A welding method for joining a first plate made of a material other than steel and a second plate made of steel includes a step of making a hole through each of the first plate and the second plate, a press-fitting step, an overlapping step, and a filling and welding step. A shaft portion of a joining assist member being solid, being made of steel, and having an outer shape with step having the shaft portion and a flange portion is press-fitted in the hole of the first plate. The first plate and the second plate is overlapped such that the shaft portion faces the hole of the second plate. The hole of the second plate is filled with a weld metal and the second plate and the joining assist member are welded.

In order to provide an improved method for producing metal structures which allows a high level of flexibility in respect of process speed of production, material composition of the metal structure, production accuracy, and the quality of the produced metal structure, according to the invention, a second metal additive is supplied to a welding point on a metal base material, which second metal additive is fused at least by a second electric arc produced between a second electrode and the metal base material in order to produce a second weld seam at the welding point, wherein different materials are used as the first metal additive and as the second metal additive, and wherein the first metal additive and the second metal additive are supplied to the welding point sequentially in time and are fused in the region of the welding point in whichever of the first and second electric arcs is burning, in order to form the three-dimensional metal structure.

Provided are a systems and methods for manufacturing objects by solid freeform fabrication, especially titanium and titanium alloy objects, wherein the deposition rate is increased by using two separate heat sources, one heat source for heating the deposition area on the base material and one heat source for heating and melting a metallic material, such as a metal wire or a powdered metallic material.

Provided are a systems and methods for manufacturing objects by solid freeform fabrication, especially titanium and titanium alloy objects, wherein the deposition rate is increased by using two separate heat sources, one heat source for heating the deposition area on the base material and one heat source for heating and melting a metallic material, such as a metal wire or a powdered metallic material.

A semiconductor fabrication apparatus includes a source chamber being operable to generate charged particles; and a processing chamber integrated with the source chamber and configured to receive the charged particles from the source chamber. The processing chamber includes a wafer stage being operable to secure and move a wafer, and a laser-charged particles interaction module that further includes a laser source to generate a first laser beam; a beam splitter configured to split the first laser beam into a second laser beam and a third laser beam; and a mirror configured to reflect the third laser beam such that the third laser beam is redirected to intersect with the second laser beam to form a laser interference pattern at a path of the charged particles, and wherein the laser interference pattern modulates the charged particles by in a micron-zone mode for processing the wafer using the modulated charged particles.

A semiconductor fabrication apparatus includes a source chamber being operable to generate charged particles; and a processing chamber integrated with the source chamber and configured to receive the charged particles from the source chamber. The processing chamber includes a wafer stage being operable to secure and move a wafer, and a laser-charged particles interaction module that further includes a laser source to generate a first laser beam; a beam splitter configured to split the first laser beam into a second laser beam and a third laser beam; and a mirror configured to reflect the third laser beam such that the third laser beam is redirected to intersect with the second laser beam to form a laser interference pattern at a path of the charged particles, and wherein the laser interference pattern modulates the charged particles by in a micron-zone mode for processing the wafer using the modulated charged particles.

An additive manufacturing system is disclosed including a material feeding device, a first heat source device and a second heat source device. The material feeding device is configured to feed the material onto a substrate for additive manufacturing. The first heat source device is configured to provide a main heat source for melting or sintering the material. The second heat source device is configured to provide an auxiliary heat source for melting or sintering the material. A type of the heat source provided by the first heat source device is different from a type of the heat source provided by the second heat source device. An additive manufacturing method is also disclosed. The additive manufacturing system and the additive manufacturing method according to the present application can improve the rate of the additive manufacturing, reduce the manufacturing cost, improve the stability of the molten pool and improve the manufacturing accuracy and the product quality.

An additive manufacturing system is disclosed including a material feeding device, a first heat source device and a second heat source device. The material feeding device is configured to feed the material onto a substrate for additive manufacturing. The first heat source device is configured to provide a main heat source for melting or sintering the material. The second heat source device is configured to provide an auxiliary heat source for melting or sintering the material. A type of the heat source provided by the first heat source device is different from a type of the heat source provided by the second heat source device. An additive manufacturing method is also disclosed. The additive manufacturing system and the additive manufacturing method according to the present application can improve the rate of the additive manufacturing, reduce the manufacturing cost, improve the stability of the molten pool and improve the manufacturing accuracy and the product quality.

An in-laser wire feeding device having an inductive auxiliary heating function, comprising a wire feeding pipeline and a laser path unit. The wire feeding pipeline comprises upper and lower wire feeding pipes, and a gap zone is formed between the upper and lower wire feeding pipes. The in-laser wire feeding device further comprises a connecting piece which is located on one side of the gap zone and links the upper wire feeding pipe with the lower wire feeding pipe, an inductive heating coil, and a power supply component. The inductive heating coil comprises a coil body and a connecting part. The center line of the coil body, the center line of the upper wire feeding pipe and the center line of the lower wire feeding pipe are collinear, and the inner wall of the coil body can avoid laser beams reflected downwards by a reflecting mirror.

An additive manufacturing apparatus forms layers with a material that is molten to produce a formed object. The additive manufacturing apparatus includes a CMT power supply that supplies as a power supply current to heat a wire that is the material fed to a workpiece, to the material; a laser oscillator that produces as a beam source a laser beam that is a beam with which the workpiece is irradiated; and a head drive unit that shifts as a drive unit a feed position for the material on the workpiece and an irradiation position for the beam on the workpiece. The additive manufacturing apparatus shifts the feed position and the irradiation position, with the irradiation position leading in a moving path for the feed position in spaced relation to the feed position.