The invention relates to a device for welding rod-shaped conductors (14), comprising a compression chamber for receiving joining sections (13) of the conductors to be joined together, the compression chamber being limited in a first axial direction (z-axis) on two opposite sides by an active surface of a sonotrode (16) transmitting ultrasonic vibrations in the direction of the z-axis and by a counter surface of a counter electrode (18), the device having a knife device which is provided with a drive device and comprises a knife (24) movable in the direction of the z-axis, said knife having a cutting edge which can be moved past the compression chamber, wherein a drive motor of the drive device is arranged in an installation space arranged below the sonotrode, the drive motor being connected to a knife holder (26) via a deflection gear (31) in order for the knife to be able to perform a cutting motion, the knife being moveable in the direction of the z-axis.

The invention relates to an ultrasonic welding device for introducing an embossed surface into a metal foil stack for a cell of a lithium-ion battery, comprising a sonotrode and an anvil, wherein the anvil or the sonotrode has a number of first protrusions projecting from the working surface thereof, in order to form the, in particular strip-like, embossed surface by compacting the metal foil stack. The invention additionally relates to a method for producing a metal foil stack of metal foils for a cell of a lithium-ion battery, in particular using such an ultrasonic welding device.

The invention relates to an ultrasonic welding device for introducing an embossed surface into a metal foil stack for a cell of a lithium-ion battery, comprising a sonotrode and an anvil, wherein the anvil or the sonotrode has a number of first protrusions projecting from the working surface thereof, in order to form the, in particular strip-like, embossed surface by compacting the metal foil stack. The invention additionally relates to a method for producing a metal foil stack of metal foils for a cell of a lithium-ion battery, in particular using such an ultrasonic welding device.

A method is for reducing surface roughness of an additive manufactured metallic component. The method includes placing the component in a chamber, filling the chamber with a combustible gas mixture, allowing the gas mixture to surround the component and igniting the gas mixture so as to expose the surface of the additive manufactured metallic component to at least one thermal pulse.

A method is for reducing surface roughness of an additive manufactured metallic component. The method includes placing the component in a chamber, filling the chamber with a combustible gas mixture, allowing the gas mixture to surround the component and igniting the gas mixture so as to expose the surface of the additive manufactured metallic component to at least one thermal pulse.

A method for producing the metal cylinder material according to the present disclosure includes: a process A of forming a slitted cylinder-shaped body including at least one slit extending from one end face to the other end face of a cylinder barrel portion consisting of at least one metal plate material; a process B of forming a filler-equipped cylinder-shaped body including a filling portion obtained by filling the slit with a filler for the filler to be filled throughout the slit in a length direction of the slit; and a process C of, by inserting at least a probe of a friction stir rotation tool including the probe at least into the filling portion and executing FSP, reforming at least the filling portion of the filler-equipped cylinder-shaped body to obtain the metal cylinder material including an FSP portion.

A method is provided for joining at least two components of a medical instrument, the at least two components are held so as to form at least one soldering gap between mutually assigned joining areas of the components, a solder material is arranged for filling the at least one soldering gap, and the arrangement of the at least two components and of the solder material is heated to a soldering temperature of the solder material, wherein the solder material is an iron-based solder. A use of an iron-based solder and a medical instrument, in particular a laryngoscope spatula, are also provided.

A method is provided for joining at least two components of a medical instrument, the at least two components are held so as to form at least one soldering gap between mutually assigned joining areas of the components, a solder material is arranged for filling the at least one soldering gap, and the arrangement of the at least two components and of the solder material is heated to a soldering temperature of the solder material, wherein the solder material is an iron-based solder. A use of an iron-based solder and a medical instrument, in particular a laryngoscope spatula, are also provided.

A method of repairing an oxidized defect in a superalloy article includes removing substantially all of the oxidized defect to form a cleaned out portion of the superalloy article; filling a portion of the cleaned out portion with a weld by fusion welding; cracking the weld; and filling the cracked weld and a remaining portion of the cleaned out portion with a braze material.

The present disclosure provides a wire and arc additive manufacturing (WAAM) method for a magnesium alloy. The method includes the following steps: step 1: performing a WAAM process assisted by cooling and rolling; step 2: milling side and top surfaces of an additive part; step 3: performing, by friction stir processing (FSP) equipment, an FSP process on the additive part, and applying cooling and rolling to a side wall of the additive part through a cooling and rolling device during the FSP process; step 4: finish-milling the top surface of the additive part for a WAAM process in the next step; and step 5: repeating the above steps cyclically until final forming of the part is finished. The present disclosure completely breaks dendritic structures and refines grains in the WAAM process of the magnesium alloy, thereby effectively repairing defects such as pores and cracks.