An example fume extractor for a robotic welding torch includes: a neck clamp configured to attach to a neck of a robotic welding torch; an intermediate mount rigidly attached to the neck clamp; a fume duct coupled to the intermediate mount and extending over the neck of the robotic welding torch toward a nozzle of the robotic welding torch; and a fume manifold rotationally coupled to the intermediate mount and coupled to a fume hose, wherein the fume manifold, the intermediate mount, and the fume duct are configured to communicate a negative pressure from the fume hose to an end of the fume duct closest to the nozzle of the robotic welding torch.

An example fume extractor for a robotic welding torch includes: a neck clamp configured to attach to a neck of a robotic welding torch; an intermediate mount rigidly attached to the neck clamp; a fume duct coupled to the intermediate mount and extending over the neck of the robotic welding torch toward a nozzle of the robotic welding torch; and a fume manifold rotationally coupled to the intermediate mount and coupled to a fume hose, wherein the fume manifold, the intermediate mount, and the fume duct are configured to communicate a negative pressure from the fume hose to an end of the fume duct closest to the nozzle of the robotic welding torch.

The object of the present invention is to provide a welding apparatus and a plasma welding method capable of obtaining deep penetration while suppressing initial investment in a welding apparatus. The welding apparatus of the present invention includes a torch for plasma welding and a power supply device, wherein the power supply device is composed of a first welding power supply used for a TIG welding apparatus, in which a positive terminal is electrically connected with the insert chip and a negative terminal is electrically connected with the electrode, and a second welding power supply used for a TIG welding apparatus, in which a positive terminal is electrically connected with a material to be welded and a negative terminal is electrically connected with the electrode.

A welding system includes a welding torch. The welding torch includes a sensor configured to detect a motion associated with the welding torch, a temperature associated with the welding torch, or some combination thereof. A display of the welding torch is activated, a determination is made that the welding torch has been involved in a high impact event, live welding using the welding torch is disabled, a software selection is made, or some combination thereof, based on the motion, the temperature, or some combination thereof.

A housing for a laser processing machine is described to treat work pieces. The housing comprises a dividing wall, which separates a first work space having a first length and a second work space having a second length from one another, a first entrance to allow access to the first work space, a second entrance to allow access to the second work space, a closing device, which is configured to selectively open and close the first entrance and the second entrance and a control unit, which is operatively connected to the closing device. The dividing wall is placeable in an operating position, which is variable among at least a first position, a second position and a third position. The control unit is configured to control the closing device as a function of the operating position of the dividing wall.

A housing for a laser processing machine is described comprising a dividing wall, which separates a first work space and a second work space, and a covering device, which is configured to selectively cover at least one between the first work space and the second work space. The covering device comprises at least a cover, which is controllable in an active configuration, in which the cover is configured to cover one between the first work space and the second work space and a guide system, which is configured to guide the cover so that the cover, when it is in the active configuration, comprises at least a main portion and an auxiliary portion extending from the main portion and being inclined relative to the main portion.

A welding process involves a fixture for holding a workpiece and a welder, or welding electrode. The fixture imposes ultrasonic vibration on the workpiece. The welder vibrates during vibration, and is operable at a first voltage for welding and a second voltage for peening. The peening may occur while the weldmetal is crystallizing. The welding process may be a process of welding two part as together, or of filling a groove or other feature, or of applying or restoring a surface, or of applying a hard facing or ceramic to a parent metal or object. The weldmetal may be the same, or substantially the same, as the parent metal, or it may be different. The different material may be a ceramic material.

A welding process involves a fixture for holding a workpiece and a welder, or welding electrode. The fixture imposes ultrasonic vibration on the workpiece. The welder vibrates during vibration, and is operable at a first voltage for welding and a second voltage for peening. The peening may occur while the weldmetal is crystallizing. The welding process may be a process of welding two part as together, or of filling a groove or other feature, or of applying or restoring a surface, or of applying a hard facing or ceramic to a parent metal or object. The weldmetal may be the same, or substantially the same, as the parent metal, or it may be different. The different material may be a ceramic material.

A method for producing a pin for a feedthrough for an electromedical implant. A pin is produced using the following method steps: creating a foil-, sheet- or strip-shaped semi-finished product by joining at least one first layer element including an electrically conducting, preferably biocompatible, material in foil, sheet or strip form and at least one second layer element including a solder and/or an easily soft-solderable material, preferably in wire, sheet or strip form, or by applying the at least one second layer element onto the at least one first layer element; and at least partially detaching a pin, or a set of multiple pins connected to a connecting web 46, from the semi-finished product. A method is also provided for producing a feedthrough and an electromedical implant and to a pin, a feedthrough or an implant produced in the corresponding manner.

An internal heat exchanger (IHEX) for pipeline welding includes a drive system configured to move the IHEX into a position within at least one pipe section near a weld joint location with another pipe section. The IHEX further includes a cooling section including cooling structure configured to selectively cool one or more interior surface portions of the at least one pipe section, and a controller in communication with the cooling structure and configured to activate the cooling section when the IHEX is at the position within the at least one pipe section.