UA97914C2 - Bistable electromagnet drive for switching device - Google Patents

Abstract

The invention relates to electric engineering, specifically to bistable electromagnetic drives for high-voltage switches which are used for commutation of power energy networks. The drive comprises a bistable magnet comprising a fixed portion of magnetic core with actuating/disconnecting coils and at least one constant magnet and a movable portion of magnetic core capable of connection to an actuating mechanism of a switching device, and a bistable magnet control device. The last one makes it possible to connect actuating/disconnecting coils to at least one source of direct (rectifying) current. Said device comprises at least one element to shape preset current in the coil windings and capable of simultaneous connecting the windings of actuating/disconnecting coils to the source of direct (rectified) current at connection (disconnection) of the magnetic drive. At the magnetic drive connection, the winding of actuating coil is connected directly to the one source of direct (rectified) current, the winding of disconnection coil is connected to said source through an element for shaping the preset current in the coil windings. The control device for the bistable magnet makes it possible to connect at the same time the windings of actuating/disconnecting coils to the common or separate sources of direct (rectified) current. At the electromagnetic drive disconnection, the disconnection coil is connected directly to one source of direct (rectified) current, the winding of actuating coil is connected to said source through the element for shaping the preset current in the coil windings.

Description

source of direct or rectified current directly, and the winding of the ignition coil is connected to the mentioned current source through an element for forming a given value of current in the windings of the coils. The device for controlling a bistable electromagnet is made with the possibility of simultaneously connecting the windings of the on and off coils to a common or to separate sources of direct or rectified current. th Zh a 1 th TA filfkyuktnkya and Shin

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The invention belongs to the field of electrical engineering, namely to bistable electromagnetic drives of high-voltage switches used for switching power energy networks.

The known bistable electromagnetic drive of the switching device (see Prospectus -

Vacuum switch with magnetic drive type MMI. ABB Romzheg Oivigirbshyop. - 12 p., attached), containing a bistable electromagnet, consisting of a stationary part of the magnetic circuit with on and off coils located in it and two permanent magnets and a moving part of the magnetic circuit, made with the possibility of connection with the executive mechanism of the switching device, and a device for controlling a bistable electromagnet, made with the possibility of connecting the windings of the on and off coils to one direct current source. The moving part of the magnetic circuit is made in the form of an anchor located inside the stationary part of the magnetic circuit with the possibility of reciprocating movement along the axis of the coils. The length of the armature is less than the height of the stationary part of the magnetic circuit by a given stroke value. The bistable electromagnet is made with the possibility of forming one non-magnetic air gap in the magnetic circuits of switching on and off in two stable positions of the armature. Fixation of the armature in the specified positions is ensured by permanent magnets, which create the effect of a "magnetic catch" when the coils are de-energized.

Turning on and off the electromagnetic drive is carried out when the current is supplied, respectively, to the winding of the turn-on or turn-off coil due to their creation in the magnetic circuit of the armature's gravitational forces, exceeding in value and opposite in direction to the forces that keep it in stable positions. After moving the armature from one to the opposite stable position, the winding of the corresponding coil is disconnected from the source of direct current by means of a device for controlling a bistable electromagnet. The device for controlling the bistable electromagnet contains electronic elements for controlling the operating modes of the on and off coils, for controlling the state of the switching device and for controlling the process of energy accumulation in the direct current source, made in the form of a capacitor.

The mentioned device is made with the possibility of alternately connecting the windings of the on and off coils to the capacitor. The well-known electromagnetic drive is used in the design of the UM1 high-voltage switch manufactured by the ABB company.

The disadvantages of the known bistable electromagnetic drive of the switching device are: - a relatively small value of the traction force in the bistable electromagnet when moving from one stable position to another, due to the alternating connection of the windings of the coils to a source of direct current, which causes the need to supply them with a large current to create a traction force sufficient to move the anchor from one stable position to another; - the relatively long time of operation of the bistable electromagnet when switching the switching device on and off is due to the sufficiently long duration of the increase of the magnetic flux necessary to create the necessary traction forces; - the relatively large capacity and cost of the capacitor used as a source of direct current.

