A cement-based tile formed from a mixture comprising: a cement in the range of about 0.1 to 88% by wet weight percent; a secondary material in the range of about 0.1 to 50% by wet weight percent, the secondary material comprising limestone, sand, silica sand, gypsum, silica fume, fumed silica, Plaster of Paris, calcium carbonate, fly ash, slag, rock, or a combination thereof; a reinforcement fiber in the range of about 0.5 to 20% by wet weight percent, the reinforcement fiber comprising cellulose fiber, glass fiber, plastic fiber, polypropylene fiber, polyvinyl alcohol (PVA) fiber, homopolymer acrylic fiber, alkali-resistant fiber, or a combination thereof; a rheology modifying agent in the range of about 0.5 to 10% by wet weight percent; a water in the range of 10 to 60% of a total wet material weight; and wherein the mixture is extruded or molded to form the cement-based tile.

A cement-based tile formed from a mixture comprising: a cement in the range of about 0.1 to 88% by wet weight percent; a secondary material in the range of about 0.1 to 50% by wet weight percent, the secondary material comprising limestone, sand, silica sand, gypsum, silica fume, fumed silica, Plaster of Paris, calcium carbonate, fly ash, slag, rock, or a combination thereof; a reinforcement fiber in the range of about 0.5 to 20% by wet weight percent, the reinforcement fiber comprising cellulose fiber, glass fiber, plastic fiber, polypropylene fiber, polyvinyl alcohol (PVA) fiber, homopolymer acrylic fiber, alkali-resistant fiber, or a combination thereof; a rheology modifying agent in the range of about 0.5 to 10% by wet weight percent; a water in the range of 10 to 60% of a total wet material weight; and wherein the mixture is extruded or molded to form the cement-based tile.

Disclosed is a method for manufacturing a silicon carbide ceramic special-shaped part with a complex shape by plastic fused deposition modeling (FDM)-3D printing based on water debinding. The method includes: mixing graphite, carbon black, silicon carbide, and a surface modifier, and subjecting a resulting mixture to modification to obtain a surface modifier-coated composite ceramic powder; subjecting the surface modifier-coated composite ceramic powder with a macromolecular binder to internal mixing with an internal mixer to obtain a ceramic 3D printing feed; and subjecting the ceramic 3D printing feed to 3D printing, debinding, and reaction sintering in sequence to obtain the silicon carbide ceramic special-shaped part with the complex shape.

Disclosed is a method for manufacturing a silicon carbide ceramic special-shaped part with a complex shape by plastic fused deposition modeling (FDM)-3D printing based on water debinding. The method includes: mixing graphite, carbon black, silicon carbide, and a surface modifier, and subjecting a resulting mixture to modification to obtain a surface modifier-coated composite ceramic powder; subjecting the surface modifier-coated composite ceramic powder with a macromolecular binder to internal mixing with an internal mixer to obtain a ceramic 3D printing feed; and subjecting the ceramic 3D printing feed to 3D printing, debinding, and reaction sintering in sequence to obtain the silicon carbide ceramic special-shaped part with the complex shape.

The invention relates to a system for extrusion of filaments of construction material enriched with aggregates and/or steel fibers, referred to as loaded material, for a robot for additive manufacture of architectural structures comprising: a head (100) for printing filaments of construction material comprising an inlet opening (110) for material and an outlet nozzle (120) for material; a circuit (10) for supplying material to said print head (100) comprising a reservoir (20) for storing loaded material and a conduit (31) for supplying material, connecting said storage reservoir (20) and said print head (100); characterized in that said supply circuit (10) comprises at least one piston pump (40) mounted on said supply conduit (31) and in that said print head (100) comprises an endless screw (150) arranged between said inlet opening (110) and said outlet nozzle (120) and configured to be able to extrude the loaded material in a continuous manner via said outlet nozzle.

The invention relates to a system for extrusion of filaments of construction material enriched with aggregates and/or steel fibers, referred to as loaded material, for a robot for additive manufacture of architectural structures comprising: a head (100) for printing filaments of construction material comprising an inlet opening (110) for material and an outlet nozzle (120) for material; a circuit (10) for supplying material to said print head (100) comprising a reservoir (20) for storing loaded material and a conduit (31) for supplying material, connecting said storage reservoir (20) and said print head (100); characterized in that said supply circuit (10) comprises at least one piston pump (40) mounted on said supply conduit (31) and in that said print head (100) comprises an endless screw (150) arranged between said inlet opening (110) and said outlet nozzle (120) and configured to be able to extrude the loaded material in a continuous manner via said outlet nozzle.

An extruder, preferably for calcining and extruding raw gypsum, including a calcination zone and a mixing zone, wherein the extruder is optionally configured to capture and/or retain water liberated in the calcination zone, apparatuses and processes employing such extruders and respective uses.

Prefabricated floor element (1) having an elongated shape wherein a longitudinal direction (X), a transversal direction (Y), a height direction (Z), two end faces (11) which delimitate the element (1) in the longitudinal direction (X), two lateral faces (12) which delimitate the element (1) in the transversal direction (Y), a lower face (13) and an upper planar face (14) that delimitate the element (1) in the height direction (Z) are defined, which comprises transversal continuous upper grooves (15) on the upper planar face (14) or lateral grooves (26) on the lateral faces (24), the lateral grooves (26) extending from the lower tab (TS) to the upper planar face (24). The invention also relates to a structure comprising such prefabricated floor element (1) and further comprising a linear supporting element (LS) which supports one end of the prefabricated floor element.

The present invention relates to a brick and a manufacturing method therefor, and provides a brick which has at least improved strength by comprising: as a brick material, soil (e.g., red clay, clay, kaolin, and/or dredged soil), sludge or the like used as a base material; and a solidifying agent for solidifying the base material, and a manufacturing method therefor. According to the present invention, particles of the base material constituting the brick are firmly gathered together, resulting in at least improved strength.

The present invention relates to a brick and a manufacturing method therefor, and provides a brick which has at least improved strength by comprising: as a brick material, soil (e.g., red clay, clay, kaolin, and/or dredged soil), sludge or the like used as a base material; and a solidifying agent for solidifying the base material, and a manufacturing method therefor. According to the present invention, particles of the base material constituting the brick are firmly gathered together, resulting in at least improved strength.