Provided is a method of molding a composite material by laser metal deposition in which a powder metal material is irradiated with a laser beam while supplying the powder metal material onto a surface of a base material, in which the powder metal material is a mixed powder of an Fe alloy powder and a Cu powder, and a mixing ratio of the Fe alloy powder and the Cu powder is 15% or more and 30% or less by weight % of the Cu powder, and in which the composite material having anisotropy is molded by setting energy of the laser beam to be 9 KJ/g or more and 10 KJ/g or less in a mixed powder ratio.

Provided is a method of molding a composite material by laser metal deposition in which a powder metal material is irradiated with a laser beam while supplying the powder metal material onto a surface of a base material, in which the powder metal material is a mixed powder of an Fe alloy powder and a Cu powder, and a mixing ratio of the Fe alloy powder and the Cu powder is 15% or more and 30% or less by weight % of the Cu powder, and in which the composite material having anisotropy is molded by setting energy of the laser beam to be 9 KJ/g or more and 10 KJ/g or less in a mixed powder ratio.

A chamber component for a processing chamber is disclosed herein. In one embodiment, a chamber component for a processing chamber includes a component part body having unitary monolithic construction. The component part body has a textured surface. The textured surface includes a plurality of independent engineered macro features integrally formed with the component part body. The engineered macro features include a macro feature body extending from the textured surface.

A chamber component for a processing chamber is disclosed herein. In one embodiment, a chamber component for a processing chamber includes a component part body having unitary monolithic construction. The component part body has a textured surface. The textured surface includes a plurality of independent engineered macro features integrally formed with the component part body. The engineered macro features include a macro feature body extending from the textured surface.

The present invention belongs to the technical field related to additive manufacturing, and provides a multi-field composite-based additive manufacturing device and method. The device comprises a powder delivery adjustment module, a sound field control module, a microwave field/thermal field control module and a microprocessor. The powder delivery adjustment module, the sound field control module and the microwave field/thermal field control module are respectively connected to the microprocessor; the powder delivery adjustment module comprises a raw material dispersion chamber, and the raw material dispersion chamber is provided within a forming cavity formed by a housing; the sound field control module is also provided within the forming cavity and is located below the raw material dispersion chamber; the microwave field/thermal field control module comprises a plurality of microwave generators provided in the forming cavity, the plurality of microwave generators are respectively located at two sides of a forming area.

The present invention belongs to the technical field related to additive manufacturing, and provides a multi-field composite-based additive manufacturing device and method. The device comprises a powder delivery adjustment module, a sound field control module, a microwave field/thermal field control module and a microprocessor. The powder delivery adjustment module, the sound field control module and the microwave field/thermal field control module are respectively connected to the microprocessor; the powder delivery adjustment module comprises a raw material dispersion chamber, and the raw material dispersion chamber is provided within a forming cavity formed by a housing; the sound field control module is also provided within the forming cavity and is located below the raw material dispersion chamber; the microwave field/thermal field control module comprises a plurality of microwave generators provided in the forming cavity, the plurality of microwave generators are respectively located at two sides of a forming area.

An immersion-type heat dissipation structure and a method for manufacturing the same are provided. The immersion-type heat dissipation structure includes a first heat dissipation member and a second heat dissipation member that has a plurality of heat dissipation columns and is disposed on the first heat dissipation member. The second heat dissipation member has a porous structure, the first heat dissipation member has a solid structure, and a thermal conductivity of the first heat dissipation member is greater than that of the second heat dissipation member. A shortest distance between two bottoms of any two adjacent ones of the heat dissipation columns is between 0.2 mm and 1.2 mm, a minimum diameter of a top surface of the heat dissipation column is between 0.2 mm and 1.2 mm, and a draft angle formed on a side surface of the heat dissipation column is between 1° and 5°.

An immersion-type heat dissipation structure and a method for manufacturing the same are provided. The immersion-type heat dissipation structure includes a first heat dissipation member and a second heat dissipation member that has a plurality of heat dissipation columns and is disposed on the first heat dissipation member. The second heat dissipation member has a porous structure, the first heat dissipation member has a solid structure, and a thermal conductivity of the first heat dissipation member is greater than that of the second heat dissipation member. A shortest distance between two bottoms of any two adjacent ones of the heat dissipation columns is between 0.2 mm and 1.2 mm, a minimum diameter of a top surface of the heat dissipation column is between 0.2 mm and 1.2 mm, and a draft angle formed on a side surface of the heat dissipation column is between 1° and 5°.

Disclosed is a three-dimensional printing method for instantly generating a needed molten raw material by way of a resistance heating function during three-dimensional printing. The method can realize three-dimensional printing of material having a high melting point and falls within the technical field of additive manufacturing. The method is characterized by applying a current through a solid raw material and a body to be printed; partially or fully heating the solid raw material located between a guiding device and said body to be printed into a molten state by way of resistance heating; and generating a molten raw material in a space located between the guiding device and the body to be printed. During the accumulation of the molten raw material, an area of the body to be printed and where the molten raw material is to be accumulated and/or is being accumulated is heated; or, the body to be printed is heated; or, the area of the body to be printed and where the molten raw material is to be accumulated and/or is being accumulated is heated, and the body to be printed is heated.

Articles prepared by additive manufacturing of preforms that are coated by electrodeposition of nanolaminate materials, and methods of their production are described.