RU81843U1 - VOLTAGE PROTECTION DEVICE - Google Patents

Abstract

The device for overvoltage protection contains varistors (1, 20), intermediate and end electrodes (2, 3, 4, 5, 22), varistor compression devices (spring 6, pressure screw 23) located in an internal detachable casing of two polymer insulation shells (7, 8) in the form of two halves of a diametrical longitudinal section of the cylinder, joined along the generatrix of the cylinder into a lock of the "protrusion-notch" type (28) with the application of a layer of adhesive-sealant. Two cylindrical parts are made at the end electrodes: one (37) passes into the holes in the end parts of the inner casing, and the second (38) has flats (39), mating with tides (34) along the inner diameter of the end parts of the polymer insulating shells (7, 8 ) Cylindrical grooves (11, 12) are made along the outer diameter of the end parts of the polymer insulating shells, mating with the flanges (9, 10), and seals (13, 14) are installed between the flanges and the end electrodes and a layer of adhesive-sealant is applied. In the junction planes of the end parts of the polymer insulating shells, cylindrical protrusions (31) are formed on one side and are included in blind holes (32) in the opposite polymer insulating shell. On the cylindrical surfaces of the polymer insulating shells, recesses are made (29). 6 c.p. f-ly, 8 ill.

Description

The utility model relates to the field of electrical engineering and is intended to protect the insulation of electrical equipment of high voltage AC and DC from atmospheric and switching overvoltages.

A device for surge protection is known (US patent No. 5652690 class. Н02Н 1/04; ННН 9/04, 1997), adopted as a prototype, containing a detachable inner casing in the form of two polymer insulating shells, representing two half of a diametrical longitudinal section a cylinder having end caps in the end parts with openings in the center for the passage of the output studs. Inside two polymer insulating shells are placed varistors containing zinc oxide, a compression spring, an intermediate electrode and end electrodes. A groove is made in the cylindrical part of the polymer insulating shells, which provides pressure relief when the device fails - breakdown of varistors. Both parts of the polymer insulating shells with the installed internal contents and the output studs are joined, and a longitudinal gap between them is formed at the joints, also for the pressure relief function. The joined parts are wrapped with glass tape and covered with an external insulating polymer casing with the formation of a system of ribs along the height of the casing. At the opposite ends of the device there are end caps-flanges clamped by nuts through washers and o-rings.

The disadvantage of the design, in which the inner casing is made detachable in the form of two polymer insulating shells, which are two halves of the diametrical longitudinal section of the cylinder, is its lack of mechanical strength when exposed

bending forces from straining wires and the effects of external conditions - wind and ice. Since the outer polymer casing is made, as a rule, of silicone rubber, which does not have sufficient bending stiffness under the influence of the mentioned forces, the mechanical strength of the structure during bending should be ensured by the inner casing. In this design, the inner casing is mechanically weakened by the presence of grooves and gaps at the junction of two polymer insulating shells, the absence of rigid bonds between two polymer insulating shells.

The objective of the proposed utility model is to increase the mechanical strength of the device for overvoltage protection under the influence of bending forces from wire tension and the influence of external conditions - wind and ice, as well as simplifying the assembly and eliminating the decrease in the reliability of the apparatus during assembly, simplification and cheapening of the structure.

The technical result is achieved in that in a device for overvoltage protection containing varistors, end and intermediate electrodes, a compression device for varistors enclosed in an inner casing, consisting of two polymer insulating shells, which are two halves of a diametrical longitudinal section of the cylinder with holes in the center end parts, as well as output studs and an external insulating casing made of tracking erosion-resistant polymer material, the connection at the junction of two polymer insulation of shells along the generatrices of the cylinder is made into a "protrusion-notch" type lock with a layer of adhesive-sealant applied to the mating surfaces, two types of cylindrical surfaces are made on the end electrodes, on one of them flats are mated with tides along the inner diameter of the end parts of the polymer insulating shells and the other is cylindrical

part of the end electrodes passes into the holes in the center of the cylinder, cylindrical grooves are made along the outer diameter of the end parts of the polymer insulating shells, mating with the flanges that are installed at the ends of the polymer insulating shells, and seals are installed between the end electrodes and flanges on the plane of the flanges adjoining the cylindrical and seals applied a layer of adhesive sealant.

The compression device of the varistors is made in the form of a spring.

The varistor compression device is made in the form of a pressure screw.

In the junction planes of the end parts of the polymer insulating shells, cylindrical protrusions are formed on one side, which enter blind holes in the opposite polymer insulating shell.

