A three-dimensional manufacturing apparatus and a three-dimensional manufacturing method easily adjust a heating quantity per unit area individually for a solidified region and a non-solidified region of a powder material. A layer formation unit forms a layer of a powder material. Light sources and heat scanning units heat the layer by laser beams. The laser beam heats a solidified region in which the powder material has been fused and solidified. The laser beam heats the non-solidified region of the powder material, which is adjacent to the solidified region. The controlling section controls the light sources and the heat scanning units so as to move the laser beams along a boundary between the solidified region and the non-solidified region, and to fuse and solidify a manufacturing region of the layer.

A manufacturing method includes a mixing step, a kneading step of kneading a wet mixture, a liquid adding step of further adding a liquid to a kneaded material, a forming step of extruding a forming material of which viscosity is adjusted into a honeycomb formed body, a drying step of drying the honeycomb formed body, and a dimension measuring step of measuring a dry dimension of a honeycomb dried body that has been dried, where in the liquid adding step, the amount of the liquid to be added is adjusted based on the result of measuring the dry dimension of the honeycomb dried body.

A method and device for producing lightweight panels with a core of gypsum or of cement and gypsum, with pores for decreasing volumetric weight, and with a covering made of cardboard or of a sheet of glass fibers. The production line does not change except for the addition of a device which forms closed hollow cavities within a suspension in an area where an upper sheet covers the suspension. Air pressure which is fed into the formed cavities is slightly higher than the hydraulic pressure of the suspension, so as to prevent the gaps being filled by the suspension. The layers are less thick, and the type and dimensions of the cavities and the thickness of the walls are varied depending on the desired qualities of the panels.

In one example, a method of fabricating a three-dimensional object includes depositing a layer of build material, depositing a coalescing agent onto the layer of build material according to a slice of three-dimensional model data, irradiating the coalescing agent with microwave radiation such that the coalescing agent converts the microwave radiation into heat to coalesce the build material in which the coalescing agent was deposited.

A system and method for manufacturing a set of cast stones includes a set of spray stations, a set of fill stations, a set of vibration tables, a drying rack, and a demolder connected to the drying rack. A controller is connected to each of the set of spray stations, the set of fill stations, the set of vibration tables, the drying rack, and the demolder, each of which has a set of sensors connected to the controller. The set of spray stations include a set of release stations and a set of color stations. A mold is sprayed with a release product, a set of colors, and then filled with a cementitious material. Once vibrated, the cementitious material is dried to form the set of cast stones, which is then automatically released from the mold utilizing the demolder.

A method for additive manufacturing of an object, in particular a hybrid object, based on a data record describing an object to be additively manufactured, includes providing a data record describing the object to be additively manufactured, subdividing the data record into at least two sub-data records, wherein a first sub-data record describes a first sub-object forming a first object part of the object to be additively manufactured, and at least one other sub-data record describes another sub-object forming another object part of the object to be additively manufactured, forming the first sub-object based on the first sub-data record in a first additive construction process, and forming the at least one other sub-object based on the at least one other sub-data record in at least one separate other additive construction process, wherein the at least one other sub-object is formed at least partially, especially completely, on the first sub-object.

The method comprises the steps of: a) supplying building material; and b) fusing the building material using a light beam (2); wherein steps a) and b) are carried out so as to progressively produce the object out of the fused building material. In step b), the beam (2) is projected onto the building material so as to produce a primary spot on the building material, the beam being repetitively scanned in two dimensions in accordance with a first scanning pattern so as to establish an effective spot (21) on the building material, said effective spot having a two-dimensional energy distribution. The effective spot (21) is displaced in relation to the object being produced to progressively produce the object by fusing the building material.

A strongly scattering optoceramic converter material having a density of less than 97% is provided, as well as a method for producing such an optoceramic material. By appropriately choosing in particular the composition, blending method, and sintering conditions, the production method permits to produce converter materials with tailored properties.

A strongly scattering optoceramic converter material having a density of less than 97% is provided, as well as a method for producing such an optoceramic material. By appropriately choosing in particular the composition, blending method, and sintering conditions, the production method permits to produce converter materials with tailored properties.

A method of printing includes mixing a clay mixture with an alkaline agent to form a printable mixture; forming pellets from the printable mixture; ejecting the pellets from a print head onto a printing surface; and curing the pellets.