A bistable electromagnetic drive of a switching device is known (see patent OA Mo 72320, НО1НЗ33/66, publication date 02.15.2005), which contains a bistable electromagnet consisting of a stationary part of the magnetic circuit with on and off coils located in it and two permanent magnets and a movable part of the magnetic circuit, made with the possibility of connection with the executive mechanism of the switching device, and the device for controlling a bistable electromagnet, made with the possibility of connecting the windings of the on and off coils to a source of direct current. The moving part of the magnetic circuit is made in the form of an anchor located inside the stationary part of the magnetic circuit with the possibility of reciprocating movement along the axis of the coils. The length of the armature is less than the height of the stationary part of the magnetic circuit by a given stroke value. The bistable electromagnet is made with the possibility of forming one non-magnetic air gap in the magnetic circuits of switching on and off in stable positions of the armature. Fixation of the armature in these positions is ensured by permanent magnets, which create the effect of a "magnetic catch" when the coils are de-energized. Turning on and off the electromagnetic drive is carried out when the current is supplied, respectively, to the winding of the turn-on or turn-off coil due to their creation in the magnetic circuit of the anchor's gravitational forces, which exceed in value and are opposite in direction to the forces that keep it in stable positions. After moving the armature from one to the opposite stable position, the winding of the corresponding coil is disconnected from the source of direct current by means of a device for controlling a bistable electromagnet. because the device for controlling a bistable electromagnet contains electromechanical elements for controlling the modes of operation of the on and off coils, for controlling the state of the switching device and for controlling the process of energy accumulation in a direct current source made in the form of a capacitor. The mentioned device is made with the possibility of alternately connecting the windings of the switching on and off coils to the main source of direct or rectified current, while the winding of the switching off coil is connected to an additional source of direct current - a capacitor, which ensures uninterrupted power supply in case of emergency disconnection of the main source.

Improvement of the design of the device for controlling the bistable electromagnet made it possible to increase the reliability and safety of the drive. The well-known bistable electromagnetic drive was tested in the design of the high-voltage circuit breaker of the BP2 series manufactured by the Rivne High-Voltage Equipment Plant.

The disadvantages of the known bistable electromagnetic drive of the switching device are: - a relatively small value of the traction force in the bistable electromagnet when moving from one stable position to another, due to the alternating connection of the coil windings to a source of direct current, which causes the need to supply them with a large current to create a traction force , sufficient to move the anchor from one stable position to another; - relatively long activation time of the bistable electromagnet when turning on and off the switching device, due to the sufficiently long duration of the increase of the magnetic flux necessary to create the necessary traction forces; - the relatively large capacity and cost of the capacitor used as an additional source of direct current.

The indicated shortcomings collectively reduce the technical characteristics of the bistable electromagnetic drive of the switching device while simultaneously increasing its cost.

The invention is based on the task of creating such a design of a bistable electromagnetic drive of a switching device, in which due to a different interconnection of the windings of the on and off coils with the device for controlling the bistable electromagnet and another design of the mentioned device, a significant increase in the traction force of the bistable electromagnet is ensured at a lower value

From the current in its windings, which allows you to increase the speed of the drive while simultaneously reducing its cost.

The problem is solved by the fact that in a bistable electromagnetic drive of a switching device, which contains a bistable electromagnet, consisting of a stationary part of the magnetic circuit with on and off coils located in it and at least one permanent magnet, and a movable part of the magnetic circuit, made with the possibility of connection with the executive mechanism of the switching device, and a device for controlling a bistable electromagnet, made with the possibility of connecting the windings of the on and off coils to at least one source of direct or rectified current, according to the invention, the mentioned device contains at least one element for forming a given current value in the windings of the coils and is made with the possibility of simultaneous connecting the windings of the on and off coils to a direct or rectified current source when the electromagnetic drive is turned on and off, while when the electromagnetic drive is turned on, the winding of the on coil is connected to the DC source direct or rectified current, and the winding of the cut-off coil is connected to the mentioned current source through an element for forming a set current value in the coil windings, when the electromagnetic drive is turned off, the winding of the cut-off coil is connected to the source of direct or rectified current, and the winding of the cut-off coil connected to the mentioned current source through an element for forming a given value of current in the windings of the coils.

At the same time, the device for controlling the bistable electromagnet is made with the possibility of simultaneously connecting the windings of the on and off coils to a common or to separate sources of direct or rectified current.

