Abstract: A surface mountable over-current protection device comprises a PTC material layer, first and second conductive layers, left and right electrodes, left and right conductive members, and left and right insulating members. The PTC material layer comprises a left notch at a left end and a right notch at a right end. The first conductive layer comprises a primary portion disposed on an upper surface of the PTC material layer and a secondary portion extending over the left notch, and the second conductive layer comprises a primary portion disposed on a lower surface of the PTC material layer and a secondary portion extending over the underside of the right notch. The left conductive member connects to the left electrode and the first conductive layer and isolates from the second conductive layer. The right conductive member connects to the right electrode and the second conductive layer and isolates from the first conductive layer.

Abstract: The present invention relates to a product and fabrication method for a varistor comprising a solid phase of zinc oxide particles substantially uniformly dispersed within a resin media. The varistor of the present invention is synthesized by mixing a substantially homogenous mixture of solid zinc oxide particles and a resin media, and heating the mixture under conditions to melt the resin and suspend the solid zinc oxide particles therein.

Abstract: Resistors and a method of manufacturing resistors are described herein. A resistor includes a resistive element and a plurality of conductive elements. The plurality of conductive elements are electrically insulated from one another via a dielectric material and thermally coupled to the resistive element via an adhesive material disposed between each of the plurality of conductive elements and a surface of the resistive element. The plurality of conductive elements is coupled to the resistive element via conductive layers and solderable layers.

Abstract: A chip resistor includes a resistor board, a first electrode, a second electrode and an insulating layer. The second electrode is offset from the first electrode in a lateral direction perpendicular to the thickness direction of the resistor board. The obverse surface of the resistor board includes a first region in contact with the first electrode, a second region in contact with the second electrode and an intermediate region in contact with the insulating layer. The intermediate region is disposed between the first region and the second region in the lateral direction. The first electrode includes a first underlying layer and a first plating layer. The first underlying layer is disposed between the first plating layer and the insulating layer in the thickness direction of the resistor board.

Abstract: An overcurrent protection device includes a polymer positive temperature coefficient (PPTC) component and two pins. The PPTC component includes a positive temperature coefficient (PTC) element having two opposite surfaces, and two electrodes respectively connected to the surfaces of the PTC polymeric element. The two pins are respectively connected to the electrodes and extend in an extending direction. Each of the pins has a cross-sectional area that is perpendicular to the extending direction and greater than or equal to 0.8 mm2. The overcurrent protection device has an average trip current and an average work current, where the ratio of the average trip current to the average work current is less than 1.5.

Abstract: A method of manufacturing an electronic component includes manufacturing a ceramic element including one pair of end surfaces and four side surfaces, forming external electrodes at both end portions of the ceramic element, measuring an initial characteristic value, determining any side surface to be machined among the four side surfaces and then determining, based on stored data, an amount of machining to be performed on the side surface to be machined, and machining, by the determined machining amount, the side surface of the ceramic element, which is determined to be machined, to be flush or substantially flush with the external electrodes.

Abstract: A frequency-dependent resistance element includes an element assembly composed of a sintered magnetic material and a coil conductor embedded in the element assembly. The sintered magnetic material is composed of a primary component containing Fe, Zn, Ni, and Cu and a secondary component containing Co. In the primary component, on a percent by mole basis, the Fe content is 46.79 to 47.69, the Zn content is 12.60 to 24.84, and the Ni content is 19.21 to 32.36 in terms of Fe2O3, ZnO, and NiO, respectively. The molar ratio (Ni:Zn) of Ni to Zn is (1?X):X, where X is from about 0.28 to about 0.56. The content of Co in terms of Co3O4 is 1.0 to 10.0 parts by mass relative to 100 parts by mass of the primary component containing Fe, Zn, Ni, and Cu in terms of Fe2O3, ZnO, NiO, and CuO, respectively.

Abstract: There is provided a chip resistor suitable for power detection. The chip resistor includes a resistor having a resistor lower surface and a resistor upper surface which face mutually opposite sides in a thickness direction, a pair of resistor first side surfaces spaced apart from each other in a first direction perpendicular to the thickness direction, and a pair of resistor second side surfaces spaced apart from each other in a second direction perpendicular to both the thickness direction and the first direction, a first electrode formed along one resistor first side surface, and a second electrode formed along the other resistor first side surface, and spaced apart from the first electrode.

Abstract: An NTC component comprising a first electrode (1) and a second electrode (2) is specified. The NTC component further comprises an NTC element (3) disposed between the first electrode (1) and the second electrode (2), wherein the NTC element (3) comprises a ceramic having the general composition AB2O4, and where A and B each comprise one or more of the materials Mn, Ni, Co and Cu, and B additionally comprises one or more of the materials Fe, Y, Pr, Al, In, Ga and Sb.

Abstract: A strain detector includes a strain-causing portion, an insulation film formed on the strain-causing portion, a strain gauge formed on the insulation film and configured to detect the strain generated by the strain-causing portion as electric signals, an electrode connected to the strain gauge, a bonding pad extending from the electrode, a bonding wire connected to the bonding pad, and an insulative resin layer covering the strain gauge without covering the bonding pad and the bonding wire.

Abstract: A disconnector and related surge arrester include first and second connection terminals connecting to active electrical leads, between which a protection element is inserted, having electrodes electrically connected to the connection terminals, a disconnector between the first terminal and an electrode of the protection element including a metal plate having a base end electrically connected to the first terminal and a distal end maintained electrically connected to the electrode, the plate being able to sublimate in the presence of short-circuit currents above a preset threshold, an intercepting slider, mounted longitudinally slidable along a longitudinal direction which lies between the base end of the lamina and the electrode of the protection element to intersect development of an electric arc, a sliding guide for the intercepting slider, the slider being biased in the longitudinal direction, through a preloaded elastic unit, towards an intercepting position abutting a portion of the plate.

