Abstract: A powder module for an apparatus for additive manufacturing of three-dimensional objects, comprising a powder chamber limiting a powder room that can be filled with powdered construction material and a carrying device arranged in the powder room and limiting the powder room at the bottom, wherein between at least one powder chamber wall limiting the powder room and the carrying device a gap extending at least partially along the powder chamber wall limiting the powder room is formed, through which powdered construction material from the powder room can enter a powder module section lying below the carrying device, wherein the gap opens out into a receiving section of a receiving element arranged or formed on the powder chamber, wherein the receiving section is formed as or comprises an especially ring-shaped circumferential flow channel structure provided for receiving construction material from the gap.

Abstract: The invention relates to a powder module (1) for an apparatus for additive manufacturing of three-dimensional objects, comprising: a powder chamber (2) limiting a powder room (3) that can be filled with powdered construction material, a carrying device (4) arranged in the powder room (3), limiting the powder room (3) at the bottom and movably supported relative to the powder chamber (2), and a drive device (5) for generating a force setting the carrying device (4) in motion relative to the powder chamber (2), wherein the drive device (5) comprises at least two separate adjustment units (6a, 6b), that especially are coupled for movement, with at least one, especially cylindrical, adjustment element (7a, 7b), wherein each adjustment element (7a, 7b) is movably supported relative to a respective housing element (8a, 8b) of the respective adjustment unit (6a, 6b) between a first end position and a second end position.

Abstract: A powder module (1) for an apparatus for additive manufacturing of three-dimensional objects, comprising a powder chamber (2) limiting a powder room (3) that can be filled with powdered construction material, a carrying device (4) arranged in the powder room (3), limiting the powder room (3) at the bottom, movably supported relative to the powder chamber (2), and a position detection device (6), which is provided for the detection of the position of the carrying device (4), wherein the position detection device (6) is formed as or at least comprises a cable pull sensor.

Abstract: The invention relates to a powder chamber table assembly (1) for a powder module, especially a construction module, of an apparatus for additive manufacturing of three-dimensional objects, comprising at least two components or component groups to be sealed to each other especially in terms of the intrusion of powdered construction material, wherein the at least two components or component groups are sealed to each other by at least one sealing element (9), wherein the sealing element (9) is formed of or comprises a high temperature resistant silicone material.

Abstract: The invention relates to a construction chamber (1) for an apparatus for additive manufacturing of three-dimensional objects, comprising a construction chamber base body (2) which limits a construction volume (4) forming a construction room (3), wherein the construction chamber base body (2) is formed segmented in several construction chamber base body segments (2a, 2b) that can be attached or are attached to each other forming the construction chamber base body (2).

Abstract: Device for the additive production of three-dimensional components (2), namely a laser melting device or laser sintering device, in which a component (2) is produced by successive solidifying of individual layers (3) made from solidifiable construction material, by the effect of radiation (4), through melting of the construction material (5), wherein the dimensions and/or temperature of the melt area (6) generated by a point-shaped or line-shaped energy input can be captured by a sensor device (8) of a process monitoring system, and sensor values for evaluation of a component quality can be deduced therefrom, wherein the radiation (9) created by the melt area and used for the generation of the sensor values passes through the scanner used for the melt energy input, and is guided from there to the sensor device (8) of the process monitoring system, wherein an optical focus tracking device (20) is arranged in the radiation path used for generation of the sensor values between the scanner (10) and the sensor dev

Abstract: A method for controlling the exposure of a selective laser sintering or laser melting apparatus. The method includes providing a selective laser sintering apparatus or laser melting apparatus that uses successive solidification of layers of a powder-type construction material that can be solidified using radiation.

Abstract: The invention relates to a device for producing three-dimensional objects by successive solidification of layers of a construction material that can be solidified using radiation on the positions corresponding to the respective cross-section of the object, comprising a construction chamber in which a carrying device for carrying the object is arranged with a height adjustable carrier, a radiation device for radiating layers of the construction material at positions corresponding to the respective cross-section of the object, and an image acquisition device for acquiring at least one image data record representing the construction chamber, wherein in the construction chamber at least one position mark for calibrating the image acquisition device is present. In addition, the invention relates to a method for performing a calibration.

Abstract: A method for producing a three-dimensional component by means of a laser melting process, in which the component is produced by consecutively solidifying individual layers made of building material by melting the building material, wherein said building material can be solidified by the action of radiation, wherein the melting area produced by a punctiform and/or linear energy input is detected by a sensor device and sensor values are derived therefrom in order to evaluate the component quality. The sensor values detected in order to evaluate the component quality are stored together with the coordinate values that locate the sensor values in the component and are displayed by means of a visualization unit in two- and/or multi-dimensional representation with respect to the detection location of the sensor values in the component.