According to examples, an apparatus may include a reflector having a parabolic shape, the reflector having a focal point and a plane of symmetry. The apparatus may also include a first energy emitter positioned at or near the focal point of the reflector, in which the reflector may reflect energy emitted from the first energy emitter in a first direction to a target area. The apparatus may further include a baffle extending along the plane of symmetry of the reflector, in which the baffle may absorb reflected energy directed to the baffle from the target area.

According to examples, an apparatus may include a reflector having a parabolic shape, the reflector having a focal point and a plane of symmetry. The apparatus may also include a first energy emitter positioned at or near the focal point of the reflector, in which the reflector may reflect energy emitted from the first energy emitter in a first direction to a target area. The apparatus may further include a baffle extending along the plane of symmetry of the reflector, in which the baffle may absorb reflected energy directed to the baffle from the target area.

An additive manufacturing apparatus is disclosed including an additive manufacturing platform; a material feeding unit configured to feed a material onto the additive manufacturing platform; a laser generating unit configured to generate a laser beam with a linear light spot for projecting onto the material on the additive manufacturing platform; and a movement driving unit configured to drive at least one of the laser generating unit, the additive manufacturing platform and the material feeding unit to move in at least one direction. An additive manufacturing method is also disclosed. With the additive manufacturing apparatus and method, an additive manufacturing process can be performed efficiently, and are particularly suitable for an additive manufacturing process of large-size components.

An additive manufacturing machine includes an energy beam system situated in a fixed position relative to a reference plane coinciding with an expected location of a build plane, an energy beam system with an irradiation device configured to generate an energy beam and to direct the energy beam upon the build plane, and a position measurement system configured to determine a position of the build plane. A position measurement assembly includes one or more position sensors, and one or more mounting brackets configured to attach the one or more position sensors to an energy beam system of an additive manufacturing machine. The position measurement assembly is configured to determine a position of a build plane with the energy beam system situated in a fixed position relative to a reference plane coinciding with an expected location of the build plane.

An additive manufacturing machine includes an energy beam system situated in a fixed position relative to a reference plane coinciding with an expected location of a build plane, an energy beam system with an irradiation device configured to generate an energy beam and to direct the energy beam upon the build plane, and a position measurement system configured to determine a position of the build plane. A position measurement assembly includes one or more position sensors, and one or more mounting brackets configured to attach the one or more position sensors to an energy beam system of an additive manufacturing machine. The position measurement assembly is configured to determine a position of a build plane with the energy beam system situated in a fixed position relative to a reference plane coinciding with an expected location of the build plane.

A method of manufacturing a three-dimensionally formed object includes: forming a layer using a flowable composition including constituent material particles of a three-dimensionally formed object and a flowable composition including support portion-forming particles for forming a support portion which supports the three-dimensionally formed object during the formation of the three-dimensionally formed object; and imparting energy to the constituent material particles and the support portion-forming particles, in which in the imparting of the energy, the energy is imparted such that a temperature of the constituent material particles and a temperature of the support portion-forming particles are equal to or higher than a sintering temperature of the constituent material particles and are lower than a sintering temperature of the support portion-forming particles.

The present disclosure is drawn to material sets for 3-dimensional printing. The material set can include a thermoplastic polymer powder having an average particle size from 20 m to 100 m, a conductive fusing ink comprising a transition metal, and second fusing ink. The second fusing ink can include a fusing agent capable of absorbing electromagnetic radiation to produce heat. The second fusing ink can provide a lower conductivity than the conductive fusing ink when printed on the thermoplastic polymer powder.

An additive manufacturing apparatus including an energy source configured for transmitting a laser, a build plate configured to have a powder configured to be heated by the laser for additive manufacturing, at least one mirror positioned between the energy source and the build plate, the at least one mirror configured to direct the laser from the energy source to the build plate, and an optical isolator configured to reduce energy bounce back into the energy source.

A smart additive manufacturing system uses a spectrometer to collect emission spectra along an optical axis from a laser-generated plasma plume, and wherein the laser beam and the optical axis of the emission spectra are co-axial, at least in the vicinity of the melt pool, thereby minimizing the fluctuation of spectral signals caused by ambient pressure/gas variations. The laser beam passes through a beam splitter prior to reaching the work piece, and the emission spectra from the work piece are redirected by the beam splitter to the spectrometer, and wherein the laser beam and the optical axis of the emission spectra are co-axial between the work piece and the beam splitter. The beam splitter may be a dichroic mirror or other type of beam splitter, including holographic beam splitters, and spectral filtering may be carried out with separate optical elements, as long as the overall goal of on-axis excitation and collection is achieved.

A processing apparatus with: an irradiation apparatus that emits an energy beam; and a supply apparatus that supplies materials to an irradiation position of the energy beam, the processing apparatus forms a build object by moving the irradiation position from a first position on a first object to a second position that is away from the first object.