The inner diameter of the inner casing is made corresponding to the outer diameter of the varistors.

On the outer diameter of the varistors with a diameter smaller than the inner diameter of the inner casing, rings of elastic material are installed centering the varistors in the inner casing.

On the cylindrical surfaces of the polymer insulating shells, recesses are made.

The essence of the utility model is illustrated by the figures: figure 1 shows a device for surge protection with varistors corresponding to the inner diameter of the inner casing and the compression device of the varistors in the form of a spring; figure 2 - a device for surge protection with varistors having a diameter smaller than the inner diameter of the inner casing and the compression device of the varistors in the form of a pressure screw; figure 3 is a section aa of the device for surge protection in figure 1; figure 4 is a view of one of two polymer insulating shells; figure 5 is a view along arrow B of the polymer

insulating shell in figure 4; figure 6 is a section bb of the polymer insulating sheath in figure 4; Fig.7 is a cross section of the end electrode in the device for surge protection in Fig.1 with a compression device for varistors in the form of a spring; in Fig.8 is a view along arrow G of the end electrode in Fig.7.

The device for surge protection in figure 1 contains varistors 1, end electrodes 2 and 3, intermediate electrodes 4 and 5, a compression device for varistors 1 in the form of a spring 6, enclosed in an inner casing, consisting of two polymer insulating shells 7 and 8, inner the diameter of which corresponds to the outer diameter of the varistors 1. The polymer insulating shells 7 and 8 can be made, for example, by casting from glass-filled polyamide. Flanges 9 and 10 at the ends of the polymer insulating shells 7 and 8 are mated with their cylindrical grooves 11 and 12, and seals 13 and 14 are located between the flanges 9 and 10 and the end electrodes 2 and 3. The outer casing 15 is made, for example, of tracking resistant silicone rubber. The intermediate and end electrodes 2, 3, 4 and 5 are made of cast aluminum alloy, and the studs 16 and 17 are reinforced in the end electrodes 2 and 3. The final assembly of the device for overvoltage protection is carried out using nuts 18 and washers 19.

The device for overvoltage protection in figure 2 contains varistors 20, the outer diameter of which is smaller than the inner diameter of the inner casing of two polymer insulating shells 7 and 8. On the outer diameter of the varistors 20 there are rings 21 made of elastic material, for example, molded from silicone rubber. Rings 21 center the varistors 20 in the inner casing. Threaded holes are made in the end electrodes 22, and, on the one hand, a pressure screw 23 is screwed into the end electrode, abutting against the intermediate

the electrode 4, and on the other hand, the output pin 24 abuts the intermediate electrode 24. The output pin 25 abuts the pressure screw 23, fixing its position.

On the surfaces 26 and 27 of the flanges 9 and 10, facing the seals 13 and 14 and the cylindrical grooves 11 and 12 (FIGS. 1 and 2), a layer of adhesive-sealant is applied.

In section AA (Fig. 3), the device for surge protection in Fig. 1 shows the connection to the lock 28 of the "protrusion-notch" type of two polymer insulating shells 7 and 8, and a layer of adhesive-sealant is applied on the surface of the joints. The recesses 29 are made on the cylindrical surfaces, reducing the thickness of the cylindrical wall of the polymer insulating shells so that in case of failure of the device (breakdown of the varistors), the internal pressure can destroy the thinned wall, thereby relieving pressure.

Features of the design of the polymer insulating shell are shown in FIGS. 4, 5 and 6. In the end parts of the polymer insulating shell, cylindrical surfaces 30 are made, forming a hole during assembly of two shells, and cylindrical protrusions 31 and blind holes 32 are made in the joint plane. On the surface 33 adjacent to the cylindrical surface 30, tides 34 are made. On one side, a protrusion 35 is made in the joint plane of the cylindrical part of the polymer insulating sheath, and on the other hand, a recess 36, an image guides in the assembly 28 locking the two shells.

The end electrodes, an example of which is shown in Figs. 7 and 8, comprise a cylindrical surface 37 which, when assembled with polymer insulating shells 7 and 8, fits into an opening formed by cylindrical surfaces 30. On a cylindrical surface

38 of the end electrode, two flats 39 are made, mating during assembly with tides 34.

