Abstract: A metal 3D printer, a cathode holder system, a carrier for an electron emitter, and an electron source piece with a thermal break in a mechanical interface are provided. The metal 3D printer has an electron gun adapted to direct an electron beam generated by a back heated electron emitter of a cathode arrangement onto a metal material via an anode arrangement. The back heated electron emitter is capable of emitting electrons via thermionic emission from an emitting surface when heated on a back surface, and includes a side surface, essentially perpendicular to the emitting surface, between the emitting surface and the back surface.

Abstract: An arrangement for additive manufacturing by selective fusion of layers of a three-dimensional product from a powder bed including successively formed powder layers is provided. The arrangement includes a heating element having a powder layer facing surface, arranged in a powder layer heating position above a powder layer, in such a way that heat radiation emitted from said heating element heats at least a part of the powder layer before the selective fusion of a layer of the three-dimensional product from the powder layer.

Abstract: A method for removing powder from a component or part produced by metal additive manufacturing systems based on powder beds. The method includes manufacturing a part by additive manufacturing, the part having at least one internal cavity with at least one external opening. The internal cavity is at least partly filled with powder, the powder in the internal cavity having grains agglomerated or connected to each other. The method further including: evacuating gas from the internal cavity; adding liquid electrolyte to the internal cavity, and using an electrochemical process for separating connected powder grains in the cavity.

Abstract: A method for removing powder from a component or part produced by a powder bed additive manufacturing system is provided. The method includes providing a part, the part having at least one internal cavity with at least one external opening, the at least one cavity being at least partly filled with powder grains, the powder grains being connected to each other and to the walls of the cavity by mechanical, frictional, electrical, physical, or chemical forces. The method further includes adding medium in liquid phase to the at least one cavity of the part, the liquid having the property that it expands in phase transition from liquid to solid phase; transforming added medium to solid phase to loosen and break up at least a fraction of the powder grains connections from each other; and removing powder from the at least one internal cavity.

Abstract: A method for manufacturing a three-dimensional object by solidifying selected areas of consecutive powder layers is provided. At least one electron beam successively irradiates predetermined sections of each powder layer by moving an interaction region in which the electron beam interacts with the powder layer. Electromagnetic radiation from a radiation source is directed onto the powder layer to reduce local electrostatic charging in the interaction region. In this way, levitation and scattering of charged powder will be avoided.

Abstract: A method for removing powder from a component or part produced by a powder bed additive manufacturing system is provided. The method includes providing a part, the part having at least one internal cavity with at least one external opening, the at least one cavity being at least partly filled with powder grains, the powder grains being connected to each other and to the walls of the cavity by mechanical, frictional, electrical, physical, or chemical forces. The method further includes adding medium in liquid phase to the at least one cavity of the part, the liquid having the property that it expands in phase transition from liquid to solid phase; transforming added medium to solid phase to loosen and break up at least a fraction of the powder grains connections from each other; and removing powder from the at least one internal cavity.

Abstract: The present invention relates to a method for removing powder from a component or part produced by a powder bed additive manufacturing system. The method comprises the steps; providing a part, the part having at least one internal cavity with at least one external opening, the at least one cavity being at least partly filled with powder grains, the powder grains being connected to each other and to the walls of the cavity by mechanical, frictional, electrical, physical or chemical forces; adding medium in liquid phase to the at least one cavity of the part, the liquid having the property that it expands in phase transition from liquid to solid phase; transforming added medium to solid phase to loosen and break up at least a fraction of the powder grains connections from each other; and removing powder from the at least one internal cavity.

Abstract: The present invention relates to a heating method for preparing a powder bed for subsequent processing by irradiating the powder bed with an electron beam from an electron source. The electron source may be designed for fast moving of the electron beam to different heating positions at the powder bed comprising the step, local heating of at least two powder bed heating positions by successive resting of said electron beam at the at least two powder bed heating positions. By jumping between local preheating positions at the powder bed before the powder is fused, charged powder can be prevented from levitation and scattering from the powder bed.

Abstract: The present invention relates to an apparatus and a method for an electron beam system for manufacturing a three-dimensional object by fusing successive layers of powder, said system having at least one lens for reshaping of said electron beam, an electron source and a powder bed, said method comprising the step: blocking a selected cross section of said electron beam for controlling the electron beam power. By interference between the electron beam and a beam blocking part a portion of the electron beam is prevented from reaching the powder bed.

