A pressure contact type connector includes: an upper flat plate portion; a lower flat plate portion which is disposed below the upper flat plate portion; a first spring portion which connects the upper and lower flat plate portions; and a second spring portion which extends upward from the lower flat plate portion and applies a resilient force to the upper flat plate portion, in which the first and second spring portions are wound about the upper flat plate portion when viewed from above in a plan view, and extend so that the spring portions do not interfere with each other when being compressed and extended in the vertical direction, the first spring portion is formed to be bent so that a width dimension is larger than a thickness dimension, and the second spring portion is formed to be bent so that a width dimension is larger than a thickness dimension.

In an electronic component, an outer electrode includes a sintered layer including a sintered metal, a reinforcement layer not containing Sn but including Cu or Ni, an insulation layer, and a Sn-containing layer. The sintered layer extends from each end surface of an element assembly onto at least one main surface thereof to cover each end surface of the element assembly. The reinforcement layer extends on the sintered layer and covers the sintered layer entirely. The insulation layer is directly provided on the reinforcement layer at each end surface of the element assembly, extends in a direction perpendicular or substantially perpendicular to a side surface of the element assembly, and defines a portion of a surface of the outer electrode. The Sn-containing layer covers the reinforcement layer except for a portion of the reinforcement layer that is covered by the insulation layer, and defines another portion of the surface of the outer electrode.

A lead assembly includes a lead with a distal end and a proximal end. The lead includes a plurality of electrodes disposed at the distal end and a plurality of terminals disposed at the proximal end. The lead also defines at least one central lumen and a plurality of outer lumens. The central and outer lumens extend from the proximal end to the distal end such that the plurality of outer lumens extend laterally from the at least one central lumen. The lead further includes a plurality of conductive wires. Each conductive wire couples at least one of the plurality of electrodes electrically to at least one of the plurality of terminals. At least two conductive wires are disposed in each of the plurality of outer lumens.

In a method for manufacturing an electronic component, a step of providing an outer electrode includes a step of providing a sintered layer including a sintered metal, a step of providing a reinforcement layer not containing Sn but including Cu or Ni, a step of providing an insulation layer, and a step of providing a Sn-containing layer. The sintered layer extends from each end surface of an element assembly onto at least one main surface thereof to cover Bich. The reinforcement layer covers the sintered layer entirely. The insulation layer is directly provided on the reinforcement layer at each end surface of the element assembly and defines a portion of a surface of the outer electrode. The Sn-containing layer covers the reinforcement layer except for a portion of the reinforcement layer that is covered by the insulation layer, and defines another portion of the surface of the outer electrode.

An implantable electrode for electrical stimulation of a body, for example, being a component of an implantable medical electrical lead, is preferably in the form of a coiled conductor wire, wherein the wire is formed by a tantalum (Ta) core directly overlaid with a platinum-iridium (PtIr) cladding. When a maximum thickness of the PtIr cladding defines a cladded zone between an outer, exposed surface of the electrode and the Ta core, a surface of the Ta core encroaches into the cladded zone by no more than approximately 50 micro-inches. The tantalum core may be cold worked to improve surface quality or formed from a sintered and, preferably, grain stabilized tantalum.

A connecting device including a substantially elongated inserting member extending in a longitudinal direction and comprising a transverse direction transverse thereto, said inserting member comprising an outer surface with at least two electrically conductive parts with insulating material arranged there between; and wherein the inserting member is configured to mechanically and electrically connect the at least two electrically conductive parts with wire ends of a connection cable within the space enclosed by the outer surface. The invention is further related to an assembly of a connection cable and a connecting device, as well as a method for connecting a connecting device to a connection cable.

An electrical contact component and a method for the production thereof. The contact component has a sintered contact element and a contact carrier cast onto the contact element. The grains of the contact element are oriented in a preferential direction.

A pressure contact type connector includes: an upper flat plate portion; a lower flat plate portion which is disposed below the upper flat plate portion; a first spring portion which connects the upper and lower flat plate portions; and a second spring portion which extends upward from the lower flat plate portion and applies a resilient force to the upper flat plate portion, in which the first and second spring portions are wound about the upper flat plate portion when viewed from above in a plan view, and extend so that the spring portions do not interfere with each other when being compressed and extended in the vertical direction, the first spring portion is formed to be bent so that a width dimension is larger than a thickness dimension, and the second spring portion is formed to be bent so that a width dimension is larger than a thickness dimension.

A pressure contact type connector includes: an upper flat plate portion; a lower flat plate portion which is disposed below the upper flat plate portion; a first spring portion which connects the upper and lower flat plate portions; and a second spring portion which extends upward from the lower flat plate portion and applies a resilient force to the upper flat plate portion, in which the first and second spring portions are wound about the upper flat plate portion when viewed from above in a plan view, and extend so that the spring portions do not interfere with each other when being compressed and extended in the vertical direction, the first spring portion is formed to be bent so that a width dimension is larger than a thickness dimension, and the second spring portion is formed to be bent so that a width dimension is larger than a thickness dimension.

A method of forming a terminating end of a cable, comprising the steps of: providing a cable; cutting a circumferential slit through an outer insulation layer; clamping a first section of the outer insulation layer with a first clamping device, and clamping a second section of the outer insulation layer with a second clamping device; displacing the first clamping device, separating the first section from the second section and exposing a section of a metal braid; displacing the first clamping device; pushing and pressing the exposed section to fold the exposed section into a braid protrusion portion; loosening the first and second clamping devices, and removing the cable from the first and second clamping devices; cutting the braid protrusion portion with a cutting device to form a protruding braid portion, the protruding braid portion; and removing the first section of the outer insulation layer and a first protruding braid portion.