A connection method of an RF cable end connector and a coaxial cable and an internal terminal used thereof are provided. An insulator is formed outside a body of the internal terminal by embedded molding, making the internal terminal have a composite structure integrated with the insulator. The internal terminal can be connected to the coaxial cable by, for example, clamping. This allows connection between the RF cable end connector and the coaxial cable to be easily accomplished by automatic processes, thereby reducing fabrication costs of RF cable end connector jumpers.

An electric energy transmission joint and a preparation method therefor. The electric energy transmission joint includes an electric energy transmission copper part, an electric energy transmission aluminum part (9), and an aluminum wire (3). The electric energy transmission copper part includes a fixer (1) for connection with an electric consumption device, and a connector (2) for connection with the electric energy transmission aluminum part (9). A first through hole is provided inside the electric energy transmission aluminum part (9), and a second through hole is provided inside the connector (2). An aluminum conductive core (4) exposed by stripping an insulation layer (5) from a front end of the aluminum wire (3) is inserted into a cavity formed by the connection of the first through hole and the second through hole. The electric energy transmission aluminum part (9) is connected to the aluminum wire (3) by crimping. The electric energy transmission copper part has the advantages of light weight, fast production, and reduced production cost.

Prior to insertion into the recess of a crimping region, the axial ends of the plurality of electrical strands of the cable are fixed with a clamping tool so that the axial ends of the plurality of electrical strands protrude axially out of the clamping tool and the ends of the plurality of strands protruding axially from the clamping tool are sheared off in the transverse direction with a cutting tool so that a closed end face is produced at the axial end of the strands. The axial end of the plurality of electrical strands is inserted into the recess and the plurality of strands are welded to the contact piece by melting the closed end face arranged in the recess by radiation energy of a radiation directed onto the end face.

An electronic device includes a fork structure having a pair of arms disposed in spaced relation and defining an open-ended channel therebetween. A surface of channel defines a seat opposite the open end. The channel has a width W.sub.1 at its narrowest section. A rigid wire of an electrical component is disposed in the channel generally adjacent to the seat. The wire has a width W.sub.2 that is greater than the width W.sub.1 so surfaces of the channel at the narrowest section defined by width W.sub.1 interfere with the wire, preventing the wire from moving towards the open end of the channel. The pair of arms are constructed and arranged to be moved toward each other so as to crimp the wire to the fork structure.

A tool for soldering an electrical conductor with a connection device includes a deformation unit plastically deforming the connection device around the electrical conductor. The deformation unit has a fixed deformation module and a movable deformation module that is movable with respect to the fixed deformation module. The fixed deformation module has an anvil with an electrical contact area on which the electrical conductor and the connection device are disposed. An electric current circulates through the electrical conductor and the connection device by passing through an electrically conductive first part of the anvil that is electrically insulated from a rest of the anvil.

A method of manufacturing a terminal-equipped electrical wire includes: inserting a core-wire exposed part of a core wire of an electrical wire at a terminal between inner wall surfaces of a pair of piece parts of a terminal fitting including a core-wire connection body formed of a bottom part and the piece parts protruding from both ends of the bottom part, and placing the core-wire exposed part on an inner wall surface of the bottom part; melting the core-wire exposed part and the core-wire connection body by emitting a laser beam to the core-wire exposed part and the core-wire connection body from a free end side of each piece part; and fixing the core-wire exposed part and the core-wire connection body melted by the laser beam, with the emission of the laser beam stopped.

A method of assembling a connector for automotive applications, comprising the steps of: providing a cable having at least one inner conductor; connecting an elongated inner signal contact of the connector to a stripped end of the at least one inner conductor; surrounding the elongated inner signal contact by an insulating element; placing a first shielding part of the connector around a first portion of the insulating element from a first radial direction; placing a second shielding part of the connector around a second portion of the insulating element from a second radial direction generally opposite to the first radial direction; and joining the first and second shielding parts to form a shielding contact of the connector surrounding the insulating element.

A method for producing an electrical connection between an electrical conductor, which includes a plurality of individual wires, and a contact element. The electrical conductor is arranged in a contact portion of the contact element, and the contact portion and the electrical conductor are subsequently pressed together so that the contact portion surrounds the electrical conductor. A a plurality of mutually spaced elongate welded connections between the contact portion and the electrical conductor are produced by laser irradiation of the contact portion, or by laser irradiation of the electrical conductor through an opening in the contact portion. The elongate welded connections extend in an irradiation direction from an irradiated region of the contact portion, or from an irradiated region of the electrical conductor, through an entire cross-section of the pressed electrical conductor to a region of the contact portion opposite to the irradiated region, such that the electrical conductor is connected to this area of the contact portion; and the irradiated regions are arranged in the form of a grid.

An electric energy transmission aluminum part and a machining process therefor including an aluminum conductive device (1) and an aluminum cable, with the aluminum cable including an aluminum conductive core (2) and an insulation layer (3) cladding a surface of the aluminum conductive core (2). An exposed section of the aluminum conductive core (2) with the insulation layer (3) stripped from the aluminum cable and at least part of the aluminum conductive core (2) clad with the insulation layer (3) are crimped inside the aluminum conductive device (1). A transition section (4) with a trapezoidal axial cross-section is provided at a junction between the insulation layer (3) and the exposed section of the aluminum conductive core (2) in the aluminum conductive device (1). Taking the transition section (4) as a demarcation point, an inner diameter of an end of the aluminum conductive device (1) that is crimped with the insulation layer (3) is greater than an inner diameter of an end of the aluminum conductive device (1) that is crimped with the aluminum conductive core (2). At least one concave structure is provided on a periphery of the aluminum conductive device (1). The concave structure provided on the surface of the aluminum conductive device (1) can effectively prevent the aluminum conductive device (1) from moving relative to a clamp, so as to solve the problem of displacement or rotation of the aluminum conductive device (1) in the clamp during welding, and improve the welding efficiency and the yield.

A method of making an electrical connection is here proposed. The method includes the steps of joining a first contact member to a second contact member in a material-to-material contact. The method steps for the same include: providing the first contact part, which towards the second contact part has a male, first joining section as a solid component with an at least substantially rotationally symmetrical profile, providing the second contact part having towards the first contact part a female second joining portion with a hollow profile, inserting the first joining section into the second joining section, applying a friction welding tool (400) to or in an opening of the second joining section (121), and moving the friction welding tool relative to the first contact part and/or the second contact part to generate welding energy for at least partially plasticizing a part of the first joining portion and/or second joining portion facing the other contact part.