Abstract: A measuring device is provided having at least one substrate, which contains or consists of a polymer or a glass, at least one optical waveguide being written in the substrate, in which at least one Bragg grating with a predeterminable grating constant is arranged, wherein the measuring device further includes an evaluation device, which is configured to determine a deformation of the substrate and/or a force acting on the substrate from a change in the grating constant and/or a change in the refractive index of the Bragg grating.

Abstract: A calibration method serves for calibrating a manufacturing device for additively producing a three-dimensional object by applying layer by layer and selectively solidifying a building material. The manufacturing device comprises at least two scanning units, each of which is capable of directing a beam to different target points in the working plane, which are located within a scanning region assigned to the respective scanning unit, wherein the scanning regions region of the at least two scanning units overlap in an overlap area. At least a first of the at least two scanning units is assigned a first monitoring unit whose monitoring region extends to a target point of the first scanning unit and its proximity, wherein a change of a position of the monitoring region is carried out as a function of a change of a position of the target point.

Abstract: A fire-resistant glazing is disclosed which comprises at least two transparent plies and at least one transparent fire-resistant layer wherein each fire-resistant layer is an interlayer for two plies and at least one fire-resistant interlayer comprises a hydrogel based on an aluminium 1,2,3-tricarboxy late, for example, aluminium citrate. A base solution and method for the production of the fire-resistant glazing is also disclosed.

Abstract: This invention relates to a fire-resistant glazing (1), a precursor solution for forming an intumescent layer (30) of a fire-resistant glazing (1), a method of manufacturing the fire-resistant glazing (1), and to the use of a fire-resistant glazing (1). More specifically, the present invention relates to a fire-resistant glazing (1) which comprises a phase separation additive and to the manufacture and use thereof.

Abstract: A control method serves for controlling at least one solidification device of an additive manufacturing device for manufacturing a three-dimensional object by means of an additive layer build method in which at least one object is manufactured by repeated application of a layer of a building material to a build area and by selective solidification of the applied layer at positions corresponding to a cross-section of the object to be manufactured, wherein a gas having a plurality of flow directions which essentially are not aligned in the same direction flows across the build area.

Abstract: The invention relates to a computer-assisted method for generating a control data set for an additive layer manufacturing device. In a first step, a layer data set is accessed, wherein points are marked in the data model which correspond to an object cross-section and at which the bid-up material should be solidified. In a second step, the layer data set is modified in such a way that for at least a portion of the object cross-section, the number of beams required for solidifying the build-up material inside said portion is determined preferably automatically, according to quality specifications of the portion and/or a manufacturing time of the object. In a third step, the modified layer data set is provided as a control data set for the additive layer manufacturing device.

Abstract: A framework in which computing devices can divide messages into chunks or sub-portions for transmission in accordance with a topic-based messaging protocol. A caching service facilitates the receipt of a set of messages with individual sub-portions. The caching service uses embedded information in the sub-portion messages to determine when a full set of sub-portions have been received. The caching service can release a completed set of sub-portion messages to an intended network service recipient or utilizing time expiration caching criteria to wait for additional messages.

Abstract: A calibration method serves for calibrating a manufacturing device for additively producing a three-dimensional object by applying layer by layer and selectively solidifying a building material. The manufacturing device comprises at least two scanning units, each of which is capable of directing a beam to different target points in the working plane, which are located within a scanning region assigned to the respective scanning unit, wherein the scanning regions region of the at least two scanning units overlap in an overlap area. At least a first of the at least two scanning units is assigned a first monitoring unit whose monitoring region extends to a target point of the first scanning unit and its proximity, wherein a change of a position of the monitoring region is carried out as a function of a change of a position of the target point.

Abstract: A calibration method serves for calibrating a manufacturing device for additively producing a three-dimensional object by applying layer by layer and selectively solidifying a building material. The manufacturing device comprises at least two scanning units, each of which is capable of directing a beam to different target points in the working plane, which are located within a scanning region assigned to the respective scanning unit, wherein the scanning regions region of the at least two scanning units overlap in an overlap area. At least a first of the at least two scanning units is assigned a first monitoring unit whose monitoring region extends to a target point of the first scanning unit and its proximity, wherein a change of a position of the monitoring region is carried out as a function of a change of a position of the target point.