The assembly of the overvoltage protection device shown in Fig. 1 begins with the installation of varistors 1, intermediate electrodes 4 and 5, end electrodes 2 and 3 with compression spring 6 in the same polymer insulating sheath. The arrangement of all these elements is accessible for viewing and control when assembly. The surfaces of the protrusions 35 and the recesses 36 (FIG. 6) of the joint of the cylindrical part of both polymer insulating shells 7 and 8 are smeared with glue-sealant and the shells are docked, while in the end parts of the shells the cylindrical protrusions 31 go into the blind holes 32, fixing their relative position, thus forming an inner casing closed in the circumferential direction. Additional alignment of the varistors 1 in the casing is not required, since the outer diameter of the varistors corresponds to the inner diameter of the casing. The cylindrical surface 37 (Fig. 7) of the end electrodes 2 and 3 is located in the hole formed by the cylindrical surfaces 30 of the polymer insulating shells, and the flats 39 of the surface 38 of the end electrodes mate with tides 34 on the surface 33 of the polymer insulating shells. Seals 13 and 14 are installed, on flanges 9 and 10, surfaces 26 and 27 are covered with a layer of adhesive-sealant, and flanges 9 and 10 are installed on the ends of the polymer insulating shells 7 and 8, covering their cylindrical grooves 11 and 12. The assembly of the inner casing with its contents is completed by tightening the nuts 18 on the studs 16 and 18 with the installation of washers 19. As a result, the end parts of the inner casing, consisting of polymer insulating shells 7 and 8, after assembly with flanges 9 and 10 become solid, since the end parts are polymer x insulating shells mate with the cylindrical portion 37 of the end electrodes and on the outer

the cylindrical groove 11 and 12, the polymer insulating shells cover the flanges 9 and 10. The final assembly step is to cover the inner casing with the outer casing 15 with ribs along the length of the casing.

The assembly of the surge protection device shown in figure 2 is slightly different from the previously described. In particular, on varistors 20, the outer diameter of which is smaller than the inner diameter of the inner casing, rings 21 are made of elastic material, and after installing the flanges 9 and 10 in the end electrodes 22 having threaded holes, a stud 24 is screwed on one side and on the other hand the pressure screw 23 is screwed in tightly, providing compression and tight contact of the varistors 20 and electrodes 4. The end electrodes 22 also have cylindrical surfaces 37 and flat surfaces 38, as well as the end electrodes 2 and 3. After screwing the spire ki 25 and nuts 18 with washers 19 we get the same, as previously described, monolithic design of the inner casing.

The monolithic inner casing of the device for overvoltage protection has increased mechanical strength when exposed to bending forces from wire pulling and the influence of external climatic conditions - wind and ice. The installation of the main elements of the device for surge protection, which determine the operability and reliability of the apparatus, performed in one polymer insulating shell, is accessible to visual and instrumental control, which simplifies and reduces the cost of assembly and increases the reliability of the apparatus as a whole.

Claims (7)

1. An overvoltage protection device comprising varistors, end and intermediate electrodes, a varistor compression device enclosed in an inner casing, consisting of two polymer insulating shells, which are two halves of a diametrical longitudinal section of a cylinder with holes in the center at the end parts, and output studs and an external insulating casing made of tracking erosion-resistant polymer material, characterized in that the connection at the junction of two polymer insulating shells in the image the cylinder is made into a "protrusion-notch" type lock with a layer of adhesive-sealant applied to the mating surfaces, two types of cylindrical surfaces are made on the end electrodes, one of them is made of flats mating with tides along the inner diameter of the end parts of the polymer insulating shells, and another cylindrical part of the end electrodes extends into the holes in the center of the cylinder; cylindrical grooves mating with the flanges are made along the outer diameter of the end parts of the polymer insulating shells Which are mounted at the ends of polymeric insulating shells and between the end electrodes and the sealing flanges and mounted on the plane abutment of the flanges to the cylindrical bore and seals a layer of sealant adhesive. 2. The device for surge protection according to claim 1, characterized in that the compression device of the varistors is made in the form of a spring. 3. The device for surge protection according to claim 1, characterized in that the varistor compression device is made in the form of a pressure screw. 4. The device for overvoltage protection according to claim 1, characterized in that in the junction planes of the end parts of the polymer insulating shells, cylindrical protrusions are formed on one side and enter into blind holes in the opposite polymer insulating shell. 5. The device for surge protection according to claim 1, characterized in that the inner diameter of the inner casing is made corresponding to the outer diameter of the varistors. 6. The device for surge protection according to claim 1, characterized in that on the outer diameter of the varistors with a diameter smaller than the inner diameter of the inner casing, rings of elastic material are installed, centering the varistors in the inner casing. 7. The device for surge protection according to claim 1, characterized in that recesses are made on the cylindrical surfaces of the polymer insulating shells.