Abstract: A surge protector includes a body having an outer surface, and a clamp snapped on the body. The clamp includes spring clips. The spring clips have at least two support areas that are in a substantially same plane. The surge protector may also include a center electrode and terminal electrodes on ends of the body.

Abstract: An electrical component includes a base object made of two insulating objects with curved external surfaces, and external electrodes. Each of the external electrodes is disposed adjacent to one of the two insulating objects. A central electrode is disposed inside of the base object. The central electrode includes a flat mounting surface on an exterior of the component.

Abstract: A surge protector includes a body having an outer surface, and a clamp snapped on the body. The clamp includes spring clips. The spring clips have at least two support areas that are in a substantially same plane. The surge protector may also include a center electrode and terminal electrodes on ends of the body.

Abstract: A protective element safely dissipates overvoltages which is comprised of a parallel connection of a varistor and an surge arrester. To reduce the capacity of the protective element, the varistor is fashioned as a disc and arranged between a contact pins and the surge arrester. An electrical isolation between contact pin and varistor is ensured by an electrically isolated spacer, in which openings for electrical contact elements are provided to connect the varistor with the cup and the contact pin with the surge arrester. The surge arrester and the spacer are preferably fit positively into the cup.

Abstract: The invention relates to a spring clip (17) having a clamping device (1) by means of which the spring clip (17) can be clamped from one side of a surge diverter (2) onto the latter, having at least one spring arm (3), having a thermal protective device (4) attached to the inside of the spring arm (3), and containing a fusible element (5). By attaching the thermal protective device (4) to the spring clip (17), a low melting temperature can be chosen for the fusible element (5). The invention also relates to a surge diverter array (2) with the spring clip (17). Furthermore, the invention relates to a method for manufacturing the array.

Abstract: The invention relates to an electrical component with a base object (3), which comprises two insulating objects (1 and 2) with curved external surfaces, each having an external electrode (4 and 5) disposed on its face, in which a central electrode (7) is disposed along a shell surface in a central section (6) of the base object, and in which the central electrode (7) features a flat mounting surface (8) on the exterior of the component. The invention also relates to an arrangement of the component. Furthermore, the invention relates to a method for manufacturing the arrangement. Because of the flat mounting surface (8) on the central electrode (7), the component can be effectively prevented from rolling away from the surface of a printed circuit board (10). In addition, the holding surface (9) permits the suction holding of the component using a suction nozzle (11).

Abstract: In order to simplify the mountability of electrode terminals in the form of band-like clips on either two-electrode or three-electrode arresters, the clips are resiliently fashioned in a circumferential direction. When such a clip axially projects beyond a foot part of the respective end electrode, the projecting region in a three-electrode arrester can be part of a short-circuit device which electrically connects to the middle electrode, potentially in combination with an auxiliary discharge path.

Abstract: A protective element safely dissipates overvoltages which is comprised of a parallel connection of a varistor and an surge arrester. To reduce the capacity of the protective element, the varistor is fashioned as a disc and arranged between a contact pin and the surge arrester. An electrical isolation between contact pin and varistor is ensured by an electrically isolated spacer, in which openings for electrical contact elements are provided to connect the varistor with the cup and the contact pin with the surge arrester. The surge arrester and the spacer are preferably fit positively into the cup.

Abstract: In order to be able to produce an electrically conductive, positive connection between an end electrode of a gas-filled discharge path and a lead more simply in fabrication-oriented terms, the raised terminal region, which is provided at the end electrode, is provided with a blind hole into which the one end of the lead is introduced and joined thereat to the terminal region with a laser welding.

Abstract: A resilient bracket, in the form of an open ring that is placed on the insulator between the two electrodes and whose one end, having two side bars shaped at the sides, forms the short-circuiting link, serves as a device for the external short-circuiting of two electrodes of a gas-filled surge arrester. A spacer, which is made of a material that can be melted and which is inserted between the short-circuiting link and the insulator, holds the side bars at a radial distance from the electrodes. A surge arrester of this sort is suited in particular for arrangement in cartridges for the acceptance of a multiplicity of arresters.

Abstract: In order to give an external short-circuit device of a surge voltage protector a current carrying capacity that is as large as possible, a device is made up of a two-armed flexible short-circuit clip whose contact regions are arranged axially to end electrodes. The contact region is formed by two brackets that release a center region of the respective end electrode, and that stand opposite an edge region. An insulating spacer is arranged between a common base of the contact brackets and the edge region of the respective.

Abstract: A gas-filled surge arrester includes at least two electrodes, a hydrogen-containing gas filling and an activating compound applied to at least one of the electrodes. In order to ensure the required operating behavior of the surge arrester even at temperatures to 40%, the activating compound contains nickel powder in an amount of 30 to 35% by weight and potassium silicate in an amount of 25 to 30% by weight as basic components, sodium bromide in an amount of 15 to 20% by weight, as well as aluminum powder, sodium silicate and barium titanate as further components each in an amount of 5 to 10% by weight.

