RU2423752C1 - Gas-filled discharger - Google Patents

Abstract

FIELD: electricity. ^ SUBSTANCE: discharger shell consists of a metal body in the form of a cylindrical sleeve with flanging and an insulator installed in it in the form of a truncated cone with side cylindrical surface in its lower part. On the inner surface of the lower part of the metal body there is a collar that follows the shape of this surface to form a ledge, where there is a base of the lower part of the insulator, the side cylindrical surface of which is connected with the inner surface of the upper part of the collar by a sealing seam. The lower parts of the collar and the metal body are connected to each other by means of, for instance, argon-arc welding, as a result of the fact that on the inner surface of the body at the level of the upper border of insulator connection with the collar there is an additional ledge, and the upper part of the collar higher than the upper border of its connection with the insulator has a bulge protruding beyond the outer surface of the collar above the additional ledge. The collar bulge is equal to the width of the additional ledge and is arranged with rounded edges inverted inside the cavity formed by the body and the insulator. ^ EFFECT: increased mechanical and electric strength and stability of dynamic voltage of discharger breakthrough, and its agreement with a load at coaxial connection. ^ 1 dwg

Description

The invention relates to gas-discharge equipment and can be used to create gas-discharge devices, for example, gas-discharge spark arresters with high mechanical and electric strength.

Known gas-filled spark gap, containing a shell consisting of an insulator in the form of a hollow truncated cone and a metal body formed by a flanging cylinder and a cap screwed into it, welded at the junction, a cathode mounted on the inner surface of the cap, an anode located on the end surface of a smaller the base of the insulator connected by welding another base to the flanging of the cylinder [High-voltage surge arresters / Yu.V. Kiselev, B. P. Merkulov / - Electronic Technology. Series 4. Electrovacuum and gas-discharge devices. Issue 2 (79) / 1980, p. 37].

The rigidity of the design of such arresters is ensured due to the fact that the insulator, made in the form of a truncated cone, whose convex surface faces the inside of the arrester, experiences compression forces, while the insulator rests directly on the inner flanging of the metal case. The vacuum density of the arresters from the side of the junction of the insulator with the metal casing is carried out by an enveloping cylindrical junction. Such a junction of an insulator with a metal casing is possible with relatively small geometrical dimensions of the soldered parts (the diameter of the parts is not more than 50 mm), since with an increase in their sizes due to the large difference in the thermal expansion of the soldered parts at the soldering temperature, a large gap arises, which reduces the quality of the joint, and when the wall thickness of the metal case is much more than 1 mm after soldering in the insulator mass in the immediate vicinity of the junction, compressive forces arise, leading to its destruction.

Thus, the disadvantage of this arrester is the low mechanical strength when using a metal case with a wall thickness of more than 1 mm.

Known gas-filled spark gap containing a shell consisting of a metal body in the form of a cylindrical glass with flanging and placed in it an insulator in the form of a hollow truncated cone with a lateral cylindrical surface in its lower part, two electrodes, one of which is fixed to the inner surface of the bottom of the cylindrical glass, and the second - on the surface of the smaller base of the insulator, inside of which passes the axial output of the second electrode, a cuff located on the inside of the lower part of the metal about the housing and connected to the base of the lower part of the insulator [Copyright certificate No. 932578, H01J 17 / 02.1982]

This gas-filled spark gap differs from the previous ones in that in order to increase its mechanical strength and reliability by eliminating bending forces in the joint, a node consisting of a transition ring and a cuff is placed between the inner surface of the metal case and the end surface of the lower part of the insulator, the transition ring being connected with a metal case, and the cuff - with the end surface of the lower part of the insulator. The junction design can withstand high excess pressure (tens of atmospheres) with large geometric dimensions. Excessive pressure of the filling gas in this design causes compressive forces in the joint, since the force is transmitted to the insulator through the compensating ring and the adapter ring to the inner flange of the metal casing.

The disadvantage of the arrester is the limitation of the space between the axial output of the electrode located on the insulator and the metal housing of the arrester, which reduces the electric strength of the arrester between the axial output of the second electrode and the metal housing, and creates an inhomogeneity of the electric field when the load is coaxially connected.

