An object is to provide a chip resistor in which hot spots can be dispersed and the adverse effects on performance caused by microcracks can also be reduced. A chip resistor includes an insulating substrate, a resistive element, and electrodes. In the resistive element, a first trimming groove and a second trimming groove are formed. A first vertical groove of the first trimming groove and a second vertical groove of the second trimming groove are formed with a spacing in between in an X1-X2 direction. A first horizontal groove of the first trimming groove and a second horizontal groove of the second trimming groove extend in directions approaching each other, and terminal ends of the first horizontal groove and the second horizontal groove are formed to be separated in the X1-X2 direction such that the first horizontal groove and the second horizontal groove do not overlap in a Y1-Y2 direction.

Provided are: a temperature sensor capable of ensuring reliability and improving thermal responsiveness; and a device equipped with such a temperature sensor. The present invention is provided with: a surface-mounted heat sensitive element (10) having at least a pair of electrode parts (12a), (12b); lead parts (22a), (22b) that are electrically connected to the pair of electrode parts (12a), (12b) by welding; a holder (21) that holds and fixes the lead parts (22a), (22b); and an insulation coating part (23) that insulates at least a portion of the lead parts (22a), (22b) and the heat sensitive element (10). The lead parts (22a), (22b) are tabular metal plates and are formed of a metallic material having a melting point of not more than 1300° C.

An object is to provide a chip resistor in which hot spots can be dispersed and the adverse effects on performance caused by microcracks can also be reduced. A chip resistor includes an insulating substrate, a resistive element, and electrodes. In the resistive element, a first trimming groove and a second trimming groove are formed. A first vertical groove of the first trimming groove and a second vertical groove of the second trimming groove are formed with a spacing in between in an X1-X2 direction. A first horizontal groove of the first trimming groove and a second horizontal groove of the second trimming groove extend in directions approaching each other, and terminal ends of the first horizontal groove and the second horizontal groove are formed to be separated in the X1-X2 direction such that the first horizontal groove and the second horizontal groove do not overlap in a Y1-Y2 direction.

An object is to provide a chip resistor in which hot spots can be dispersed and the adverse effects on performance caused by microcracks can also be reduced. A chip resistor includes an insulating substrate, a resistive element, and electrodes. In the resistive element, a first trimming groove and a second trimming groove are formed. A first vertical groove of the first trimming groove and a second vertical groove of the second trimming groove are formed with a spacing in between in an X1-X2 direction. A first horizontal groove of the first trimming groove and a second horizontal groove of the second trimming groove extend in directions approaching each other, and terminal ends of the first horizontal groove and the second horizontal groove are formed to be separated in the X1-X2 direction such that the first horizontal groove and the second horizontal groove do not overlap in a Y1-Y2 direction.

Provided are: a temperature sensor capable of ensuring reliability and improving thermal responsiveness; and a device equipped with such a temperature sensor. The present invention is provided with: a surface-mounted heat sensitive element (10) having at least a pair of electrode parts (12a), (12b); lead parts (22a), (22b) that are electrically connected to the pair of electrode parts (12a), (12b) by welding; a holder (21) that holds and fixes the lead parts (22a), (22b); and an insulation coating part (23) that insulates at least a portion of the lead parts (22a), (22b) and the heat sensitive element (10). The lead parts (22a), (22b) are tabular metal plates and are formed of a metallic material having a melting point of not more than 1300 C.

A component having an active volume, the active volume not being centrally positioned along a height of the component, and/or not being centrally positioned along a width of the component. Use of the component is also disclosed. Further aspects relate to a use of the component and to a component. The component can be an NTC thermistor or a PTC thermistor or a temperature measurement element. Use of the component for monitoring a temperature of a battery or in a vehicle is also disclosed.

An electronic component includes a body part and a via part. The body part includes first and second metal layers disposed with at least one dielectric layer interposed therebetween. The via part is disposed in the body part and includes first and second vias penetrating through the body part and selectively connected to the first and second metal layers, respectively. The first and second metal layers contain different metals. In some examples, a first insulating film is disposed between the first metal layer and the second via to electrically insulate the second via from the first metal layer, and a second insulating film is disposed between the second metal layer and the first via to electrically insulate the first via from the second metal layer. A method for forming the electronic component includes use of first and second etchants to selectively etch the first and second metal layers.

A circuit substrate includes a substrate body made of a ceramic, wiring located on the substrate body, and a resistor interposed in the wiring and having an electrical resistance higher than that of the wiring. The wiring includes a first electrode and a second electrode. The first electrode includes a first body portion and a plurality of first comb-tooth portions each extending from the first body portion in a direction intersecting a direction in which the first body portion extends. The second electrode includes a second body portion and a plurality of second comb-tooth portions, each extending from the second body portion in a direction intersecting a direction in which the second body portion extends, and has a comb-tooth shape located to mesh with a comb-tooth shape of the first electrode with an interval. The resistor includes a resistive element located in contact with both the first body portion of the first electrode and the second body portion of the second electrode.

A circuit substrate includes a substrate body made of a ceramic, wiring located on the substrate body, and a resistor interposed in the wiring and having an electrical resistance higher than that of the wiring. The wiring includes a first electrode and a second electrode. The first electrode includes a first body portion and a plurality of first comb-tooth portions each extending from the first body portion in a direction intersecting a direction in which the first body portion extends. The second electrode includes a second body portion and a plurality of second comb-tooth portions, each extending from the second body portion in a direction intersecting a direction in which the second body portion extends, and has a comb-tooth shape located to mesh with a comb-tooth shape of the first electrode with an interval. The resistor includes a resistive element located in contact with both the first body portion of the first electrode and the second body portion of the second electrode.

An electronic component includes a body part and a via part. The body part includes first and second metal layers disposed with at least one dielectric layer interposed therebetween. The via part is disposed in the body part and includes first and second vias penetrating through the body part and selectively connected to the first and second metal layers, respectively. The first and second metal layers contain different metals. In some examples, a first insulating film is disposed between the first metal layer and the second via to electrically insulate the second via from the first metal layer, and a second insulating film is disposed between the second metal layer and the first via to electrically insulate the first via from the second metal layer. A method for forming the electronic component includes use of first and second etchants to selectively etch the first and second metal layers.