A system and a method are disclosed for detecting and regulating a microstructure online with an electromagnetic assistance. The system comprises a substrate, and a forming device, a detecting device and a regulating device located above the substrate, the detecting device is connected with the regulating device comprising an electromagnetic shock regulating unit and an electromagnetic stirring regulating unit; a workpiece may be formed layer by layer on the substrate through the forming device, the detecting device performs a real-time detection for the microstructure in a formed area, and transmits a detection result to the regulating device, and according to the detection result, the electromagnetic shock regulating unit may perform the electromagnetic shock on a newly formed fused micro area, or the electromagnetic stirring regulating unit may perform the electromagnetic stirring on a molten pool to regulate the microstructure of the workpiece.

A metal matrix composite composition includes tungsten carbide in an amount of 45 wt % to 72 wt % of the composition. In addition, the composition includes a binder in an amount of 28 wt % to 55 wt % of the composition. The binder includes nickel in an amount of at least 99 wt % of the binder.

A metal matrix composite composition includes tungsten carbide in an amount of 45 wt % to 72 wt % of the composition. In addition, the composition includes a binder in an amount of 28 wt % to 55 wt % of the composition. The binder includes nickel in an amount of at least 99 wt % of the binder.

A three-dimensional powder bed fusion additive manufacturing apparatus includes: a base plate; a Z drive mechanism configured to move the base plate in a vertical direction; a powder supplier configured to supply a powder sample onto the base plate to laminate a powder layer; an electron gun configured to generate a beam to be irradiated to the powder layer; a controller configured to control the Z drive mechanism, the powder supplier, and the electron gun to irradiate the beam to a powder bed that is an uppermost layer of the powder layer and perform melting on a two-dimensionally shaped region in which a shaped model is sliced by one layer to shape a three-dimensionally shaped object; and two segment detectors configured to detect a state of the powder bed.

A three-dimensional powder bed fusion additive manufacturing apparatus includes: a base plate; a Z drive mechanism configured to move the base plate in a vertical direction; a powder supplier configured to supply a powder sample onto the base plate to laminate a powder layer; an electron gun configured to generate a beam to be irradiated to the powder layer; a controller configured to control the Z drive mechanism, the powder supplier, and the electron gun to irradiate the beam to a powder bed that is an uppermost layer of the powder layer and perform melting on a two-dimensionally shaped region in which a shaped model is sliced by one layer to shape a three-dimensionally shaped object; and two segment detectors configured to detect a state of the powder bed.

A device for measuring the depth of a weld seam in real time during the welding or joining of a workpiece by means of radiation, including: its measuring light source, the light of which is coupled by a beam splitter into a reference arm and a measuring arm; a collimator module having at least one collimation lens for collimating a measuring light beam, which is fed to the collimator module via an optical waveguide in the measuring arm, and for imaging the measuring light beam, which is reflected from a workpiece to be processed, on an exit/entry surface of the optical waveguide; a coupling element for coupling the measuring light beam into the beam path of a processing beam; a focusing lens for the joint focusing of the measuring light beam and the processing beam on the workpiece and for the collimating of the reflected measuring light beam; and an analysis unit for determining the depth of a weld seam, into which the measuring light reflected from the workpiece is guided with the superimposed, reflected light from the reference arm. The collimator module includes a device for setting the axial focal position of the measuring light beam, and for setting the lateral focal position of the measuring light beam, and a field lens, which is arranged between the exit/entry surface of the optical waveguide and the collimation lens and defines the beam widening of the measuring light beam and therefore the focus diameter of the measuring light beam.

A device for measuring the depth of a weld seam in real time during the welding or joining of a workpiece by means of radiation, including: its measuring light source, the light of which is coupled by a beam splitter into a reference arm and a measuring arm; a collimator module having at least one collimation lens for collimating a measuring light beam, which is fed to the collimator module via an optical waveguide in the measuring arm, and for imaging the measuring light beam, which is reflected from a workpiece to be processed, on an exit/entry surface of the optical waveguide; a coupling element for coupling the measuring light beam into the beam path of a processing beam; a focusing lens for the joint focusing of the measuring light beam and the processing beam on the workpiece and for the collimating of the reflected measuring light beam; and an analysis unit for determining the depth of a weld seam, into which the measuring light reflected from the workpiece is guided with the superimposed, reflected light from the reference arm. The collimator module includes a device for setting the axial focal position of the measuring light beam, and for setting the lateral focal position of the measuring light beam, and a field lens, which is arranged between the exit/entry surface of the optical waveguide and the collimation lens and defines the beam widening of the measuring light beam and therefore the focus diameter of the measuring light beam.

A method for layer-by-layer manufacturing of a three-dimensional metallic work piece, comprising the steps of: delivering a metallic feed material in a substantially solid state into a feed region; emitting an electron beam; and translating the electron beam through a first predetermined raster pattern frame in an x-y plane. The method may also include monitoring a condition of one or both of the feed region or the substrate region in real time for the occurrence of any deviation from a predetermined condition; upon detecting of any deviation, translating the electron beam through at least one second predetermined raster pattern frame in the x-y plane that maintains the melting beam power density level substantially the same as the first predetermined raster pattern frame, but alters the substrate beam power density level.

A method for layer-by-layer manufacturing of a three-dimensional metallic work piece, comprising the steps of: delivering a metallic feed material in a substantially solid state into a feed region; emitting an electron beam; and translating the electron beam through a first predetermined raster pattern frame in an x-y plane. The method may also include monitoring a condition of one or both of the feed region or the substrate region in real time for the occurrence of any deviation from a predetermined condition; upon detecting of any deviation, translating the electron beam through at least one second predetermined raster pattern frame in the x-y plane that maintains the melting beam power density level substantially the same as the first predetermined raster pattern frame, but alters the substrate beam power density level.

A method for producing a three-dimensional object by applying layers of a pulverulent construction material and by selectively solidifying said material by the action of energy comprises the steps: a layer of the pulverulent construction material is applied to a support or to a layer of the construction material that has been previously applied and at least selectively solidified; an energy beam from an energy source sweeps over points on the applied layer corresponding to a cross-section of the object to be produced in order to selectively solidify the pulverulent construction material; and a gas flow is guided in a main flow direction (RG) over the applied layer during the sweep of the energy beam. The main flow direction (RG) of the gas flow (G) and the sweep direction (RL) of the energy beam are adapted to one another at least in one region of the cross-section to be solidified.