Abstract: An over-current protection device comprises a PTC device and a heating element operable to heat the PTC device. The PTC device contains crystalline polymer and metal or ceramic conductive filler dispersed therein. The PTC device has a resistivity less than 0.1 ?·cm. The over-current protection device has the relation: It (heating)<Ih (60° C.)×10%, where Ih (60° C.) is a hold current of the over-current protection device at 60° C. when the heating element is not activated; It (heating) is a trip current of the over-current protection device when the heating element is activated to heat the PTC device. The PTC device has high hold current, thereby allowing a battery containing the device can be fast charged with a large current. In a specific situation, the heating element heats the PTC device to decrease the hold current of the over-current protection device of low resistivity, and accordingly the PTC device can trip by a small current.

Abstract: The invention concerns a device for protection against transitory overvoltages, comprising: a varistor; a discharge tube; a thermofusible soldering securing a first electrode of the discharge tube and a first electrode of the varistor, the thermofusible soldering being a conductor of electricity and being able to melt beyond a temperature threshold when the varistor or the discharge tube heats up; the second electrode of the varistor being designed to be connected to a first electrical line and the second electrode of the discharge tube being designed to be connected to a second electrical line; a restoring element exerting a restoring force tending to move the first electrode of the varistor away from the first electrode of the discharge tube in order to allow a separation between the first electrode of the varistor and the first electrode of the discharge tube during a melting of the thermofusible soldering.

Abstract: In order to realize a thermistor on a base substrate without restricting the layout of a wiring layer, a thermistor mounting apparatus is provided, the thermistor mounting apparatus including a base substrate, and a thermistor component provided over the base substrate, in which the thermistor component has an insulating substrate, an electrode provided over the insulating substrate, and a thermistor provided over the insulating substrate and electrically connected to the electrode.

Abstract: Processes for manufacturing touch sensors with one or more guard traces to reduce the effect of moisture damage are provided. One example process can include forming one or more guard traces between an edge of the touch sensor and the metal traces that route the drive and sense lines to bond pads. The one or more guard traces can be uncoupled from the drive lines and sense lines to protect the inner metal traces from moisture damage. In some examples, ends of the one or more guard traces can be coupled to ground by copper. In other examples, ends of the one or more guard traces can be coupled to ground by indium tin oxide or the one or more guard traces can be coupled to ground by a strip of indium tin oxide. In yet other examples, the guard trace can be floating (e.g., not coupled to ground).

Abstract: A surge arrester has a resistance column which is pressed together by one or more clamping devices. The clamping devices are each fixed at both ends of the resistance column to an end fitting by way of a fixing device. An electrically insulating housing encloses the fixing device. Each end fitting has a first contour, on which the fixing devices are arranged and which is enclosed by the housing. The end fitting also has a second contour with a smaller diameter than the first contour.

Abstract: To provide a chip resistor in which a resistive element can be surely protected from an external environment and which is also excellent in corrosion resistance, a chip resistor 1 is configured to include an insulating substrate 2, a pair of front electrode 3 provided on opposite end portions of a front surface of the insulating substrate 2, a pair of back electrodes 7 provided on opposite end portions of a back surface of the insulating substrate 2, a resistive element 4 provided to extend onto the two front electrodes 3, a first insulating layer 5 covering the resistive element 4, a second insulating layer 6 made of a resin material to cover the first insulating layer 5, end surface electrodes 8 establishing electrical continuity between the front electrodes 3 and the back electrodes 7, plating layers 9 covering the end surface electrodes 8, etc.

Abstract: A voltage-nonlinear resistor element 10 includes a voltage-nonlinear resistor (referred simply as “resistor”) 20 and a pair of electrodes 14 and 16 between which the resistor 20 is interposed. The resistor 20 has a multilayer structure including a first layer 21 composed primarily of zinc oxide, a second layer 22 composed primarily of zinc oxide, and a third layer 23 composed primarily of a metal oxide other than zinc oxide. The second layer 22 is adjacent to the first layer 21 and has a smaller thickness and a higher volume resistivity than the first layer 21. The third layer 23 is adjacent to the second layer 22.

Abstract: A sensor including a sensing element comprising conductive features formed on a substrate; wherein the conductive features have been formed from a palladium complex ink composition that has been deposited onto the substrate to form the deposited features and wherein the deposited features have been heated to form the conductive features on the substrate. A method including disposing a palladium complex ink composition onto a substrate to form deposited features; and heating the deposited features to form conductive features on the substrate. A strain gauge sensor including a sensing element comprising conductive features formed on a substrate; wherein the conductive features conform to a two dimensional substrate surface; or wherein the conductive features conform to a three dimensional substrate surface.

Abstract: A manipulator includes a manipulation body having a plurality of bar-shaped portions which intersect orthogonally with each other at one intersection point, and a plurality of detection bodies which detect a displacement of the manipulation body. The plural bar-shaped portions include a bar-shaped portion and another bar-shaped portion which intersect orthogonally with each other. The plural detection bodies include a first detection body which detects a displacement of one end side of the bar-shaped portion with respect to the intersection point, a second detection body which detects a displacement of the other end side of the bar-shaped portion with respect to the intersection point, and a third detection body which detects a displacement of one end side of the bar-shaped portion with respect to the intersection point.