Closest to the proposed invention is a gas-filled surge arrester containing a shell consisting of a metal housing in the form of a cylindrical cup with a flanging and an insulator placed in it in the form of a hollow truncated cone with a side cylindrical surface in its lower part, two electrodes, one of which is fixed to the inside the bottom surface of the cylindrical cup, and the second on the end surface of the smaller base of the insulator, inside which passes the axial output of the second electrode, the cuff, located female on the inner surface of the lower part of the metal case, repeating its shape with the formation of a ledge in which the base of the lower part of the insulator is installed, the lateral cylindrical surface of which is connected to the inner surface of the upper part of the cuff by a sealing seam, and the lower parts of the cuff and the metal case are connected to each other, for example, argon-arc welding [RF Patent No. 2321097, H01J 17/02, H01T 1/00, 2008 - prototype]

The disadvantage of this arrester is the low stability of the dynamic breakdown voltage and the limited service life caused by the presence of an electric field strength concentrator. The emergence of a concentrator of electric field strength is due to the fact that during argon-arc welding of the lower part of the cuff with the housing, a gap is formed between them, the size of which increases to one side of this connection, while the thickness of the cuff welded to the ceramic has a size of less than 1 mm. The electric field concentrator on the sharp edge of the cuff near the point with the maximum gap between the cuff and the inner surface of the casing is a source of preliminary ionization that is not tied in level and time. This means that this ionization source is a destabilizing factor in the operation of the arrester. In addition, the appearance of a concentrator near the point of the sharp edge of the cuff at the point of maximum clearance with the housing introduces an asymmetry of the electric field in the internal volume of the arrester. A one-sided corona discharge from the cuff edge displaces the main discharge between the electrodes to the boundary of its working surfaces and leads to a strong deposition of erosion products on that part of the insulator surface that faces the pulsed corona source, which leads to a decrease in the insulator's electrical strength and a decrease in the spark gap durability.

The objective of the invention is to create a gas-filled spark gap with high electrical strength and stability of dynamic breakdown voltage, while ensuring consistency with the load during coaxial switching.

This goal is achieved by the fact that in the known gas-filled spark gap containing a shell consisting of a metal housing in the form of a cylindrical cup with a flange and an insulator placed in it in the form of a hollow truncated cone with a side cylindrical surface in its lower part, two electrodes, one of which is fixed on the inner surface of the bottom of the cylindrical glass, and the second on the end surface of the smaller base of the insulator, inside which passes the axial output of the second electrode, the cuff located on the inner surface of the lower part of the metal case, repeating its shape with the formation of a ledge in which the base of the lower part of the insulator is installed, the lateral cylindrical surface of which is connected to the inner surface of the upper part of the cuff by a sealing seam, and the lower parts of the cuff and the metal case are connected to each other, for example , by argon-arc welding, an additional step is made on the inner surface of the housing at the level of the upper boundary of the connection between the insulator and the cuff, and the upper part of the cuff Above the upper boundary of its connection with the insulator, there is a thickening protruding beyond the outer surface of the cuff above the additional ledge, and the thickening of the cuff is equal to the width of the additional ledge and is made with rounded edges facing the cavity formed by the housing and the insulator.

In the proposed design of the arrester, the upper part of the cuff above the upper boundary of its connection with the insulator covering the layer has a thickening with rounded edges facing the inside of the arrester, located above an additional ledge with a width equal to the thickness of the cuff. This design of the connection of the cuff and the housing significantly reduces the electric field near the point of the upper part of the cuff, which has a maximum clearance with the housing, and practically does not affect the distribution of the electric field in the space of the arrester. In this case, the deposition of erosion products is uniform over the entire surface of the insulator, which increases the electric strength of the arrester and durability in a given operating mode.

The analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information, and the identification of sources containing information about analogues of the claimed invention, allows us to establish that the applicant has not found an analogue characterized by features identical to those of the claimed invention, and the definition from the list of identified analogues of the prototype, as the closest in the totality of the features of the analogue, allowed to identify the set of essential in relation to the applicant to technical result of the characterizing features claimed in the object set forth in the claims.

Therefore, the claimed invention meets the requirement of "novelty."