The set of general and distinctive features of the claims of the claimed invention makes it possible to realize in the design of the bistable electromagnetic drive when it is turned on and off a significant increase in the traction force of the bistable electromagnet at a lower value of the current in the coil windings. The implementation of a device for controlling a bistable electromagnet with at least one element for forming a given current value allows supplying a direct current to the windings of the coils with certain parameters that are selected, for example, taking into account the design and purpose of the switching device. Execution of the mentioned device with the possibility of simultaneously connecting the windings of the on and off coils to a source of direct or rectified current when the electromagnetic drive is turned on and off, as well as with the possibility of connecting the winding of the on coil directly to the current source and the winding of the off coil - through an element when the electromagnetic drive is turned on for the formation of a set value of current and when the electromagnetic drive of the winding of the turn-off coil is turned off directly with the current source and the winding of the turn-on coil - through the mentioned element, it ensures the creation of total magnetic fields in the bistable electromagnet, which significantly increase its traction forces, which affect the moving part of the magnetic circuit when transitioning from from one stable position to another. It also makes it possible to significantly reduce the value of the current in the coil windings when the electromagnetic drive is turned on and off and to reduce the duration of the process of overcoming the magnetic field created by the permanent magnet to hold the moving part of the magnetic circuit in its extreme positions. Reducing the value of the current in the coil windings when the electromagnetic drive is turned on and off allows, in turn, to use other sources of direct or rectified current in the design of the switching device, for example, capacitors with a smaller capacity or operational power sources of the switching device of lower power. Due to this, the specified result can be achieved while simultaneously reducing the cost of the electromagnetic drive of the switching device.

The essence of the claimed invention is explained by the presented figures of the drawings, where in fig. 1 provides a schematic diagram of a bistable electromagnetic drive; in fig. 2 - the schematic diagram of the magnetic circuit and the direction of the magnetic fluxes when the windings of the coils are de-energized (off state); in fig. With - the same when turning on the drive; in fig. 4 - the basic electrical diagram of the drive with a common source of direct current when the drive is turned on; in fig. 5 - the same when turning off the drive; in fig. 6 - the basic electrical diagram of the drive with separate sources of direct current when the drive is turned on; in fig. 7 - also when turning off the drive.

The bistable electromagnetic drive of the switching device contains (Fig. 1) a bistable electromagnet 1, which consists of a stationary part of the magnetic circuit 2 with coaxially located coils on and off 3 and 4 and two permanent magnets 5 and a moving part of the magnetic circuit b, and a device 7 for controlling the bistable an electromagnet, made with the possibility of connecting the windings of the mentioned coils C and 4 to a source of direct or rectified current 8. The moving part of the magnetic circuit would be made in the form of an anchor placed in the mentioned stationary part 2 3 with the possibility of reciprocating movement along the axis of the coils. The length of the armature is less than the height of the fixed part of the magnetic conductor 2 by a given amount of its stroke. The armature is connected by means of an intermediate mechanical device to the moving contacts of the switching device (not shown). The bistable electromagnet 1 is made with one non-magnetic air gap (not marked), which is formed between the stationary part of the magnetic conductor 2 and the end of the armature in each of the stable positions - on or off.

The device 7 for controlling a bistable electromagnet contains at least one element for forming a set current value 9 in the windings of the coils and is made with the possibility of simultaneously connecting the windings of the on and off coils 4 to the source of direct or rectified current 8 when the electromagnetic drive is turned on and off. The permanent magnets 5 are magnetized against each other, while the surfaces of one pair of identical poles M are adjacent to the anchor, and the other pair of identical poles 5 are attached to the fixed part 2 of the magnet wire of the bistable electromagnet 1 (Fig. 2). When the windings of the start-up and turn-off coils 3 and 4 are de-energized and the magnetization directions of the permanent magnets 5 correspond to the designations M and 5, the magnetic fluxes Fi and Fo created by them are directed in opposite directions (marked by arrows). With the specified directions of magnetization of permanent magnets 5, after connecting the windings of the on and off coils 3 and 4 with a source of direct or rectified current 8 (Fig. 3), currents pass in the opposite direction (indicated by arrows) in the mentioned windings, as a result of which in the magnetic system simultaneously with magnetic fluxes Phi; and Fo, magnetic fluxes are created

Фз and Фи, the direction of which coincides with the direction of the magnetic flux Fo and is opposite to the direction of the magnetic flux фи.

In these examples of the implementation of the bistable electromagnetic drive, the device 7 for controlling the bistable electromagnet is made with the formation of a closed loop between the element for forming the specified current value 9 and the windings of the on-off coils 3 and 4. At the same time, in the case of using one source of constant or of rectified current 8, the mentioned device 7 is made in such a way that when the drive is turned on, the winding of the switching coil C is connected to the source of direct or rectified current 8 directly, and the winding of the switching coil 4 is connected to the mentioned current source through an element for forming a given current value 9 (Fig. 4). When the drive is turned off, the winding of the cut-off coil 4 is connected to the source of direct or rectified current 8 directly, and the winding of the turn-on coil 3 is connected to the mentioned current source through the element for forming the set value of the current 9 (Fig. 5). When using two DC or rectified current sources 10 and 11 for the operation of a bistable electromagnetic drive, the mentioned device 7 is made in such a way that when the drive is turned on, the winding of the start-up coil C is connected to the DC or rectified current source directly, and the turn-off coil winding 4 is connected through an element to form the current value 9 (Fig. 6), when the drive is turned off, the winding of the cut-off coil 4 is connected to the source 10 of direct or rectified current 11 directly, and the winding of the turn-on coil C is connected through the element for forming the current value 9 (Fig. 7). In both examples, the element for forming the specified current value 9 can be made, for example, in the form of a resistor.

