The invention relates to an ultrasonic metal welding device and a method for welding electrical conductors using a compression chamber that is adjustable at least in height and that is delimited on opposite sides by a section of a sonotrode as a first delimiting surface and by at least one section of a counter electrode (156) as a second delimiting surface, wherein for welding, the counter electrode and the sonotrode are displaced relative to one another. The counter electrode used is one that comprises sections (152, 154) of geometrically different working surfaces or is composed of at least two sections that are displaceable relative to one another.

The invention relates to a method and to an arrangement for electrically conductive connecting, by means of ultrasonic welding, of first electric conductors (140, 142) and second electric conductors (144, 146) in a compression space the cross section of which can be changed and which comprises at least one lateral slide, a sonotrode and a counter electrode, wherein firstly, blank ends of the first electric conductors (140, 142) are introduced into the compression space and are welded by means of ultrasonic action to form a first connection (148) and then after the first connection has been removed from the compression space, blank ends of the second electric conductors (144, 146) are introduced into same and are welded by means of ultrasonic action to form a second connection, wherein the first connection is fed to a retaining device (182, 184) before the second connection is welded.

A harness is provided with one or more first wires each including a first core exposed portion, one or more second wires each including a second core exposed portion, and a bonded portion formed by welding the first and second core exposed portion(s). A total cross-sectional area of the second core(s) is equal to or less than ⅓ of the sum of total cross-sectional areas of the first and second core(s). The bonded portion has two pairs of outer surfaces extending along an extending direction of the first and second wires and facing each other and a distance H between one pair of the outer surfaces (upper/lower surfaces), out of the two pairs of outer surfaces, is longer than a distance W between another pair of the outer surfaces (right/left side surfaces). The second core exposed portion(s) is/are arranged adjacent to the upper surface Up in the bonded portion.

A cable connection structure includes an electric cable, an end face of a core wire of which is exposed, a first electrode that covers the end face, a substrate, a terminal of which is exposed on a principal surface, and a second electrode bonded to the first electrode without another member interposed between the first electrode and the second electrode, the second electrode covering the terminal and having substantially same Vickers hardness as Vickers hardness of the first electrode.

A terminal includes: a tubular box portion to receive a mating terminal; a spring portion extending in a beam shape from a front end portion of the box portion; and a pressing piece configured to restrict a bending range of the spring portion. A free end of the spring portion is inside the box portion, and the spring portion has a contact point with the mating terminal. The pressing piece is placed at a pressing position located inside the box portion and away from the contact point in the bending direction. The pressing piece is configured to restrict the bending range of the spring portion to achieve at least part of the spring portion closer to the free end than the contact point is located on the bending direction side with respect to the pressing position.

A bus bar and a method of manufacturing the same may include a first metal portion made of a first metal material; and a second metal portion made of a second metal material different than the first metal portion. The first metal portion and the second metal portion are coupled by a rotation friction welding (RFW).

A transition block fixing assembly has a transition block mounting unit that includes a support member and a connecting member. The support member is configured to support a transition block and a pair of cables that are received within the transition block, and the connecting member is configured to mount the transition block mounting unit within a base station antenna.

A method for joining a first cable to a second cable that each include at least one electrically conductive inner conductor, an outer sheath which at least partially surrounds the at least one inner conductor, and an insulation material which is arranged at least partially between the at least one inner conductor and the outer sheath. The method includes: bringing an end of each cable together such that at least one inner conductor of the cables are opposite one another and a fusible conductor joining material having a lower melting point than the at least one inner conductor is present in between; and heating at least one of the cables from the outside such that the heat penetrates into an interior of the at least one heated cable so the fusible conductor joining material melts and electrically connects the at least one inner conductor of the cables to one another.

In a joining method of an electric wire, an end of a first conductor is held by a holding surface of a first jig electrode from an outer circumference side and an end of a second conductor is held by a holding surface of a second jig electrode from an outer circumference side to butt and join the ends of the first conductor and the second conductor in the axial direction while heating the ends. Then, a melted material is bulged outward from an outer circumferential surface of a joining portion to a bulge molding portion formed to surround a joining portion of the ends of the first conductor and the second conductor.

Provided are a rotary-electric-machine stator coil, a rotary-electric-machine stator having the same, and a rotary electric machine having the same, capable of improving a bonding strength and insulation reliability of a conductor bonding portion. A rotary-electric-machine stator coil includes: a conductor 110 having a bonding portion 104 bonded to other conductors; and a bonding member 401 having a melting point lower than a melting point of the conductor, wherein a tip of the bonding portion has an alloy layer 402 formed of an alloy of the conductor and the bonding member, and a root of the bonding portion is electrically connected by the bonding member.