The invention relates to corrosion-protected ductile cast iron pipes, a method for producing corrosion-protected ductile cast iron pipes, and the use of specific compositions for producing corrosion-protected ductile cast iron pipes. More particularly, the invention relates to corrosion protection for ductile cast iron pipes using latex-modified cement mortars based on calcium-aluminum cements.

A wear resistant substrate including a metal substrate having a surface, a reinforcing support attached to the surface and cured reaction products of an inorganic curable composition disposed over and through the reinforcing support and bonded to the surface. Also a method of enhancing the wear resistance of a metal surface by attaching a reinforcing support to the surface; disposing an inorganic curable composition over and through the reinforcing support and into contact with the surface; and curing the composition.

A method for preparing aerogel particles and a coated component are provided. The coated component includes a substrate and a coating. The coating includes aerogel particles sprayed from a hot gas jet or plasma jet. The method includes the step of feeding one or a plurality of gel particles into a hot gas jet or plasma j et. The one or a plurality of gel particles are sufficiently small to permit supercritical drying during the time the particles are in the jet. The method further includes the step of exposing the one or a plurality of gel particles to the temperatures and pressures of the hot gas jet or plasma jet to create the aerogel particles outside of a jet emitter and/or without a sealed pressure vessel.

The invention relates to a gypsum-cement dry mix, the use thereof and a method for producing prefabricated construction parts using the gypsum-cement dry mix. For this purpose, the gypsum-cement dry mix comprises: a binder containing calcium sulphate hemihydrate or a mixture having at least 50 wt. % thereof and hydraulic cement in a weight ratio of 5:1 to 3:1; an aggregate material selected from crushed wood, plastic, expanded clay, perlites or a foam material or a mixture thereof; additives containing at least one plasticiser, at least one air-entraining agent, at least one stabiliser, and at least one delayer/accelerator, wherein the additives are present in dry form, and the mass fraction of the sum of all the additives in the total mass of the dry mix is <1%, wherein the stabiliser is selected from fluorophosphates or condensed phosphates, wherein the delayer is a water-soluble anionic polymer, and wherein the stabiliser-delayer mass ratio is 3:1 to 1:3.

A mineral wool insulating product which comprises a layer, notably a continuous layer, of mixed mineral wool fibres, the mixed mineral wool fibres comprising a binder, first mineral wool fibres and second mineral wool fibres, the first mineral wool fibres and the second mineral wool fibres have a difference of softening point.

A corrosion-resistant cover system, having a corrosion-resistant cover structured and configured to be arrangeable around an object having one or more metallic surfaces that are susceptible to corrosion. The corrosion-resistant cover is operable to provide increased corrosion resistance to the object by preventing contact between the one or more metallic surfaces and ambient conditions exterior to the corrosion-resistant cover.

Use of a geopolymer in a coating composition for a building construction component, a coated component for use in building construction wherein the coating comprises a geopolymer, a method of coating a component comprising applying a curable geopolymer mixture to a surface of the component and curing the mixture to form a cured geopolymer coating, and the use of a geopolymer as a mortar.

Techniques and methods are disclosed for facilitating the fireproofing application process to the structural members of buildings (e.g., houses, apartment buildings, office buildings, sky-rises, etc.) and for improving the structural integrity of steel when exposed to extreme temperatures. The components of the Universal Fireproofing Patch provide a fireproofing protection product that exceeds Underwriters Laboratories fireproofing guidelines, which may be used under any circumstances (i.e., in the event the existing material to be fire-patched is either unknown or unavailable). The components of the Universal Fireproofing Patch enable a user the ability to coat a non-conforming area quickly, easily and for a fraction of the price compared to commercial patching services. Finally, the Universal Fireproofing Patch is sold as a kit that is comprised of a container, a premeasured quantity of water and fireproofing mix, a mixer, a trowel and an instrument capable of measuring liquids. The container provided in the kit stores the fireproofing mix, serves as a housing for when a user mixes the components together and is readily mobile for transporting purposes.

An additive for a bituminous binder respectively a bituminous composite material, able to reduce bituminous binder respectively bituminous composite material viscosity when an alternating magnetic field is applied, in particular for healing pavement cracks and in-depth micro-cracks in asphalt, wherein the additive comprises an amount of magnetic iron oxide particles should be improved, in order to reach bituminous composite material respectively a bituminous binder which can be melted in a faster and simplified way, in particular usable for crack healing of asphalt structures on site. This is reached by forming the additive comprising at least a part of magnetic iron oxide nanoparticles with average sizes between 1 nm and 300 nm coated with a fatty acid.

The method disclosed includes: a step (I) of preparing a dispersion liquid (S) including an aluminum compound (A); a step (II) of mixing the dispersion liquid (S) and a predetermined phosphorus compound (B) so as to prepare a coating liquid (U); a step (III) of applying the coating liquid (U) onto the base (X) so as to form a precursor layer of the layer (Y); and a step (IV) of subjecting the precursor layer to heat treatment at a temperature of 110 C. or more so as to form the layer (Y). The aluminum compound (A) can be formed by adding an acid to a solution including an aluminate. The number of moles (N.sub.M) of aluminum atoms derived from the aluminum compound (A) and the number of moles (N.sub.P) of phosphorus atoms derived from the phosphorus compound (B) satisfy 0.8(N.sub.M)/(N.sub.P)4.5.