A metal additive manufacturing technique is provided to improve various characteristics by irradiation of a pulse laser without disposing a transparent medium. A metal additive manufacturing device includes: a material supply source configured to supply a material to be deposited; a heat source configured to melt the material by outputting an energy beam; a moving driver configured to scan at least the energy beam; and a laser irradiator configured to irradiate a solidified portion of the material in a temperature lowering process with a pulse laser.

A metal laminating and modeling method includes a first inclination angle modeling step including a first inclination step of setting a table on which the metal layers are to be formed at a first table inclination angle and setting a welding torch at a first torch inclination angle and a first welding step of forming a weld bead that becomes a part of the modeled object by arc welding with the welding torch and a second inclination angle modeling step including a second inclination step of inclining the table at a second table inclination angle that is larger than the first table inclination angle and setting the welding torch at a second torch inclination angle and a second welding step of forming the weld bead.

The invention relates to a welding process for producing a component (10) by depositing multiple layers (100) of a metal material in layers, said layers lying one on top of the other. In said process, the base (10a) of the component (10) is placed in a liquid coolant (6) such that the coolant contacts the base (6), and a surface (10b) of the base (6) lies above the coolant level (3). A first layer (100) of the material is deposited onto the surface (10b) by welding the material to the surface (10b), and each subsequent layer (100) is deposited onto a temporary component surface (10bb) formed by the previously deposited layer (100) by welding the material to the temporary component surface (10bb), wherein the heat resulting from welding the material is absorbed by the coolant (6). The invention additionally relates to a device (1) for carrying out the method.

A system and method to correct for height error during a robotic additive manufacturing process. One or both of an output current, output voltage, output power, output circuit impedance and a wire feed speed are sampled during an additive manufacturing process when creating a current layer. A plurality of instantaneous contact tip-to-work distances (CTWD's) are determined based on at least one or both of the output current, output voltage, output power, output circuit impedance and the wire feed speed. An average CTWD is determined based on the plurality of instantaneous CTWD's. A correction factor is generated, based on at least the average CTWD, which is used to compensate for any error in height of the current layer.

Strip cladding heads having strip pressure limits and strip cladding systems with strip cladding heads having strip pressure limits are disclosed are disclosed. A disclosed example cladding head for a strip cladding system includes a first contact jaw comprising first and second contacts to deliver welding power to a cladding strip that is driven between the first and second contacts, a first contact pressure adjuster to set a first pressure applied by the first and second contacts to the cladding strip, and a first strip lock preventer to limit the first pressure applied by the first and second contacts to the cladding strip to less than a threshold pressure.

Provided is a metal laminating and modeling method including sequentially carrying out a step of laminating metal layer to form a modeled article, in which the step of laminating a metal layers includes a step of forming blocking beads that are continuous along the outer peripheral shape of the modeled article by arc welding on at least one end portion in the width direction of a target surface, on which the metal layers are to be formed, and a step of forming inner beads by arc welding with a current higher than the current in the step of forming blocking beads so as to fill a space on the inside of the blocking beads in the width direction of the target surface.

A welding or additive manufacturing system includes a contact tip assembly having first and second exit orifices. A wire feeder is configured to deliver a first and second wire electrodes through the exit orifices. An arc generation power supply is configured to output a current waveform to the wire electrodes simultaneously, through the contact tip assembly. The current waveform includes a bridging current portion, and a background current portion having a lower current level than the bridging current portion. The bridging current portion has a current level sufficient to form a bridge droplet between the wire electrodes before the bridge droplet is transferred to a molten puddle during a deposition operation. Solid portions of the wire electrodes do not contact each other during the deposition operation. The bridge droplet is transferred to the molten puddle during a short circuit event between the molten puddle and the wire electrodes.

A metal laminating and molding method molds a 3-dimensional molded object formed by sequentially laminating a plurality of metal layers. The metal laminating and molding method is accomplished by repeatedly performing a unit process including a metal layer laminating process of laminating the metal layer constituted by welding beads formed through arc welding and a removal process of removing impurities from a surface of the metal layer laminated in the metal layer laminating process. When the unit process is repeated, the metal layer laminating process is performed again such that a new metal layer is laminated on the surface of the metal layer from which impurities have been removed in the removal process.

A method for manufacturing a T-shaped structure includes depositing one or more layers of weld beads over a portion of a surface of a first component such that the one or more layers of weld beads develop a metallurgical bond with the portion. Also, the method includes placing an end of a second component over the one or more layers of weld beads such that the end develops a metallurgical bond with the one or more layers of weld beads. The one or more layers of weld beads define a fully penetrated weld joint between the end and the portion to form the T-shaped structure.

The present invention relates to noble metal-containing components prepared by cold metal transfer (CMT) methods, along with methods of preparing such components by CMT. More especially, an advantageous method of preparing a platinum metal group metal or alloy containing ignition device component by CMT is provided.