the total weight of the mixture, where neutralized vinsol resin and alpha olefin sulfonate are acceptable, and a surfactant in an amount between about 0.3 and about 1.5 percent of the total weight of the mixture, where sulfonated melamine and napthalene formaldehyde are acceptable. A method of making the lightweight insulating concrete composition includes blending the cementitious forming material and the combination of lightweight aggregate of expanded vermiculite and expanded perlite, and any admixture or surfactant that may be included. A method of repairing or patching concrete surfaces using the lightweight insulating concrete, includes hydrating the composition, applying the concrete slurry and permitting it to cure for about 2 to about 4 hours until it sets.

Glass fibre reinforced plasterboard including a gypsum matrix of high density with embedded staple glass fibres therewith forming a pressure resistant solid body frame in which are embedded a plurality of very small hollow spaces of 5-350 microns in diameter, produced by a fine-pore foam or at least partially by small particles of non-porous and non-water absorbing fillers. During the manufacturing process of such glass fibre reinforced gypsum board, the gypsum and the fibre pieces are given only so much water that the water/gypsum ratio does not exceed 0.6, whereafter a foam and/or pourable or free-flowing fillers are added in such quantities that the apparent density of the entire board is at least 20% smaller than the density of the bonding means component of the matrix, and the paste is subjected while being formed to a vibration.