Abstract: The present invention relates to a build compartment used in 3D printing systems based on powder beds. The build compartment is the volume in a 3D printing apparatus where 3D objects are formed by successive consolidation of thin layers of powder. The build compartment is designed with at least two vertical wall structures movable in relation to each other. The movable wall structures are at least partly overlapping in the movable direction, providing self-sealing for a variable volume for enclosing powder. Contrary to other available designs, this solution does not need a compressible sealing material, for example an elastomer, a textile felt or a braided rope, to prevent powder leakage from the build compartment. The advantages are more reliable sealing and no risk of contamination of the powder by debris from sealing material.

Abstract: The present invention relates to a circuit arrangement comprising an analogue amplifier electrically connected to a first end of an inductive load. Further at least one electrical switch is electrically connected to a second end of the inductive load, where the electrical switch increases the rate of current change in the inductive load by applying an electrical voltage potential to the second end of the inductive load. The voltage at the second end can also be switched by a digital circuit at the second end for improved performance The inductive load may e.g. be a beam control coil, which may be provided for controlling an electron beam, e.g. in an electron gun.

Abstract: The present invention relates to a build compartment used in 3D printing systems based on powder beds. The build compartment is the volume in a 3D printing apparatus where 3D objects are formed by successive consolidation of thin layers of powder. The build compartment is designed with at least two vertical wall structures movable in relation to each other. The movable wall structures are at least partly overlapping in the movable direction, providing self-sealing for a variable volume for enclosing powder. Contrary to other available designs, this solution does not need a compressible sealing material, for example an elastomer, a textile felt or a braided rope, to prevent powder leakage from the build compartment. The advantages are more reliable sealing and no risk of contamination of the powder by debris from sealing material.

Abstract: Three-dimensional (3D) printing systems based on powder beds, in which 3D objects are formed by successive consolidation of thin layers of powder are disclosed. The powder compartment from which powder feedstock is distributed in a 3D printer has at least two vertical wall structures movable in relation to each other, the wall structures being at least partly overlapping in the movable direction, providing a variable volume for enclosing powder. Contrary to other available designs, this solution does not need a compressible sealing material, for example an elastomer, a textile felt or a braided rope, to prevent powder leakage from the powder compartment. The benefits are a simple and robust design providing more reliable sealing and no risk of contamination of the powder by debris from sealing material.

Abstract: The present invention relates to a method for removing powder from a component or part produced by a powder bed additive manufacturing system. The method comprises the steps; providing a part, the part having at least one internal cavity with at least one external opening, the at least one cavity being at least partly filled with powder grains, the powder grains being connected to each other and to the walls of the cavity by mechanical, frictional, electrical, physical or chemical forces; adding medium in liquid phase to the at least one cavity of the part, the liquid having the property that it expands in phase transition from liquid to solid phase; transforming added medium to solid phase to loosen and break up at least a fraction of the powder grains connections from each other; and removing powder from the at least one internal cavity.

Abstract: A method for manufacturing a three-dimensional object by solidifying selected areas of consecutive powder layers is provided. At least one electron beam successively irradiates predetermined sections of each powder layer by moving an interaction region in which the electron beam interacts with the powder layer. Electromagnetic radiation from a radiation source is directed onto the powder layer to reduce local electrostatic charging in the interaction region. In this way, levitation and scattering of charged powder will be avoided.

Abstract: A cathode assembly for emitting charged particles, used in for example an electron gun as source for generating an electron beam is provided. The cathode assembly has a cathode including an emitting member and a carrier. The emitting member is mounted in the carrier, and the carrier is electrically connected to a holder. The cathode is heated by irradiation from an external source, whereby the emitting member emits charged particles from an emitting surface at an emitting temperature. The connection between the carrier and the holder provides a thermal barrier for reducing the amount of thermal energy transferred from the cathode to the holder.

Abstract: A method for removing powder from a component or part produced by metal additive manufacturing systems based on powder beds. The method includes manufacturing a part by additive manufacturing, the part having at least one internal cavity with at least one external opening. The internal cavity is at least partly filled with powder, the powder in the internal cavity having grains agglomerated or connected to each other. The method further including: evacuating gas from the internal cavity; adding liquid electrolyte to the internal cavity, and using an electrochemical process for separating connected powder grains in the cavity.