Abstract: In a gas-filled overvoltage diverter, the electrodes are coated with an activation compound and are located on an insulator. At least one axial ignition strip is disposed on the inner surface of the insulator. The inner surface of the insulator also has an ionization source in the form of a coating of an electroluminescent material. The coating is connected to both electrodes and may take the form of a strip. Alternatively, the coating may cover the entire inner surface of the insulator. The alkali halide and/or alkaline-earth halide coating material may also contain dielectric or ferro-electric crystals.

Abstract: To adapt a three-electrode arrester having copper electrodes to high switching capacities (200 Amp a.c. current per discharge gap simultaneously for 11 cycles at 60 Hz), the following measures are provided: The cylindrical end electrodes have a volume of at least 60 mm.sup.3, given a ratio of length (L.sub.2) to diameter (D.sub.2) of less than 2.5; the middle electrode has the shape of a hollow cylinder with end regions of a reduced wall thickness; the middle electrode and the hollow cylindrical insulators are soldered to one another at the front ends.

Abstract: In order to guarantee that the gas atmosphere of the structure of an encapsulated spark gap (9) is reliably protected from the effect of moisture, two flat discharge surfaces of two dish-type electrodes (1,6), each designed with a collar-shaped rim (2), abut on both sides of a thin insulating layer (4) having punched holes. A tubular glass insulator (3) is sealed on the front side into the collar-shaped rims of the two electrodes. During the course of their manufacturing, the electrodes are placed with their collar-shaped rim on the front sides of the glass insulator, are inductively heated and, under the action of an axially directed pressing force, are driven toward one another and pressed against the insulating layer. A spark gap of this type can be used as a secondary discharge gap for triple-electrode arresters.

Abstract: A gas-filled three-electrode overvoltage arrester may be developed in such a manner that it has dependable "fail-safe" and "vent-safe" behavior. For this purpose, a two-arm spring clip (10) is fastened to the center electrode (1). The ends of the two-arm spring clip (10) rest, with the interpositioning of a spacer (20, 21; 22, 23), against the ends of the end electrodes (2, 3). The end of each arm of the spring clip bears a cap (14, 15) which is provided with a flange-like edge (16, 17). One end of the connecting wire (6, 7) of each end electrode has the shape of a ring (61, 71) which is fastened at the end side to the end electrode. The ring of the connecting wire and the flange-like edge of the cap are opposite each other and are held apart by a disk-shaped fusible pellet (20, 22) and a cylindrical part (21, 23) having insulating properties. The cylindrical part consists either of a temperature-resistant insulating material or of a metal-oxide varistor.

Abstract: As a known "back-up device" for a gas-filled over-voltage arrester, a voltage-dependent resistor (6) is arranged centrally in a housing with the over-voltage arrester (1). The varistor (6) can, in this connection, be sealed with a moisture-repelling substance and it is arranged concentrically to a connecting pin (5) of the over-voltage arrester. By means of an auxiliary electrode (8) of annular disk shape placed on the varistor (6), an air gap (13) from the connecting pin (5) can be formed. The varistor, after its response, can be short-circuited via this air gap.

Abstract: A triggerable switching spark gap has two main electrodes, which are insulated from each other, and a galvanically controllable trigger electrode, which is configured in the center of a circular opening of one main electrode. A clearance (a) between the two main electrodes is greater by the factor 1.1 to 2.3, preferably by the factor 1.4 to 1.7, than the width (b) of the ring gap between the trigger electrode and the corresponding main electrode. Furthermore, the circumferential edge of the trigger electrode (6) arranged to be flush with the discharge surface of the corresponding main electrode has a radius of curvature less than or equal to 0.1 mm and the trigger electrode and the corresponding main electrode are coated with a silver-containing activating mass. The delay time of the switching spark gap is able to be reduced to values less than or equal to 0.5 .mu.s.

Abstract: Overvoltage arrester having a gas-filled housing wherein, spaced from one another by a tubular insulator, cylindrical electrodes ending frustoconically are disposed opposite one another and are formed, in a region of active surfaces thereof, with walls that are thicker than conical side walls thereof located in a region of transition to the insulator, at least one line of electrically conductive material being disposed at the inner surface of the tubular insulator and extending as an ignition line in direction from the one cylindrical electrode to the other, the electrodes and the insulator being receivable in a metallic sleeve acting as a socket at ground potential and having a movable surrounding cage, including a metallic sleeve for receiving the electrodes and the insulator, the sleeve serving as a socket and having a movable cage substantially concentrically and closely surrounding the electrodes and the insulator, one of the electrodes being a wire or pin electrode and the other electrode being a hollow

Abstract: Overvoltage arrester having a gas-filled housing, including two overvoltage arrester electrodes disposed across from each other in the housing, a tubular insulator body spacing the overvoltage arrester electrodes apart from each other, a ring-shaped flange integral with one of the overvoltage arrester electrodes forming a first spark gap electrode, a ring-shaped metal cap forming a second spark gap electrode being superimposed on the first spark gap electrode and pressed in on the tubular insulator body, the first and second spark gap electrodes forming a spark gap having a given clearance therebetween, and a contact spring connecting the second spark gap electrode to the other of the overvoltage arrester electrodes.