The purpose of the present invention is to provide: a temperature sensor able not only to prevent failures where a temperature-sensitive sintered body ends up coming out of a protective case together with a packing resin, but also to curb changes in properties of the temperature-sensitive sintered body and ensure reliability; and a device provided with this temperature sensor. A temperature sensor (1) is provided with: a protective case (2) that has a linear expansion coefficient of 7.5 to 19.5×10.sup.−6/° C.; a temperature-sensitive sintered body (3) that is arranged inside the protective case (2); a lead wire (4) that is connected to the temperature-sensitive sintered body (3) and has a cross-sectional area of 0.097 mm.sup.2 or less; and a packing resin (6) that has a linear expansion coefficient of 7.5 to 19.5×10.sup.−6/° C. and that is packed around the temperature-sensitive sintered body (3) inside the protective case (2).

A process manufactures a PTC heating element (10) that includes at least one PTC component (20) and, on at least one side (50, 52) of the at least one PTC component (20), at least one carrier (14, 16) permanently connected to the PTC component (20). The process includes arranging solder material (46, 48) between the one side of the at least one PTC component (20), which side is to be permanently connected to the at least one carrier (14, 16), and the at least one carrier to be connected on this side of the at least one PTC component (20). The solder material (46, 48) is melted by induction soldering to connect the at least one PTC component (20) to the at least one carrier (14, 16).

An externally-controllable thermal tripping device comprising a voltage dependent resistor including a voltage dependent resistor chip; a thermal tripper including a tripping electrode; and a controllable heating element. The tripping electrode is connected to an electrode of the voltage dependent resistor chip through a meltable welding material, and the controllable heating element is controlled by an external control device to generate heat and transmit generated heat to a commissure of said welding material to melt said welding material and electrically disconnect the tripping electrode from the voltage dependent resistor chip.

A resistor according to the present disclosure includes an insulated substrate, a resistive layer formed of a resistance body material and a bonding layer for bonding the insulated substrate and the resistive layer, wherein the resistor is configured so that a ratio of a sheet resistance of the bonding layer to a sheet resistance of the resistive layer is 100 or more.

A resistor according to the present disclosure includes an insulated substrate, a resistive layer formed of a resistance body material and a bonding layer for bonding the insulated substrate and the resistive layer, wherein the resistor is configured so that a ratio of a sheet resistance of the bonding layer to a sheet resistance of the resistive layer is 100 or more.

Disclosed is a circuit protection device including a case, a negative temperature coefficient thermistor which is accommodated in the case and includes a resistant heating element, a pair of electrodes installed on both sides of the resistant heating element, and a first lead wire and a second lead wire withdrawn from the pair of electrodes, respectively, and a thermal fuse which is accommodated in the case and includes a thermal fuse body and a third lead wire and a fourth lead wire connected to both ends of the thermal fuse body, respectively. Here, the second lead wire and the third lead wire are connected to each other in the case.

A shunt resistor 10, 110 includes a flat resistive element 11; a first electrode block 12 that is made of a conductive metal material and is laminated on a lower surface 11a of the resistive element 11; and a second electrode block 13, 113 that is made of a conductive metal material and is laminated on an upper surface 11b of the resistive element 11, in which the second electrode block 13, 113 is a block body including an electrode portion 14 connected to the resistive element 11 and an extension portion 15, 115 extending downward from a side surface of the electrode portion 14.

A shunt resistor 10, 110 includes a flat resistive element 11; a first electrode block 12 that is made of a conductive metal material and is laminated on a lower surface 11a of the resistive element 11; and a second electrode block 13, 113 that is made of a conductive metal material and is laminated on an upper surface 11b of the resistive element 11, in which the second electrode block 13, 113 is a block body including an electrode portion 14 connected to the resistive element 11 and an extension portion 15, 115 extending downward from a side surface of the electrode portion 14.

A composite circuit protection device includes first and second positive temperature coefficient (PTC) components, a voltage-dependent resistor, and first, second and third conductive leads. The first PTC component includes a first PTC layer, and first and second electrode layers respectively disposed on two opposite surfaces of the first PTC layer. The second PTC component includes a second PTC layer, and third and fourth electrode layers respectively disposed on the two opposite surfaces of the second PTC layer. The voltage-dependent resistor is connected to the second and third electrode layers. The first, second and third conductive leads are bonded to the first electrode layer, the voltage-dependent resistor, and the fourth electrode layer, respectively.

The invention relates to a production method for an electrical resistance element (for example a shunt) with the following steps: -providing a resistance alloy in powder form, and -forming the resistance element from the powdered resistance material. The invention also relates to a correspondingly produced resistance element.