To verify the conformity of the claimed invention to the requirements of the inventive step, an additional search was carried out for known solutions in order to identify features that match the distinctive features of the claimed invention, the results of which show that the claimed invention does not explicitly follow from the prior art, as it has not been identified technical solutions to increase the electric strength and stability of the dynamic breakdown voltage, as well as ensure the condition for matching the spark gap with the coaxially switched load of gas-filled arresters containing a shell consisting of a metal body in the form of a cylindrical cup with a flanging and an insulator placed in it in the form of a hollow truncated cone with a side cylindrical surface in its lower part, two electrodes, one of which is fixed on the inner surface of the bottom of the cylindrical glass, and the second on the end surface of the smaller base of the insulator, inside which passes the axial output of the second a cuff located on the inner surface of the lower part of the metal casing, repeating its shape with the formation of a ledge, in which the base of the lower part of the insulator is installed, the lateral cylindrical surface of which is connected to the inner surface of the upper part of the cuff by a sealing seam, and the lower parts of the cuff and the metal case are connected with each other, for example, by argon-arc welding, by completing the connection between the insulator and the cuff on the inner surface of the housing nogo ledge, and on top of the cuff above the upper limit of its connection to the insulator thickening projecting beyond the outer surface of the cuff over the additional shoulder, wherein the thickening equal to the width of the cuff further ledge and formed with rounded edges facing inside the cavity formed by the housing and the insulator.

Therefore, the claimed invention meets the requirement of "inventive step".

The claimed invention is illustrated in the drawing, which shows one of the options for the proposed gas-filled spark gap in the context.

The gas-filled spark gap contains a metal housing 1 in the form of a cylindrical cup with a flanging, an insulator 2 in the form of a hollow truncated cone having a lateral cylindrical surface in its lower part, the convex surface of the insulator 2 facing the inside of the metal housing 1, the electrodes anode 3 mounted on the inside the bottom surface of the metal housing 1, and the cathode 4, located on the end surface of the smaller base of the insulator 2, the cuff 5, located on the inner surface of the lower part of the metal housing 1, repeating the shape of this surface with the formation of a ledge 6, in which the base of the lower part of the insulator 2 is installed, while the cuff 5 is connected by its lower part to the metal housing 1 by a seam 7, made, for example, by argon-arc welding, and the inner surface is connected to a lateral cylindrical surface of the insulator 2 with a sealing seam 8, formed, for example, by soldering with silver-containing solder, an additional step 9 made on the inner surface of the housing 1 at the level of the upper boundary of the connection from insulator 2 and the cuff 5, the upper part of which is provided with a thickening 10 having rounded edges, facing inside the cavity formed by the housing 1 and the insulator 2, and the thickening 10 of the cuff 5 is disposed on an additional shoulder 9, whose width is equal to the thickening 10.

The gas-filled spark gap operates as follows.

A pulse voltage is applied between the anode 3 and the cathode 4, the amplitude of which increases with time. Upon reaching a voltage equal to the breakdown voltage, the arrester breaks through and a current pulse arises in the load, the magnitude and shape of which is determined by the parameters of the discharge circuit and the magnitude of the breakdown voltage of the arrester.

The use of the present invention made it possible to create a mechanically strong and reliable gas-filled spark gap-sharpener RO-50 with a dynamic breakdown voltage of 250 kV at a filling gas pressure of about 80 atmospheres and fully coordinated with the load during coaxial switching. The relative rms spread of the dynamic breakdown voltage of the arrester-sharpener RO-50 does not exceed 1%, and the arrester-sharpener, made according to the design of the prototype, amounted to 3%. Life tests of these arresters have confirmed the significant advantage of the arrester of the claimed design. The resource RO-50 amounted to 10 ⁷ breakdowns, which significantly exceeds the resource of the arrester-sharpener, taken as a prototype, amounting to 3 · 10 ⁶ breakdowns.

Such arresters will find wide application in X-ray inspection of metal structures and in the development of subnanosecond pulse generators.

Claims (1)

A gas-filled spark gap containing a shell consisting of a metal housing in the form of a cylindrical cup with a flanging and an insulator placed in it in the form of a hollow truncated cone with a side cylindrical surface in its lower part, two electrodes, one of which is fixed to the inner surface of the bottom of the cylindrical cup, and the second - on the end surface of the smaller base of the insulator, inside which passes the axial output of the second electrode, a cuff located on the inner surface of the lower part of the metal repeating its shape with the formation of a ledge in which the base of the lower part of the insulator is installed, the lateral cylindrical surface of which is connected to the inner surface of the upper part of the cuff by a sealing seam, and the lower parts of the cuff and the metal case are connected to each other, for example, by argon-arc welding characterized in that on the inner surface of the housing at the level of the upper boundary of the junction of the insulator with the cuff, an additional step is made, and the upper part of the cuff is higher than the upper boundary of its connection The system with the insulator has a thickening protruding beyond the outer surface of the cuff above the additional ledge, and the thickening of the cuff is equal to the width of the additional ledge and is made with rounded edges facing the cavity formed by the housing and the insulator.