A gas insulated surge arrester is disclosed, including a metal clad housing within which a block stack is arranged. The block stack includes at least one metal-oxide resistor column and the gas insulated surge arrester is characterized by a capacitive element arranged to obtain an electric field measurement of the gas insulated surge arrester; and by a bushing arranged through the metal clad housing and arranged to the provide a capacitive third-order harmonic current measurement to an input of a surge arrester monitoring device. A monitoring system is also provided, including a gas insulated surge arrester connected to a surge arrester monitoring device.

A laminated varistor includes a varistor layer, a first internal electrode provided on an upper surface of the varistor layer, a second internal electrode provided on a lower surface of the varistor layer and facing the first internal electrode across the varistor layer in upward and downward directions, a first external electrode provided on a first side surface of the varistor layer and electrically connected to the first internal electrode, and a second external electrode provided on a second side surface of the varistor layer and electrically connected to the second internal electrode. The first internal electrode is extended from the first external electrode in a first extension direction. The first internal electrode includes first electrode strips arranged in a first arrangement direction perpendicular to the first extension direction and spaced apart from one another. This laminated varistor has improved surge-resistant characteristics.

A laminated varistor includes a varistor layer, a first internal electrode provided on an upper surface of the varistor layer, a second internal electrode provided on a lower surface of the varistor layer and facing the first internal electrode across the varistor layer in upward and downward directions, a first external electrode provided on a first side surface of the varistor layer and electrically connected to the first internal electrode, and a second external electrode provided on a second side surface of the varistor layer and electrically connected to the second internal electrode. The first internal electrode is extended from the first external electrode in a first extension direction. The first internal electrode includes first electrode strips arranged in a first arrangement direction perpendicular to the first extension direction and spaced apart from one another. This laminated varistor has improved surge-resistant characteristics.

A multilayer varistor includes a sintered body and a first internal electrode, a second internal electrode, a third internal electrode, and a fourth internal electrode which are disposed in the sintered body. The first internal electrode, the second internal electrode, the third internal electrode, and the fourth internal electrode are arranged in an order of the first internal electrode, the third internal electrode, the fourth internal electrode, and the second internal electrode from a side of a first main face. The third internal electrode and the fourth internal electrode are electrically connected to each other. At least part of the first internal electrode and at least part of the third internal electrode overlap each other when viewed in a third direction. At least part of the second internal electrode and at least part of the fourth internal electrode overlap each other when viewed in the third direction.

A multilayer varistor includes a sintered body and a first internal electrode, a second internal electrode, a third internal electrode, and a fourth internal electrode which are disposed in the sintered body. The first internal electrode, the second internal electrode, the third internal electrode, and the fourth internal electrode are arranged in an order of the first internal electrode, the third internal electrode, the fourth internal electrode, and the second internal electrode from a side of a first main face. The third internal electrode and the fourth internal electrode are electrically connected to each other. At least part of the first internal electrode and at least part of the third internal electrode overlap each other when viewed in a third direction. At least part of the second internal electrode and at least part of the fourth internal electrode overlap each other when viewed in the third direction.

A module for a fire-mitigating surge arrester includes: an inner arrester module including an electrically conductive assembly; a cartridge including a first end, a second end, a sidewall that extends between the first end and the second end, and an exhaust region in the sidewall, the sidewall surrounding the inner arrester module; a first electrical component in contact with a first end of the electrically conductive assembly and the first end of the cartridge; a second electrical component in contact with a second end of the electrically conductive assembly and the second end of the cartridge; and a reinforcement structure on the sidewall, the first electrical component, and the second electrical component.

The present invention relates to a polymer voltage-dependent resistor (PVDR) in various physical forms and methods for manufacturing the varistor. The body of the PVDR is composed of a polymer matrix having a filler composed of doped zinc oxide particles, other semi conductive particles or metal particles uniformly distributed therein. Conductive electrodes may be affixed to the polymer matrix and electrical leads attached to the electrodes.

A method for creating a dielectric thin-film coating for devices having a fusible element is disclosed. The method comprises mixing insoluble and soluble polymers in solid form and exposing the mixture to heat to create a melt mixture. The melt mixture is then dissolved in a solvent to create a slurry which can then be deposited on the device as a thin-film coating to create an interior insulation layer or an external surface.

Provided is a varistor assembly capable of achieving good surge breakdown voltage while suppressing capacitance. The varistor assembly is obtained by connecting a plurality of varistor elements in parallel. Each varistor element includes: a sintered body obtained by sintering a laminate in which varistor layers and internal electrodes are alternately laminated; and a pair of external electrodes provided in a state where the internal electrodes are alternately connected on at least both end faces of this sintered body. Varistor element includes at least a plurality of first group varistor elements in which a value obtained by dividing a surface area of the sintered body by a volume of the sintered body is 1.9 mm.sup.−1 or more.

Provided is an improved overvoltage protection element. The overvoltage protection devices comprises at least one ESD protection couple comprising discharge electrodes in a plane, a gap insulator between the discharge electrodes, an overvoltage protection element parallel to the planar discharge electrodes wherein the overvoltage protection element comprises a conductor and an secondary material. The overvoltage protection element also comprises a primary insulator layer between the discharge electrodes and overvoltage protection element.