An electrode with multiple metallic-layers structure formed by a magnetron sputtering technique for a semiconductor device and method for producing same is disclosed. The ceramic device includes at least one from selected group consisting of ZnO-MOV (metal oxide varistors), BaTiO3-PTC (positive temperature coefficient) thermistors, Mn3O4-NTC (negative temperature coefficient) thermistors, and capacitors. The multiple metallic-layers include a sputtered buffer layer and a sputtered electrical contact layer. The buffer layer includes at least one alloy selected form group consisting of NiCr (Ni from 50-90 wt %), TiNi (Ti from 40-60 wt %), and AlNi (Al from 40-70 wt %) and the thickness of this layer is from greater than zero to less than 100 nm. The electrical contact layer includes at least one of Cu, Ag, Pt, Au, or combination. More specifically, the electrode includes one of NiCr/Cu system, NiCr/Ag system, NiCr/Cu/Ag system, TiNi/Cu/Ag system, or AlNi/Cu/Ag system. The thickness ratio of the electrical contact layer to the intermetallic barrier layer is from 1 to 4.

A surge arrester includes a polymer body including a first leg having a first channel defined therein and a second leg perpendicular to the first leg and having a second channel defined therein. A varistor assembly is in the first channel. The varistor assembly includes a plurality of varistor elements electrically connected in series and forming a stack of the plurality of varistor elements. The stack has a first end surface, a second end surface, and an outer side surface extending between the first end surface and the second end surface. The varistor assembly includes a first end fitting at the first end surface of the stack, a second end fitting at the second end surface of the stack, a plurality of rods disposed around the side surface of the stack, and a polymer fill layer between the side surface of the stack and the first leg of the body.

A chip varistor includes an element body exhibiting varistor characteristics, internal electrodes containing a first electrically conductive material, and an intermediate conductor containing a second electrically conductive material. The intermediate conductor is separated from the internal electrodes in a direction in which the internal electrodes oppose each other, and is disposed between the internal electrodes. At least a part of the intermediate conductor overlaps the internal electrodes in the direction in which the internal electrodes oppose each other. The element body includes a low resistance region in which the second electrically conductive material is diffused. The low resistance region is located between the first and second internal electrodes in the direction in which the first and second internal electrodes oppose each other.

A chip varistor includes an element body exhibiting varistor characteristics, internal electrodes containing a first electrically conductive material, and an intermediate conductor containing a second electrically conductive material. The intermediate conductor is separated from the internal electrodes in a direction in which the internal electrodes oppose each other, and is disposed between the internal electrodes. At least a part of the intermediate conductor overlaps the internal electrodes in the direction in which the internal electrodes oppose each other. The element body includes a low resistance region in which the second electrically conductive material is diffused. The low resistance region is located between the first and second internal electrodes in the direction in which the first and second internal electrodes oppose each other.

A surge arrester includes a tubular housing and an end fitting which is connected to one end of the housing and on which a column having at least one electrical resistor is disposed. A support abuts the inner surface of the tubular housing in the region of the end fitting. The support has a recess in the longitudinal direction of the surge arrester, into which a pressure device is inserted. A method for installing a surge arrester is also provided.

A functional contactor is provided. The functional contactor according to one embodiment of the present invention comprises: a conductive elastic portion having elasticity and electrically contacting one of a circuit board of an electronic device, a bracket coupled to the circuit board, and a conductor which can come into contact with the human body; a substrate made from a dielectric material and having a groove in either the upper surface or the lower surface thereof; and a functional element comprising a high dielectric material inserted into the groove and made from sintered ceramic having a higher dielectric constant than a dielectric material, a first electrode disposed on the upper surface of the substrate and electrically connected in series to the conductive elastic portion, and a second electrode disposed on the lower surface of the substrate and opposite to the first electrode.

Provided are metal oxide varistors comprising a sintered ceramic, in which the ceramic comprises, by weight, about 91.0% to about 97.0% ZnO, at least 0.3% Mn, at least 0.4% Bi, at least 1.0% Sb, and 0.50% or less Co. The metal oxide varistors as disclosed herein may exhibit reduced power dissipation, improved thermal stability, and may be produced at a lower cost relative to conventional MOV devices.

Provided are metal oxide varistors comprising a sintered ceramic, in which the ceramic comprises, by weight, about 91.0% to about 97.0% ZnO, at least 0.3% Mn, at least 0.4% Bi, at least 1.0% Sb, and 0.50% or less Co. The metal oxide varistors as disclosed herein may exhibit reduced power dissipation, improved thermal stability, and may be produced at a lower cost relative to conventional MOV devices.

Provided are a resin composition for forming a varistor and a varistor capable of increasing freedom in the design of substrates, ICs, or electronics. The resin composition for forming a varistor includes (A) an epoxy resin, (B) a curing agent, (C) carbon nanotubes, and (D) a dispersant. The (C) carbon nanotubes may be single-walled carbon nanotubes, multi-walled carbon nanotubes, or a combination thereof. The (D) dispersant includes a polyalkyl oxide surfactant. The polyalkyl oxide surfactant has a polyalkyl ether skeleton in the molecule.

A surge arrester assembly comprises a ground connector with a clamping component and line connector assembly that incorporates non-bolted mechanical and electrical connections. The assembly connections permit the use of insulating hot sticks for installation and removal of the arrester module for safe and rapid removal and replacement of expired surge arresters. The clamp and line connector are reusable for replacement of surge arresters.