An electronic component is disclosed. In an embodiment, an electronic component includes at least one NTC element and at least two electrically conductive contact elements, wherein the NTC element is electrically conductively connected to a respective contact element via a connection material, and wherein a coefficient of thermal expansion of the contact elements is adapted to a coefficient thermal expansion of the NTC element.

A composite thermistor material, a preparation method and an application thereof. The perovskite structure oxide and the pyrochlorite structure oxide are composite by solid state reaction method, which comprise process of ball milling, drying, and calcining. Then the thermistor ceramics with high temperature resistance and controllable B value are sintered at high temperature after mould forming, then the thermistor disks are coated by platinum paste, and then the platinum wire is welded as the lead wire to form thermistor element. The thermistor of the invention can realize temperature measurement from room temperature to 1000 C. and has good negative temperature coefficient thermistor characteristics. The thermistor coefficient B can be adjusted by changing the two-phase ratio to meet the requirements of different systems.

A composite thermistor chip includes a thermosensitive ceramic chip, a metal electrode and a glass glaze resistor, wherein the thermosensitive ceramic chip has a front side and a back side, the metal electrode includes a first terminal electrode, a second terminal electrode and a third electrode layer; the first terminal electrode and the second terminal electrode are respectively arranged at two ends of the front side of the thermosensitive ceramic chip, and the glass glaze resistor is arranged on the front side of the thermosensitive ceramic chip, two ends of the glass glaze resistor are respectively connected to the first terminal electrode and the second terminal electrode; and the back side of the thermosensitive ceramic chip is covered with the third electrode layer.

An electrical device with a soldered joint is disclosed. In an embodiment, an electrical device includes at least one soldered joint having a first wire soldered at one end to the device, wherein the first wire bears with a bearing surface on the device, and wherein the first wire has at least one bend in a region of the bearing surface of the first wire on the device.

In an embodiment a sensor element includes at least one carrier layer having a top side and an underside, at least one functional layer arranged at the top side of the carrier layer and comprising a material having a temperature-dependent electrical resistance and at least one top electrode configured for electrically contacting the functional layer from a top side of the functional layer, wherein the top electrode is arranged directly on the functional layer, wherein the top electrode forms the top side of the sensor element, and wherein the sensor element is configured to be integrated as a discrete component directly into an electrical system.

An electronic component includes a ceramic body, and an external electrode on the ceramic body, the external electrode includes a base layer continuously covering an end surface of the ceramic body and a portion of a side surface bordering the end surface, and a plating layer covering the base layer, the ceramic body includes a recess open on the side surface, an opening of the recess includes a pair of edges, one edge of the opening is located within a covered region on the side surface covered with the base layer, and the other edge of the opening is spaced away from the covered region.

In an embodiment, a component includes a first electrode and a second electrode arranged one above the other in a stacking direction, wherein the first electrode and the second electrode overlap in a first overlap region, wherein the first electrode has, in a first region containing the first overlap region, an extent in a first direction perpendicular to the stacking direction that is greater than an extent of the second electrode in the first direction in the first region, and wherein the first electrode has, in the first region containing the first overlap region, an extent in a second direction perpendicular to the stacking direction and to the first direction that is greater than an extent of the second electrode in the second direction in the first region, and a third electrode arranged in the same plane as the second electrode, wherein the first electrode is a floating electrode, wherein the first electrode and the third electrode overlap in a second overlap region, wherein the first electrode has, in a second region that contains the second overlap region, extents in the first direction and in the second direction that are greater than the extents of the third electrode in the first and the second direction in the second region, and wherein the first electrode has, in a connecting region that connects the first region and the second region, an extent in the first direction that is smaller than the extent of the first electrode in the first region and smaller than the extent of the first electrode in the second region.

An electronic component that includes: a base body having an outer surface defining a recess with an inner surface, wherein, when the recess is viewed in a direction orthogonal to the outer surface, at least a part of an outer edge of the recess is curved, and when the recess is viewed in a section orthogonal to the outer surface, at least a part of the inner surface of the recess is curved; a wiring inside the base body; and a glass film covering the outer surface of the base body and not covering the inner surface of the recess.

An electronic component that includes: a base body; wiring inside the base body; a glass film covering an outer surface of the base body; an underlying electrode electrically connected to the wiring and covering a part of the glass film; and a metal layer covering the underlying electrode, wherein the glass film includes an uncovered portion that is not covered with the underlying electrode and separated from an outer edge of the underlying electrode by more than 10 ?m, and a boundary portion that is not covered with the underlying electrode and not separated from the outer edge of the underlying electrode by more than 10 ?m, and a thickness of the boundary portion is larger than a thickness of the uncovered portion.

An NTC thermistor element includes a thermistor body and a plurality of internal electrodes disposed in the thermistor body and opposing each other. The thermistor body includes a region interposed between adjacent internal electrodes of the plurality of internal electrodes. The region of the thermistor body includes a plurality of crystal grains arranged in succession between the internal electrodes adjacent to each other. The plurality of crystal grains include a first crystal grain, a second crystal grain, and a third crystal grain. The first crystal grain is in contact with one internal electrode of the internal electrodes adjacent to each other. The second crystal grain is in contact with another internal electrode of the internal electrodes adjacent to each other. The third crystal grain is not in contact with the first crystal grain and the second crystal grain.