RU2703989C2 - Electric disconnector - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: electric disconnector is presented. In the disconnector housing there are fixed contacts closed/opened by the movable contact. Membrane, by means of which movable contact is connected to housing, divides housing volume into upper and lower volumes filled with gas under different pressures. For fast disconnection of fixed contacts on the housing there is a valve with an electromagnetic drive and a shutter made using material with high electric conductivity.

EFFECT: fast disengagement of fixed contacts.

11 cl, 2 dwg

Description

FIELD OF THE INVENTION

The present invention relates to electrical engineering, in particular, to switching equipment, and can be used in DC circuits, for example, in power systems of various electrophysical installations.

State of the art

In some cases, for the most part related to production or research purposes, switching of electric circuits is required, in which currents of tens of thousands of amperes flow. In particular, it can be the power supply circuits of electric windings forming superstrong magnetic fields.

The handling of powerful sources of electricity requires high-speed switching equipment to minimize the energy released in the electric arc, and to provide the ability to quickly turn on / off the current in the electric circuit. In addition, very serious requirements are imposed on such switching equipment for the transition resistance of the contact group, reliability, the ability to switch with overload in terms of power and service life.

From the copyright certificate SU 1559956, a high-current switching device is known, which provides quick circuit closure, containing two fixed contacts, a movable bridge contact and an electromagnetic (induction-dynamic) drive with an armature and a coil, located in an insulating casing. The drive armature, which rests on the housing cover, is made in the form of a disk with a cylindrical protrusion from the side of the coil. The perimeter anchor is hermetically connected to the casing of the device using an additionally introduced annular membrane, and the casing is made with two holes for supplying compressed gas located on opposite sides of the specified membrane, and with a throttle hole located on the cover of the casing.

On the drive arm, on the other hand, said movable contact is made in the form of a ring, and fixed contacts are made in the form of coaxial rings mounted coaxially with said movable contact. On fixed contacts coaxial to each other additionally installed interacting with the armature contact elements. The contact group of the anchor is made in the form of elastic lamellas, based on additionally introduced annular dampers.

The closure of such a switching apparatus is performed under the action of electrodynamic forces and pressure of the compressed gas, and the disconnection occurs after the pressure is released from the volume above the membrane. As soon as the pressure in this volume becomes less than the pressure in the volume under the membrane, the drive armature with the movable contact mounted on it rises, the movable contact departs from the fixed contacts and the circuit opens. Bringing the switching apparatus into working condition is carried out by introducing gas under the working pressure into the volume above the membrane.

The disadvantage of the design of the switching apparatus disclosed in SU 1559956 is that it is intended solely for closing the electric circuit and does not allow to quickly disconnect the fixed contacts and create a gap in the electric circuit. However, the rapid opening of the disconnector contacts in the electrical circuit is necessary to perform both protective and operational tasks in electrophysical installations.

Disclosure of invention

The objective of the present invention is to reduce the time of separation of the electric circuit by a high-current switching device.

This problem is solved using a disconnector having two fixed contacts separated by an insulator, and a movable contact made with the possibility of closing / opening fixed contacts. The movable contact is attached by means of a membrane to the side walls having a mechanical connection with at least one fixed contact, the movable contact and the membrane sharing the volume between the side walls of the disconnector into the lower volume in which the fixed contacts are located and the upper volume.

A distinctive feature of the present invention is that it contains an electromagnetic valve that is installed with the possibility of rapid release of gas from the upper volume and includes a valve body, a valve made using non-magnetic material with high electrical conductivity, and an inductor coil.

The elements of the disconnector mainly have axial symmetry and are aligned. In addition, in a preferred embodiment, the disconnector elements are in the form of cylinders, circles or sectors. The disconnector may include a silencer passing gas from the upper chamber, installed in order to reduce the acoustic shock that occurs when the gas flows.

In a preferred embodiment, the valve comprises a partition adjacent to the upper volume and having one or more holes, the total area of which is not less than the area of the valve outlet. The direction of movement of the shutter is preferably perpendicular to the plane in which the membrane is located. Above and / or below the membrane are predominantly rigid elements that limit the movement of the membrane.

The objective of the present invention is also solved by using an electric circuit, which includes a disconnector according to any of the above options. In an advantageous embodiment, the circuit comprises a switch installed in series with the high voltage disconnector.

The technical result of the present invention is to reduce the time of disconnection of a switched circuit by a high-current switching apparatus and to ensure high electrical strength of the open section with small overall dimensions.

Brief Description of the Drawings

In FIG. 1 is a sectional view of an electric disconnector.

