A system for determining a temperature of an object includes a three-dimensional (3D) printer configured to successively deposit a first layer of material, a second layer of material, and a third layer of material to form the object. The 3D printer is configured to form a recess in the second layer of material. The material is a metal. The system also includes a temperature sensor configured to be positioned at least partially with the recess and to have the third layer deposited thereon. The temperature sensor is configured to measure a temperature of the first layer of material, the second layer of material, the third layer of material, or a combination thereof.

Estimation algorithms, methods, and systems are provided that estimate the internal temperatures inside of a part being built using a Finite Element Method (FEM)-based thermal model of Powder Bed Fusion (PBF) heat transfer. Closed-loop state estimation is applied to the problem of monitoring temperature fields within parts during the PBF build process. The PBF laser is very small, therefore, so too are the FEM elements nearby the laser. Thus, as the PBF laser moves, a region of high mesh density moves along with it as it progresses over a geometry. In an aspect, regions of high mesh density are predetermined for each time step according to a predefined schedule of laser movements.

Estimation algorithms, methods, and systems are provided that estimate the internal temperatures inside of a part being built using a Finite Element Method (FEM)-based thermal model of Powder Bed Fusion (PBF) heat transfer. Closed-loop state estimation is applied to the problem of monitoring temperature fields within parts during the PBF build process. The PBF laser is very small, therefore, so too are the FEM elements nearby the laser. Thus, as the PBF laser moves, a region of high mesh density moves along with it as it progresses over a geometry. In an aspect, regions of high mesh density are predetermined for each time step according to a predefined schedule of laser movements.

Methods and apparatuses for additive manufacturing are described. A method for additive manufacturing may include exposing a layer of material on a build surface to one or more projections of laser energy including at least one line laser having a substantially linear shape. The intensity of the line laser may be modulated so as to cause fusion of the layer of material according to a desired pattern as the one or more projections of laser energy are scanned across the build surface.

Methods and apparatuses for additive manufacturing are described. A method for additive manufacturing may include exposing a layer of material on a build surface to one or more projections of laser energy including at least one line laser having a substantially linear shape. The intensity of the line laser may be modulated so as to cause fusion of the layer of material according to a desired pattern as the one or more projections of laser energy are scanned across the build surface.

This disclosure describes an additive manufacturing method that includes monitoring a temperature of a portion of a build plane during an additive manufacturing operation using a temperature sensor as a heat source passes through the portion of the build plane; detecting a peak temperature associated with one or more passes of the heat source through the portion of the build plane; determining a threshold temperature by reducing the peak temperature by a predetermined amount; identifying a time interval during which the monitored temperature exceeds the threshold temperature; identifying, using the time interval, a change in manufacturing conditions likely to result in a manufacturing defect; and changing a process parameter of the heat source in response to the change in manufacturing conditions.

A production method for an alloy member having mainly high hardness and high resistance to corrosion and produced by an additive manufacturing method, the alloy member, and a product using the alloy member are provided. The production method for an alloy member includes: an additive manufacturing step of forming a shaped member through an additive manufacturing method using an alloy powder containing elements Co, Cr, Fe, Ni, and Ti each in a range of 5 atom% to 35 atom% and containing Mo in a range exceeding 0 atom% and 8 atom% or less, the remainder being unavoidable impurities; and a heat treatment step of holding the shaped member in a temperature range higher than 500° C. and lower than 900° C. directly after the additive manufacturing step without undergoing a step of holding the shaped member in a temperature range of 1080° C. to 1180° C.

An apparatus and method of mechanical milling and grinding of various materials at temperatures ranging from sub-ambient conditions to well-below their ductile-brittle transition temperature (DBTT) are presented. In one embodiment the present invention entails the design of a cryogenic milling chamber compatible with horizontal high-energy mills. The new design and configuration of the milling vessel provides robust and efficient cryomilling of various materials with no contact between the cryogen and the powders. Some embodiments of the invention improve the heat removal rate from the non-uniform heat load generated by the impact energy deposited into the chamber wall by the milling media.

An apparatus and method of mechanical milling and grinding of various materials at temperatures ranging from sub-ambient conditions to well-below their ductile-brittle transition temperature (DBTT) are presented. In one embodiment the present invention entails the design of a cryogenic milling chamber compatible with horizontal high-energy mills. The new design and configuration of the milling vessel provides robust and efficient cryomilling of various materials with no contact between the cryogen and the powders. Some embodiments of the invention improve the heat removal rate from the non-uniform heat load generated by the impact energy deposited into the chamber wall by the milling media.

One of the objects of the present application is to provide a technique capable of preventing the generation of excessive metallic vapor during fabrication according to an AM technique. Further, one of the objects of the present application is to provide a technique for reducing machining processing after the fabrication as much as possible or eliminating the necessity thereof. According to one aspect, an AM apparatus configured to manufacture a fabrication object is provided. This AM apparatus includes a first DED nozzle configured to fabricate a contour of a fabrication target and a second DED nozzle configured to fabricate an inner portion of the contour.