Disclosed are methods to produce composite materials, which contain customized mixes of nano- and/or micro-particles with tailored electromagnetic spectral properties. In some defense-related applications, the use of such materials enables an improved spectral match between different structures, such as vehicles or buildings with the surrounding environment at least in the VIS and NIR wavelength range. This can camouflage the structures, and reduce the detectability thereof by ground-, air- or space-based multi-spectral long-range imaging systems, including aircrafts, drones, and satellites, and thus, generally delay, complicate, or eliminate detection or classification of the camouflaged structures.

Disclosed are methods to produce composite materials, which contain customized mixes of nano- and/or micro-particles with tailored electromagnetic spectral properties. In some defense-related applications, the use of such materials enables an improved spectral match between different structures, such as vehicles or buildings with the surrounding environment at least in the VIS and NIR wavelength range. This can camouflage the structures, and reduce the detectability thereof by ground-, air- or space-based multi-spectral long-range imaging systems, including aircrafts, drones, and satellites, and thus, generally delay, complicate, or eliminate detection or classification of the camouflaged structures.

Disclosed are methods to produce composite materials, which contain customized mixes of nano- and/or micro-particles with tailored electromagnetic spectral properties. In some defense-related applications, the use of such materials enables an improved spectral match between different structures, such as vehicles or buildings with the surrounding environment at least in the VIS and NIR wavelength range. This can camouflage the structures, and reduce the detectability thereof by ground-, air- or space-based multi-spectral long-range imaging systems, including aircrafts, drones, and satellites, and thus, generally delay, complicate, or eliminate detection or classification of the camouflaged structures.

The present invention relates to a process for manufacturing a wood-based board, a wood-based board as use of a liquid coating composition comprising at least one particulate filler material and at least one binder for in-line coating of wood-based boards.

The present invention relates to a process for manufacturing a wood-based board, a wood-based board as use of a liquid coating composition comprising at least one particulate filler material and at least one binder for in-line coating of wood-based boards.

The present invention relates to a process for manufacturing a wood-based board, a wood-based board as use of a liquid coating composition comprising at least one particulate filler material and at least one binder for in-line coating of wood-based boards.

The present invention provides a process for producing a friction material for a construction waste filler, including steps of: (S1) sorting a building material, removing fiber impurities, calcining, removing white garbage and metal impurities, and obtaining a first intermediate product; (S2) sifting and removing dust from the first intermediate product, obtaining an intermediate filler, cooling and then soaking after performing calcination on the intermediate filler, dehydrating, drying and obtaining a material to be mixed; (S3) evenly mixing the material to be mixed, graphite, molybdenum disulfide and other media materials, performing enhancement treatment, grinding and obtaining a building filler; and (S4) mixing composite fiber, phenolic resin, the building filler, friction material, pyrite, carbon black, alumina, and brass powder, stirring in a mixer for 20-40 min till all materials are fused, taking out a fused mixture, barreling, and obtaining the friction material for the construction waste filler.

The present invention is a granular material that can be well recoated regardless of the type of the granular material, and enables a refractory aggregate in an unprinted portion to be used without any regeneration process, in the manufacture of a three-dimensional laminated and shaped mold. This granular material is a granular material for use in three-dimensional laminated mold shaping, and obtained by adding a material that causes a hydration reaction having a moisture absorbing function and generates a catalytic effect to a coating material mixed with or coated with an acid as a catalyst which activates and hardens an organic binder for binding the granular material.

The present invention is a granular material that can be well recoated regardless of the type of the granular material, and enables a refractory aggregate in an unprinted portion to be used without any regeneration process, in the manufacture of a three-dimensional laminated and shaped mold. This granular material is a granular material for use in three-dimensional laminated mold shaping, and obtained by adding a material that causes a hydration reaction having a moisture absorbing function and generates a catalytic effect to a coating material mixed with or coated with an acid as a catalyst which activates and hardens an organic binder for binding the granular material.

The present invention is a granular material that can be well recoated regardless of the type of the granular material, and enables a refractory aggregate in an unprinted portion to be used without any regeneration process, in the manufacture of a three-dimensional laminated and shaped mold. This granular material is a granular material for use in three-dimensional laminated mold shaping, and obtained by adding a material that causes a hydration reaction having a moisture absorbing function and generates a catalytic effect to a coating material mixed with or coated with an acid as a catalyst which activates and hardens an organic binder for binding the granular material.