An additive manufacturing system is provided. The system includes: a stage, a powder supplying device, an energy beam generating device and an atmosphere controlling module. The powder supplying device provides powder to the stage. The energy beam-generating device generates an energy beam and directs the energy beam to the stage. The atmosphere controlling module includes at least one pair of gas inlet-outlet devices coupled around the stage, and a dynamic gas flow controlling device connected with the gas inlet-outlet devices. The dynamic gas flow controlling device dynamically controls an angle between a flow direction of the gas and a moving direction of the energy beam. The angle is predetermined by a scanning strategy.

An additive manufacturing method for making an additive object, which includes the steps of : introducing a mechanical wave to vibrate a holding platform; melting a raw material powder into a melted raw material; and depositing the melted raw material in multiple layers on the holding platform, vibrated by the mechanical wave to form the additive object.

An additive manufacturing method for making an additive object, which includes the steps of : introducing a mechanical wave to vibrate a holding platform; melting a raw material powder into a melted raw material; and depositing the melted raw material in multiple layers on the holding platform, vibrated by the mechanical wave to form the additive object.

A nozzle includes an ejection section and an acceleration section. A powder is configured to be ejected from the ejection section. The acceleration section is configured to allow the powder to circle around and is configured to accelerate the powder in a peripheral direction of the powder that circles around so as to transport the powder to an opening.

A method for fabricating an object using an additive manufacturing process. The method involves a computer-controlled apparatus including a fabrication head for selectively fabricating material and a build area for receiving the fabricated material, and comprises the steps of the apparatus receiving computer instructions relating to the object geometry, and moving the fabrication head and the build area relative to each other, and selectively operating the fabrication head, to fabricate at least one bead of material in the build area corresponding with the object geometry, whereby the at least one bead has non-uniform thickness.

There is provided a method for manufacturing a three-dimensional shaped object by a continuous formation of a plurality of solidified layers through a light beam irradiation, the three-dimensional shaped object being provided with a hollow portion in an interior of the shaped object. The manufacturing method performs the formation of the solidified layer by irradiating a raw material with a light beam at the time of suppling the raw material, thereby allowing a sintering of the raw material or a melting and subsequent solidification of the raw material. In particular, a solidified foundation portion is provided as a part of the three-dimensional shaped object, the solidified foundation portion being used for a platform for a formation of a subsequent layer provided as the solidified layer. An orientation of the solidified foundation portion is changed prior to the formation of the subsequent solidified layer.

An electric melting method for forming metal components provides an electric melting head (6) and a base material (2) being connected to the anode and the cathode of a power supply (12). During the forming of the component, the raw metal wire (1) is sent to the base material (2) and the electric melting head (6) to generate electric arc (9) between the raw wire (1) and the base material (2). The electric arc melts a part of the deposited auxiliary material (3) and creates a molten slag pool (8). Electric current generates the resistance heat and the electroslag heat. The raw wire (1) is molten under the high-energy heat resource composed of the electric arc heat, the resistance heat and the electroslag heat, and thereby creating a molten pool (11) on partial surface of the base material (2).

Methods and systems for fabricating a component by consolidating a particulate include a build platform configured to receive a particulate, a particulate dispenser configured to deposit the particulate on the build platform, and at least one print head including at least one jet. The at least one print head is configured to dispense a binder through the at least one jet onto the particulate to consolidate at least a portion of the particulate and form a component. The methods and systems also include at least one actuator assembly configured to rotate at least one of the at least one print head and the build platform about a rotation axis extending through the build platform and move at least one of the at least one print head and the build platform in a build direction perpendicular to the build platform as part of a helical build process for the component.

A method for forming at least one three-dimensional article through successive fusion of parts of a powder bed on a support structure, the method comprising the steps of: providing at least one model of the three-dimensional article, lowering the support structure a predetermined distance and rotating the support structure a predetermined angle in a first direction before applying a first powder layer covering the lowered and rotated support structure, rotating the support structure the predetermined angle in a second direction opposite to the first direction before directing the at least one first energy beam from the at least one first energy beam source at selected locations of the first powder layer, the at least one first energy beam source causing the first powder layer on the stationary support structure which is stationary to fuse in the selected locations according to the model to form first portions of the three-dimensional article.

A system for the additive manufacturing of components includes a powder receptacle, which is designed to receive a powdered material in the form of a starting material for a component to be manufactured, a construction platform that is mounted within the powder receptacle and is mounted so as to rotate relative to the powder receptacle about a rotational shaft, a lowering drive, which is designed to incrementally or continuously lower the construction platform within the powder receptacle, and an energy input apparatus, which is arranged above an opening in the powder receptacle and is designed to carry out locally selective melting or hardening of a powdered material introduced into the powder receptacle on a surface of the material. The construction platform can be tilted by an angle of inclination relative to a rotational shaft of the rotatable mount.