In FIG. 2 shows an enlarged view of a contact group of a disconnector.

The implementation of the invention

An embodiment of the present invention is illustrated with reference to FIG. 1, which shows an advantageous embodiment of an electric disconnector. In the shown preferred embodiment, the disconnector elements have axial symmetry and are aligned. In addition, the elements of the disconnector are preferably made in the form of cylinders, circles or sectors. These preferred features are aimed at providing the mechanical strength required when handling strong currents, high voltages and high pressures. It should be borne in mind that the present invention can be implemented in other configurations. In this regard, the present description is not limiting and is given only for the purpose of explaining the invention. The scope of protection sought is determined by the claims.

In FIG. 1 shows a sectional example of an electric disconnector. The disconnector has fixed contacts 3 and 4, separated by a lower dielectric element (insulator) 1, the upper dielectric element 2 in the form of a side wall with a movable contact installed in it, a baffle 20 and a valve body passing into the muffler 24.

On the fixed contacts 3 and 4, removable contact elements 5 and 6 are installed, respectively. The movable contact attached to the upper dielectric element 2 using the membrane 16, is made in the form of a support disk 11 with a clip 15 mounted on its lower surface (shown in Fig. 2), containing a contact ring-shaped element 13.

The disconnector is connected to an external electrical circuit through fixed contacts 3 and 4.

Thanks to this configuration, it is possible to reduce the size of the disconnector while providing a large area of contact surfaces required when large currents flow.

The contact annular element 13 in the embodiment shown in FIG. 1 is made of separate independent lamellas mounted in a cage 15 fixed to the supporting disk 11. In FIG. 2 shows that inside the cage 15, elastic elements 14 are mounted on the slats of the movable contact element 13, and the membrane 16 is fixed between the support disk 11 and the cage 15 on one side and between the partition 20 and the dielectric element 2 on the other side.

Fixed removable contact elements 5 and 6 are provided with cooling channels 10. In order to reduce contact resistance, plates 19 made of a material with high electrical conductivity and low hardness are attached to the contact surfaces of the movable 13 and / or fixed 5.6 contact elements (Fig. 2 shows plates 19 attached to both movable and fixed contact elements).

As shown in FIG. 1, the support disk 11 and the movable contact membrane 16 hermetically divide the internal cavity of the apparatus into lower 18 and upper 17 volumes. The membrane material must provide the ability to move the movable contact under the influence of the pressure difference.

In FIG. 2 shows that on top and bottom of the membrane (in some cases, it can only be on top or only on the bottom) there are rigid elements 21 and 22 that limit the movement of the membrane. In an advantageous embodiment, these are metal rings, which can, for example, be made with cuts. They are designed to limit the movement of the membrane and, thus, to protect the membrane from rupture, which allows the membrane to be made using an elastic material (e.g. rubber). In addition, these metal rings prevent the movable contact from moving in the direction transverse to the axial, so that the movable contact can only move along the axis (in this case, up and down), which makes it possible to center the contact elements and reduce the resistance and increase the life of the device.

At least one opening is made in the baffle 20, through which the gas located between the baffle 20 and the movable contact can escape into the atmosphere when the electrodynamic valve is opened. The valve provides sealing of the upper volume 17 in the closed state and a quick exit of gas when opening. The valve consists of an inductor coil 7, a cylindrical movable shutter 8, which slides along a guide in the valve body, which passes into the muffler 24, and an annular sealing collar 23, which prevents gas leakage into the atmosphere from the upper volume 17 when the shutter 8 is lowered.

The lower volume 18 is filled with compressed gas at a pressure of the order of several atmospheres, the upper volume 17 is filled with compressed gas at a pressure mainly of 1.5-2 times the pressure in the lower volume 18. If there is pressure in both volumes, the movable contact due to the pressure difference is given in the lower position and the movable contact element 13 connects the stationary contact elements 5 and 6.

In order to quickly open the contact system, it is necessary to quickly remove gas from the upper volume 17, which is achieved by opening the electromagnetic (electrodynamic) valve by applying a pulsed current (up to tens of thousands of amperes) to the inductor coil 7. When the valve opens, gas from the upper volume comes out at the speed of sound and the movable contact rises to the upper position under the action of pressure in the lower chamber 18.

The rapid removal of gas from the upper volume 17 requires a sufficiently large passage section of the hole of the electromagnetic valve, and a comparable total area of the holes in the partition 20, i.e. the total area of the holes in the partition must exceed the effective area of the through hole formed when the valve is opened. The area of the valve orifice is preferably at least 5%, 10%, 15%, 20%, 25%, 30%, 35%, 40%, 45% or 50% of the partition area above the upper volume, depending on the required gas outflow time . The amount of upper volume, working pressure and effective area of the openings in the valve and the baffle affect the time of gas outflow.

