A surface-mountable over-current protection device comprises at least one chip, a first lead and a second lead. The chip comprises a PTC material layer and two metal electrode layers disposed on upper and lower surfaces of the PTC material layer. The first lead is bent into multiple portions comprising a first electrode connecting portion connecting to one of the two metal electrode layers of the at least one chip and a first soldering portion for surface-mounting. The second lead is bent into multiple portions comprising a second electrode connecting portion connecting to another one of the two electrode layers of the at least one chip and a second soldering portion for surface-mounting. The PTC material layer comprises crystalline polymer and conductive filler dispersed therein, and the conductive filler has a resistivity less than 500 .Math.cm. The surface-mountable over-current protection device can withstand a cycle life test of 300 cycles at 20V/40 A without blowout.

Provided is a chip resistor including: a rectangular parallelepiped insulating substrate 1 which is made of ceramics; a pair of front electrodes 2 which are provided on lengthwise opposite end portions in a front surface of the insulating substrate 1; a resistive element 3 which is provided between and connected to the two front electrodes 2; an insulating protective layer 4 which covers the whole of the front surface of the insulating substrate 1 including the resistive element 3 and the two front electrodes 2; and a pair of cap-shaped end-surface electrodes 5 which are provided on the lengthwise opposite end portions of the insulating substrate 1 to be connected to the front electrodes 2; wherein: the protective layer 4 is formed out of a semi-transparent resin material which is similar in color to the insulating substrate 1.

Provided is a chip resistor including: a rectangular parallelepiped insulating substrate 1 which is made of ceramics; a pair of front electrodes 2 which are provided on lengthwise opposite end portions in a front surface of the insulating substrate 1; a resistive element 3 which is provided between and connected to the two front electrodes 2; an insulating protective layer 4 which covers the whole of the front surface of the insulating substrate 1 including the resistive element 3 and the two front electrodes 2; and a pair of cap-shaped end-surface electrodes 5 which are provided on the lengthwise opposite end portions of the insulating substrate 1 to be connected to the front electrodes 2; wherein: the protective layer 4 is formed out of a semi-transparent resin material which is similar in color to the insulating substrate 1.

An electronic component that includes: a base body; a glass film covering at least a part of an outer surface of the base body; and an underlayer electrode covering a part of a surface of the glass film, wherein the base body contains a Mn oxide, the underlayer electrode contains a conductive metal and a glass component, the base body has a reaction layer containing a composite oxide of Mn and the conductive metal at an end portion of the underlayer electrode, and the reaction layer has a void.

A medical temperature monitoring system includes an electrical wire set having a thermistor at a distal end of the wire set configured to sense temperatures to which the thermistor is exposed; an electronic circuit in electrical communication with the wire set and the thermistor and configured to convert the temperatures sensed by the thermistor to temperature display signals; a display in electrical communication with the electronic circuit for receiving the temperature display signals and displaying temperatures corresponding to the temperature display signals; and a bead of cured protective material encapsulating the thermistor. The protective material is a radiation curable adhesive applied to the thermistor in an uncured state and then cured to encapsulate the thermistor. The bead of cured protective material electrically isolates the conductor sufficient to pass a Hi-Pot test at 500 VAC, <0.1 mA.

The present invention relates to a surge-resistant wire-wound resistor and a manufacturing method thereof, wherein soldering points, at which a cap at each end of the wire-wound resistor is soldered, are electroplated with an electroplated metal layer to significantly improve the reliability of soldering points. The surge-resistant wire-wound resistor comprises a ceramic rod; one or more than one wound metal wire; a first cap and a second cap; a first lead wire and a second lead wire, wherein the first cap and the second cap are respectively electroplated to have a first cap electroplated layer and a second cap electroplated layer.

A temperature sensor includes a thermo-sensitive element, a pair of element electrode wires electrically connected to the thermo-sensitive element, a glass sealing body that covers the thermo-sensitive element and part of the pair of the element electrode wires, and a tablet formed with a pair of insertion holes extending in an axial direction thereof, through which the pair of the element electrode wires pass respectively. The glass sealing body includes a sealing part formed so as to extend from an element side end surface thereof located on a side of the thermo-sensitive element toward the thermo-sensitive element, and a sagging part formed in each of the pair of the insertion holes so as to extend integrally from the sealing part. The length of the sagging part in the axial direction being smaller than or equal to 1.5 mm.

A production method for an electronic component using an exterior packaging material containing a silicone resin comprises a step of dipping an element into an exterior packaging material containing a silicone resin to which aluminum hydroxide or magnesium hydroxide and a nonpolar solvent are added, an additive amount of the aluminum hydroxide or the magnesium hydroxide being controlled to a range of 60 [wt. %] or more to less than 70 [wt. %], a step of drying the exterior packaging material formed on a surface of the element to evaporate the nonpolar solvent and cause a silicone resin component to appear on a surface of the exterior packaging material, and a curing step of curing the exterior packaging material.

A production method for an electronic component using an exterior packaging material containing a silicone resin comprises a step of dipping an element into an exterior packaging material containing a silicone resin to which aluminum hydroxide or magnesium hydroxide and a nonpolar solvent are added, an additive amount of the aluminum hydroxide or the magnesium hydroxide being controlled to a range of 60 [wt. %] or more to less than 70 [wt. %], a step of drying the exterior packaging material formed on a surface of the element to evaporate the nonpolar solvent and cause a silicone resin component to appear on a surface of the exterior packaging material, and a curing step of curing the exterior packaging material.

An electronic component of the present disclosure includes a first insulating layer that includes impurities, a thin film resistor formed on the first insulating layer, and a barrier layer that is formed in at least one part of a region between the thin film resistor and the first insulating layer and that obstructs transmission of the impurities. The first insulating layer includes a first surface and a concave portion that is hollowed with respect to the first surface, and the barrier layer may include a first part embedded in the concave portion and a second part formed along the first surface of the first insulating layer from an upper area of the first part.