A connection element for securing to a component, in particular a component made of a fiber composite material, comprising a main part, a functional part and a friction welding inlay, which in turn comprises a thermoplastic material. A tool application point is formed on an upper side of the main part. The friction welding inlay may be interlocking.

A jacket main body is formed of a first aluminum alloy. A seal body is formed of a second aluminum alloy. The first aluminum alloy is higher in hardness than the second aluminum alloy in material type. A method includes: a preparing step of forming on an peripheral wall part a step part having a step bottom surface and a step side surface obliquely rising; a mounting step of mounting the seal body on the jacket main body to form a first butt portion and putting the step bottom surface and a back surface of the seal body on each other to form a second butt portion; a main joining step of performing friction stir welding while only the stirring pin of the rotary tool rotating contacts with only the seal body.

The disclosed wall includes several narrow aluminum sheets and posts that are Friction Stir Welded (FSW) into a sidewall. The length of the wall is the summation of the narrow sheets' width, and the walls width is the narrow sheets' length. Several aluminum posts are spaced along the wall's length direction in order to improve the stiffness and strength of the wall. When welding the aluminum sheets and posts together, the sheets are placed under the posts and jointed tightly together through FSW. With the high-speed spinning of the stirring pin, the post and sheet melt and form into a compact solid phase weld seam under the extrusion of the welding head. When welding two aluminum sheets and one post together, the two sheets are placed edge-to-edge or slightly overlapped. The post is then placed over the sheet joint and the stir-welding head melts portions of the post and the two sheets simultaneously.

The disclosed wall includes several narrow aluminum sheets and posts that are Friction Stir Welded (FSW) into a sidewall. The length of the wall is the summation of the narrow sheets' width, and the walls width is the narrow sheets' length. Several aluminum posts are spaced along the wall's length direction in order to improve the stiffness and strength of the wall. When welding the aluminum sheets and posts together, the sheets are placed under the posts and jointed tightly together through FSW. With the high-speed spinning of the stirring pin, the post and sheet melt and form into a compact solid phase weld seam under the extrusion of the welding head. When welding two aluminum sheets and one post together, the two sheets are placed edge-to-edge or slightly overlapped. The post is then placed over the sheet joint and the stir-welding head melts portions of the post and the two sheets simultaneously.

According to an embodiment, there are provided a method for manufacturing a battery module for an electric vehicle and a battery module manufactured by the method. The method comprises preparing an electrode assembly, the electrode assembly including a plurality of electrode plates, a plurality of electrode tabs, and a separator, forming a plurality of electrode leads by friction-welding a copper piece and an aluminum piece, attaching a sealing film to each of the plurality of electrode leads, packing the electrode assembly in a pouch case, with the aluminum piece exposed to an outside of the pouch case, injecting an electrolyte into the pouch case, sealing the pouch case to form each of the plurality of battery cells, stacking the plurality of battery cells one over another, and connecting the aluminum pieces of the plurality of battery cells to each other via a sensing bus bar.

An apparatus and method of alloying a weld in an induction-kinetic welding of metal parts together includes heating substantially planar portions of two metal parts with an induction heating coil in between the planar portions. During at least a portion of the step of heating the planar portions, flowing a gas containing an alloying element in proximity to the planar portions. A chemical reaction results in an alloying element alloying the planar portions. The induction heating coil is withdrawn from in between the planar portions and the parts are forced into contact with each other in a kinetic energy welding process resulting in the metal parts being welded together. The welded parts have improved strength in the area of the weld. The welding process can be used to increase the presence of alloying transition metals and to improve the flowability and weldability during the kinetic phase before dilution of enriched carbon by shear accelerated diffusion.

An apparatus and method of alloying a weld in an induction-kinetic welding of metal parts together includes heating substantially planar portions of two metal parts with an induction heating coil in between the planar portions. During at least a portion of the step of heating the planar portions, flowing a gas containing an alloying element in proximity to the planar portions. A chemical reaction results in an alloying element alloying the planar portions. The induction heating coil is withdrawn from in between the planar portions and the parts are forced into contact with each other in a kinetic energy welding process resulting in the metal parts being welded together. The welded parts have improved strength in the area of the weld. The welding process can be used to increase the presence of alloying transition metals and to improve the flowability and weldability during the kinetic phase before dilution of enriched carbon by shear accelerated diffusion.

A bonding device for joining together a first member (3), an intermediate member (4), and a second member (3) which are layered as a laminated assembly includes a probe (12, 41, 52), an anvil (111, 121), an electric conductor configured to come into contact with the second surface of the laminated assembly, the electric conductor being either the probe or a shoulder member (13, 13a, 61, 64, 68) provided with a through hole for receiving the probe, and a shoulder contact surface configured to abut against the second surface, a drive mechanism (14) configured to rotate the probe around the central axial line and move the probe toward and away from the second member along the central axial line, and an electric power supply (15) electrically connected to the anvil and the probe to conduct electric power through the laminated assembly via the anvil and the probe.

A bonding device for joining together a first member (3), an intermediate member (4), and a second member (3) which are layered as a laminated assembly includes a probe (12, 41), an anvil (11, 11b, 11c, 11d), a shoulder member (13,13a, 61,64,68), a drive mechanism (14) configured to rotate the probe around the central axial line and move the probe toward and away from the second member along the central axial line, and an electric power supply (15) electrically connected to the anvil and the shoulder member to conduct electric current through the laminated assembly via the anvil and the shoulder member.

A bonding device for joining together a first member (3), an intermediate member (4), and a second member (3) which are layered as a laminated assembly includes a probe (12, 41, 52), an anvil (11), a drive mechanism (14) configured to rotate the probe around the central axial line and move the probe toward and away from the second member along the central axial line, and an electric power supply (15) electrically connected to the anvil and the probe to conduct electric current through the laminated assembly via the anvil and the probe.