Systems and apparatus are disclosed relating to improved fluid supply systems. In some examples, the improved fluid supply systems use an electrically controllable proportional valve and a surge prevention process to prevent a surge of pressurized fluid at the end of a welding-type operation. In particular, the surge prevention process may coordinate closure of the proportional valve and an on/off solenoid valve so that pressure in the fluid flow path can equalize to an ambient pressure after a welding operation (and/or a post flow operation) has ended. This coordination ensures that there is no pressure buildup and/or associated surge of fluid when the on/off solenoid valve is next opened (e.g., at the start of the next welding operation).

A shielding gas ejecting device includes a nozzle body extending along an axis, an inner shielding gas ejection path provided inside the nozzle body and opened on the axis, an outer shielding gas ejection path surrounding the inner shielding gas ejection path from a periphery, and an intermediate shielding gas ejection path provided between the inner shielding gas ejection path and the outer shielding gas ejection path. A flow velocity of an intermediate shielding gas ejected from the intermediate shielding gas ejection path is lower than a flow velocity of an inner shielding gas ejected from the inner shielding gas ejection path and a flow velocity of an outer shielding gas ejected from the outer shielding gas ejection path.

A welding or metal additive manufacturing torch includes a nozzle and a shielding gas diffuser located within the nozzle. The shielding gas diffuser has a plurality of shielding gas discharge holes spaced annularly around the shielding gas diffuser. A contact tip extends from the shielding gas diffuser distal of the shielding gas discharge holes. An annular screen extends radially between the nozzle and one or both of the contact tip and the shielding gas diffuser and is located distal of the shielding gas discharge holes. The annular screen is electrically insulated from at least one of the shielding gas diffuser and the nozzle.

Methods and apparatus are disclosed relating to mixing fluids in welding-type equipment. In some examples, a welding-type power supply (and/or wire feeder) may include multiple fluid paths through which to provide fluid from multiple fluid reservoirs to multiple welding-type tools. The power supply may be configured to automatically control fluid flow rates through the fluid paths via proportional valves. Further, the welding-type power supply may be configured to allow and/or prohibit mixing of fluids from different flow paths via control of various valves.

The present invention relates to a trailing gas nozzle (1) for a welding torch, comprising an elongated body (10) comprising an internal space (11) for receiving a trailing gas (G), and an elongated discharge area (12) on a bottom side of the body (10) for discharging the trailing gas (G) onto a weld seam (S). The body (10) comprises a plurality of segments (101, 102, 103) connected to one another contact surfaces so that a curvature of the discharge area (12) is adjustable to a desired curvature.

A welding device for welding a stud to a substrate along a welding axis in a welding direction, comprising an inert gas cover with an inert gas inlet arranged as a ring around the axis, with an inert gas outlet, and an opening facing the welding direction, the opening having transversely to the welding direction an opening diameter, wherein the inert gas inlet is at an inlet distance from the opening counter to the welding direction, wherein the inert gas outlet is at an outlet distance from the opening counter to the welding direction, and a holding device holding the stud within the cover during welding, the holding device having an outside diameter and a stud receptacle with an inside diameter, wherein the outlet distance is at least half of a difference between the opening diameter and the outside diameter or at least the same size as the inlet distance.

Through the present invention, the load of a torch (16) applied to a welding workpiece (W) in a touch start method is reduced, and stability is significantly enhanced. A welding head (10) has a rigid straight-advancing movable part (12), an elevator drive tower (14) for moving the straight-advancing movable part (12) straight forward in the vertical direction, and a torch (16) mounted on the straight-advancing movable part (12) so as to be able to move in the vertical direction. One end part of a balance arm (28) rotatably attached to a multi-purpose support part (22) of the straight-advancing movable part (12) is connected to a torch body (30), and a balance weight (98) is attached to the other end part of the balance arm (28).

The present invention relates to a device and a method for DED or WAAM, comprising a welding torch configured to generate an arc for generating a melt pool on a surface of a workpiece, and a wire feeder configured to feed a wire towards the melt pool to generate a weld seam on said surface, and an enclosure enclosing at least part of the workpiece and comprising a process atmosphere with a process gas, wherein a sucking device sucks part of the process gas out of the enclosure and thereafter re-introduces the process gas into the process atmosphere, and wherein the enclosure comprises or consists of a flexible housing or a tent and in the sucking device is connected to a buffer volume or a pressure stabilizing unit.

Processing apparatus and method for processing a workpiece surface, in particular for the internal coating of cylinder bores. Processing apparatus has a shield unit which is provided to separate from one another-at least during operation-a part region of the workpiece surface provided for the processing and an adjacently arranged part region of the workpiece surface. The shield unit has at least one blocking nozzle which is provided to generate a fluid flow for separating the at least two part regions.

Device and method for welding a workpiece (2) having a welding torch (3) which can be mechanically coupled by a coupling element (4) to a hose bundle (5) for supplying the welding torch (3) at least with compressed air or with a protective gas, wherein compressed air applied to the coupling element (4) can be diverted by a diverting valve (10) provided in the coupling element (4) for actuating an actuator (7).