The present invention relates to a method for the production of a three-dimensional object (2) by way of layered solidification of a powder construction material (11) by way of electromagnetic radiation, in particular laser radiation, having the steps: scanning points, which correspond to a cross section of the object (2) to be produced, of an applied layer of the powder construction material (11) with an electromagnetic beam (22) from a radiation source (21) for purposes of selectively solidifying the powder construction material (11), conducting a gas flow (33) across the applied layer during the scanning with the electromagnetic beam (22) and performing an irregularity determination with regard to the presence of a process irregularity with regard to at least one process parameter during the production, wherein during the scanning by way of the electromagnetic beam (22), the scanning process at least one present point of the cross section to be solidified is interrupted on the basis of a result of the irregularity determination.

A high-energy beam additive manufacturing forming device and forming method, comprising a magnetic field unit for assisting additive forming, and further comprising a forming base (6) for placing a material (12) to be processed, and a high-energy beam generation device which emits a high-energy beam, acts on the material (12) to be processed and forms a molten pool (15). The magnetic field unit comprises a first magnetic field generating device (7), and the first magnetic field generating device (7) comprises an induction coil (20) provided below the molten pool (15). The first magnetic field generating device (7) is detachably provided below a surface, used for containing the material (12) to be processed, of the forming base (6); second magnetic field generating devices (16) are provided above the forming base (6); the induction coil (20) is provided below the molten pool (15), and the molten pool (15) is located in an area, where clustered magnetic induction lines are emitted, of the induction coil (20), so that the clustered magnetic induction lines penetrate through the molten pool (15). Therefore, the magnetic field intensity of the molten pool (15) is concentrated, the control effect of the magnetic field on additive forming is improved, and the control efficiency of the magnetic field unit on the molten pool (15) is improved.

An additive manufacturing process is disclosed that involves positioning a metallic layer beneath a component substrate and welding the metallic layer to the component substrate using laser energy.

An additive manufacturing process is disclosed that involves positioning a metallic layer beneath a component substrate and welding the metallic layer to the component substrate using laser energy.

The present disclosure describes binder agents for printing three-dimensional green body objects, three-dimensional printing kits, and methods of three-dimensional printing. In one example, a binder agent for printing a three-dimensional green body object can include water, an organic co-solvent, a glycidyl compound having two or more glycidyl groups per molecule, and latex particles. The latex particles can include polymerized monomers. The polymerized monomers can include a first monomer having an acid group, and a second monomer having a vinyl group and without an acid group.

The present disclosure describes binder agents for printing three-dimensional green body objects, three-dimensional printing kits, and methods of three-dimensional printing. In one example, a binder agent for printing a three-dimensional green body object can include water, an organic co-solvent, a glycidyl compound having two or more glycidyl groups per molecule, and latex particles. The latex particles can include polymerized monomers. The polymerized monomers can include a first monomer having an acid group, and a second monomer having a vinyl group and without an acid group.

A system is disclosed for additively manufacturing a composite structure. The system may include a print head configured to discharge a continuous reinforcement that is at least partially coated in a matrix, and a compactor configured to compact the continuous reinforcement and the matrix. The system may also include a cure enhancer configured to direct a path of cure energy toward the matrix after discharge, wherein the path of cure energy passes through at least a portion of the compactor.

A system is disclosed for additively manufacturing a composite structure. The system may include a print head configured to discharge a continuous reinforcement that is at least partially coated in a matrix, and a compactor configured to compact the continuous reinforcement and the matrix. The system may also include a cure enhancer configured to direct a path of cure energy toward the matrix after discharge, wherein the path of cure energy passes through at least a portion of the compactor.

The present application provides a technique for testing execution data and an operation of an AM apparatus by bringing the AM apparatus into operation before actually carrying out fabrication. An AM apparatus configured to manufacture a fabricated object is provided. This AM apparatus includes a chamber defining a space used to manufacture the fabricated object, a base plate disposed in the chamber and configured to support a material of the fabricated object, a beam source configured to irradiate the material on the base plate with a beam, a computer configured to determine an irradiation position of the beam based on three-dimensional data of the fabricated object, a scanning mechanism configured to move the beam according to the determined irradiation position, a detector configured to detect an irradiation position of the beam applied into the chamber, and an evaluator configured to compare the determined irradiation position and the detected irradiation position.

The present application provides a technique for testing execution data and an operation of an AM apparatus by bringing the AM apparatus into operation before actually carrying out fabrication. An AM apparatus configured to manufacture a fabricated object is provided. This AM apparatus includes a chamber defining a space used to manufacture the fabricated object, a base plate disposed in the chamber and configured to support a material of the fabricated object, a beam source configured to irradiate the material on the base plate with a beam, a computer configured to determine an irradiation position of the beam based on three-dimensional data of the fabricated object, a scanning mechanism configured to move the beam according to the determined irradiation position, a detector configured to detect an irradiation position of the beam applied into the chamber, and an evaluator configured to compare the determined irradiation position and the detected irradiation position.