Abstract: Disclosed is a method of generating a ceiling gas stream in the course of the generative manufacturing of a three-dimensional object in a process chamber by a layer-by-layer application and selective solidification of a building material within a build area arranged in the process chamber. The process chamber has a chamber wall having a process chamber ceiling lying above the build area. A ceiling gas stream of a process gas is passed through the process chamber which is streaming from the process chamber ceiling towards the build area in a controlled manner. In the course of this, the ceiling gas stream is supplied to the process chamber through ceiling inlets formed in the process chamber ceiling such that the ceiling gas stream is directed substantially perpendicularly to the build area downwards onto the build area as it exits the ceiling inlets.

Abstract: A control method serves for controlling at least one solidification device of an additive manufacturing device for manufacturing a three-dimensional object by means of an additive layer build method in which at least one object is manufactured by repeated application of a layer of a building material, to a build area and by selective solidification of the applied layer at positions corresponding to a cross-section of the object to be manufactured, wherein a gas having a plurality of flow directions which essentially are not aligned in the same direction flows across the build area.

Abstract: The invention relates to a computer-assisted method for generating a control data set for an additive layer manufacturing device. In a first step, a layer data set is accessed, wherein points are marked in the data model which correspond to an object cross-section and at which the bid-up material should be solidified. In a second step, the layer data set is modified in such a way that for at least a portion of the object cross-section, the number of beams required for solidifying the build-up material inside said portion is determined preferably automatically, according to quality specifications of the portion and/or a manufacturing time of the object. In a third step, the modified layer data set is provided as a control data set for the additive layer manufacturing device.

Abstract: A recoater for applying a building material in a device for manufacturing a three-dimensional object within a build area by solidifying layers of the building material at the points corresponding to the respective cross-section of the object is suitable for applying a building material layer by moving across the build area in a movement direction. The recoater comprises a first scanning device including a first line sensor, for capturing at least a subarea of the build area.

Abstract: The invention refers to a method of generatively manufacturing a three-dimensional object (2) in a process chamber (3) of a generative manufacturing apparatus (1) by a layer-by-layer application and selective solidification of a building material (13) within a build area (10) arranged in the process chamber. In the course of this, while the object is being manufactured, a process gas is supplied to the process chamber by means of a gas supply device and is discharged from the process chamber via an outlet (42a, 42b). According to the invention, the gas supply device is designed and/or arranged relatively to the build area and/or controlled such that a gas stream (40) of the process gas streaming through the process chamber is shaped in such a manner that a substantially elongate oval impingement area (A3) of the gas stream (40) is generated within the build area (10).

Abstract: A recoater for applying a building material in a device for manufacturing a three-dimensional object within a build area by solidifying layers of the building material at the points corresponding to the respective cross-section of the object is suitable for applying a building material layer by moving across the build area in a movement direction. The recoater comprises a first scanning device including a first line sensor, for capturing at least a subarea of the build area.

Abstract: A calibration method serves for calibrating a manufacturing device for additively producing a three-dimensional object by applying layer by layer and selectively solidifying a building material. The manufacturing device comprises at least two scanning units, each of which is capable of directing a beam to different target points in the working plane, which are located within a scanning region assigned to the respective scanning unit, wherein the scanning regions region of the at least two scanning units overlap in an overlap area. At least a first of the at least two scanning units is assigned a first monitoring unit whose monitoring region extends to a target point of the first scanning unit and its proximity, wherein a change of a position of the monitoring region is carried out as a function of a change of a position of the target point.

Abstract: The invention refers to a method of generating a ceiling gas stream (44) in the course of the generative manufacturing of a three-dimensional object (2) in a process chamber (3) by a layer-by-layer application and selective solidification of a building material (13) within a build area (10) arranged in the process chamber. In the course of this, the process chamber has a chamber wall (4) having a process chamber ceiling (4a) lying above the build area (10). According to the invention, at least temporarily before and/or during and/or after the manufacturing of the object (2), a ceiling gas stream (44) of a process gas is passed through the process chamber (3) which is streaming from the process chamber ceiling (4a) towards the build area (10) in a controlled manner.

Abstract: The invention refers to a method of generatively manufacturing a three-dimensional object (2) in a process chamber (3) of a generative manufacturing apparatus (1) by a layer-by-layer application and selective solidification of a building material (13) within a build area (10) arranged in the process chamber. In the course of this, while the object is being manufactured, a process gas is supplied to the process chamber by means of a gas supply device and is discharged from the process chamber via an outlet (42a, 42b). According to the invention, the gas supply device is designed and/or arranged relatively to the build area and/or controlled such that a gas stream (40) of the process gas streaming through the process chamber is shaped in such a manner that a substantially elongate oval impingement area (A3) of the gas stream (40) is generated within the build area (10).