A method for producing a composite material includes using an alkaline binder containing alkali silicate glass; an organic gelling agent and SiO.sub.2 particles; and a biological carrier material. The composite material is particularly stable, flame-proof and also suitable for the exterior.

A vaporization core for an electronic vaporization device includes: a porous body; and a heating film arranged on a surface of the porous body. The porous body has at least one unit layer, the at least one unit layer having a liquid storage advantage layer and a liquid locking advantage layer combined with the liquid storage advantage layer. The heating film is combined with a surface of the liquid locking advantage layer and at least partially infiltrates in the liquid locking advantage layer.

A cellular glass insulation system for an outer surface of a structure or pipe. The insulation system includes multiple segments of cellular glass. An adhesive having a reduced permeability is provided at the interface between the individual cellular glass segments and is configured to limit water intrusion that might cause corrosion of the structure or pipe.

A board includes at least a substrate which is formed at least of a gypsum-based and/or cement-based basic material layer with a compressive strength of 30 kg/cm2 and a resin-based covering provided on at least one side of the substrate, in the form of a laminate layer directly pressed onto the substrate.

The present invention is directed to the use of a thermoplastic polymer-wollastonite composite and/or a thermoplastic elastomer-wollastonite composite for reducing noise. The present invention is also directed to an article comprising a thermoplastic polymer-wollastonite composite and/or a thermoplastic elastomer-wollastonite composite, a method of making an article according to the invention, and a device comprising an article according to the invention.

A board consisting at least of a substrate formed at least of a gypsum-based and/or cement-based basic material layer. The board is provided with a chamfer extending through the basic material layer.

A continuous process of forming a magnesium oxide-based product. The process includes preparing a feedstock, transferring the feedstock to a continuous curing process occurring at elevated temperatures and pressures, and drying the product of the continuous curing process. The process can further include lamination processes occurring after drying or in conjunction with curing. The continuous process reduces costs and times associated with traditional processes.

A composition and process for making calcium silicate hydrate board, which comprises preparing a slurry of a mixture of silicic material, lime material, spherical xonotlite particles, synthetic wollastonite and reinforcing fibres with balanced water; forming the slurry into a board by means of the sheet-forming technologies; steam curing the board and drying.

In the present disclosure, a cement board is disclosed. The cement board comprises a core having a first surface and a second surface opposite the first surface and a binder including a pozzolan material and a water-resistant additive, wherein the water-resistant additive is present in an amount of less than 5 wt. % based on the weight of the pozzolan material.

A geopolymeric material is described having compressive strength at 28 days ranging from 15 to 100 N/mm.sup.2, obtainable by curing for 12 hours at a temperature ranging from 20 C. to 60 C., from a geopolymeric aqueous mixture comprising the following inorganic components in the following parts by dry mass: metakaolin 15-65 potassium silicate and/or sodium silicate 20-40 aggregates recycled from CDW (Construction and Demolition Waste) 5-300; said geopolymeric aqueous mixture is obtainable by mixing 20-175 parts by mass of water with said inorganic components, and has a viscosity at 23 C. between 100 and 10000 Pa.Math.s, wherein: i) the viscosity is measured via Brookfield methodology, ii) the aggregates recycled from CDW belong to one or more of the classes 17.01.01, 17.01.02, 17.01.03, 17.01.07 according to the European Waste Catalogue, iii) the aggregates recycled from CDW have a grain size less than or equal to 4 mm, preferably less than or equal to 2 mm.