The main advantages of the present invention are provided by the small volume of the upper chamber and the use of a valve with an electromagnetic actuator, since it is such an actuator that allows you to quickly open large cross-section openings.

The electromagnetic actuator in the preferred embodiment is in the form of an inductor coil 7, which, when a pulsed electric current flows through it, induces eddy electric currents in the projected element (expanded part 9 of the shutter 8), as a result of which the shutter is repelled from the inductor. The direction of movement of the shutter may lie in the plane of the cover, be perpendicular to it or located at any other angle. In the latter embodiment, as shown in FIG. 1, where the shutter 8 can be moved in the vertical direction, the inductor coil 7 is located in a horizontal plane in the upper part of the partition 20, mainly under the expanded part 9 of the shutter 8. Due to this arrangement, the length of the interaction zone of the inductor coil 7 and the shutter 8 of the valve increases.

In order to maximize the force of the magnetic field of the inductor 7 coil on the shutter 8, the inductor coil is installed as close as possible to the object being thrown, placed mainly in the upper part of the partition 20 and located under the lower edge of the aforementioned shutter.

Bringing the disconnector into a standby state in the operation shown in FIG. 1 option is carried out by the simultaneous supply of gas to the lower and upper chamber. The gas flowing through the hole 12 in the cover causes the shutter 8 to fall down and form a sealed connection with the partition 20. Next, the gas flowing through the gap between the shutter 8 and the cover 24 fills the upper volume 17. During filling of the apparatus with gas, the movable contact acts the pressure difference is translated into the lower position and bridges the stationary contact elements, while providing sufficient contact pressure.

In order to attenuate the acoustic shock from the compressed gas flowing out at the sound velocity that occurs after the electromagnetic valve has been actuated, in the preferred embodiment, the disconnector comprises a silencer 24. The silencer may have various designs known in the art. In one embodiment, the silencer may be a pipe with several ring-shaped inner ribs 25 and comprise a cover 26 with a plurality of through holes of small diameter.

The electrical disconnector according to the present invention makes it possible to open electrical circuits in the absence of current flowing through the apparatus. In an advantageous embodiment, the circuit comprising the electrical disconnector of the present invention may comprise a switch, for example a low voltage, which is installed in series with the disconnector. The use of this configuration ensures that there is no current in the disconnector at the moment of its opening due to the preliminary operation of the switch.

Claims (11)

1. A disconnector having two fixed contact electrodes separated by an insulator and a movable contact electrode configured to close / open fixed contact electrodes and attached via a membrane to side walls having a mechanical connection with at least one fixed contact, wherein the contact electrode and the membrane divide the volume between the side walls into a lower volume, in which the stationary contact electrodes are located, and an upper volume, characterized in that it contains an elec a solenoid valve that is capable of opening when a pulse current is supplied to the inductor coil and installed with the possibility of discharging gas from the upper volume, and including a valve body, a shutter made using material with high electrical conductivity and with the possibility of sliding along the guide in the valve body and repulsion from the inductor when inductor induces eddy electric currents in it, and an inductor coil installed with the possibility of inducing eddy electric Sgiach currents flowing through it a pulsed electric current. 2. The disconnector according to claim 1, characterized in that the elements of the disconnector have axial symmetry and are located coaxially. 3. The disconnector according to claim 1, characterized in that the elements of the disconnector are made in the form of cylinders, circles or sectors. 4. The disconnector according to claim 1, characterized in that the valve comprises a partition adjacent to the upper volume and having one or more holes, the total area of which is not less than the area of the valve outlet. 5. The disconnector according to claim 1, characterized in that the direction of movement of the shutter is perpendicular to the plane in which the membrane is located. 6. The disconnector according to claim 1, characterized in that rigid elements limiting the movement of the membrane are placed above and / or below the membrane. 7. The disconnector according to claim 1, characterized in that it comprises a silencer installed with the possibility of passing gas from the valve. 8. The disconnector according to claim 1, characterized in that it comprises a system of channels providing water cooling of the conductive elements. 9. The disconnector according to claim 1, characterized in that it comprises sensors for the position of the movable contact. 10. The electrical circuit, which includes a disconnector according to any one of paragraphs. 1-9. 11. The circuit according to p. 10, characterized in that it contains a switch mounted in series with the disconnector.

Images