The technical solution described in the examples and presented in the drawings can be implemented in bistable electromagnetic drives of various designs, which contain a set of essential features included in the claims. For example, a bistable electromagnet can be made with two or more non-magnetic air gaps in the magnetic system. For example, the moving part of the magnetic circuit can be made in the form of a rod made of non-magnetic material, located inside the stationary part of the magnetic circuit, and two anchors fixed on the opposite ends of the rod from the outside of the mentioned stationary part. For example, on and/or off coils can be made with several windings. For example, a bistable electromagnet can be made not with rotary-translational movement of its moving part relative to the stationary part of the magnetic circuit, but with rotary-rotational movement at a given angle. For example, the fixed part of the magnetic circuit can be round or of another shape. For example, a device for controlling a bistable electromagnet may contain elements for forming a given current value of a different design, in particular, in the form of combinations of passive (resistors, capacitors, inductors) and active (transistors, thyristors, etc.) elements of electric circuits that provide the above-mentioned technical result.

The operation of the claimed bistable electromagnetic drive is explained on the example of its execution with a bistable electromagnet made with one non-magnetic air gap.

The bistable electromagnetic drive works as follows.

In the initial (off) position of the bistable electromagnetic drive, when the windings of the on and off coils З and 4 are de-energized (Fig. 2), counter-magnetized permanent magnets 5 create in the bistable electromagnet 1 magnetic fluxes Ф: and Ф" and the corresponding forces of attraction of the armature to the upper and lower horizontal sections of the stationary part of the magnetic conductor 2. The presence of a non-magnetic air gap between the end of the armature and the lower horizontal section of the stationary part of the magnetic conductor 2 significantly reduces the magnetic flux

Fo in comparison with the magnetic flux Fi, as a result of which the force of attraction of the anchor to the upper horizontal section significantly exceeds the force of its attraction to the opposite lower section.

Due to the difference in the specified forces, the anchor will be in the upper stable position, which corresponds to the off position of the bistable electromagnetic drive.

The drive is switched on using a device 7 for controlling a bistable electromagnet by simultaneously connecting the windings of the on and off coils 4 with a source of direct or rectified current 8 (Fig. 3, 4). When the magnetization directions of the permanent magnets 5 correspond to the designations M and 5, and the connection of the windings of the on and off coils 4 with a source of direct or rectified current 8, currents pass in the opposite direction in the mentioned windings. In this case, the winding of the switching coil 3, which is connected to the source of direct or rectified current 8 directly, will create a magnetic flux Fz directed opposite to the flux Fi in the upper part of the armature and according to the flux Fo in the lower part of the armature, as a result of which the force of attraction of the latter to the upper of the horizontal section of the fixed part of the magnetic conductor 2 will decrease, and the force of attraction of the anchor to the lower horizontal section of the fixed part of the magnetic conductor 2 will increase. In order for the force of attraction of the armature to the lower horizontal section of the stationary part of the magnetic conductor 2 to exceed the force of its attraction to the upper section and the armature begins to move to the opposite stable position, it is necessary to pass a relatively large current through the winding of the switching coil C. However, as a result of the simultaneous connection to the source of direct or rectified current 8 of the winding of the shutdown coil 4 through the element 9 for the formation of a given current value with a given direction of current flow in the magnetic system, a magnetic flux Fa is created, directed opposite to the flux Fi in the upper part of the armature , which additionally reduces the force of its attraction to the upper horizontal section of the stationary part of the magnetic conductor 2. At the same time, the total value of the current in the windings of the switching coils 3 and 4 is necessary to start moving the armature of the bistable electromagnet 1 from one (off) stable position to the opposite (on) , turns out to be significantly less than the current when one winding of the turn-on coil 3 is connected, which works without the "help" of the turn-off coil winding 4. After moving the armature to the switched-on stable position, the windings of both coils 3 and 4 are de-energized, and the armature is kept in this position by forces created by permanent magnets there 5.

To turn off the bistable electromagnetic drive in the device 7 for controlling the bistable electromagnet, the cut-off coil 4 is connected to the source of direct or rectified current 8 directly, and the winding of the turn-on coil 3 is connected to the mentioned source through the element 9 to form a set current value. As a result, the force of attraction of the armature to the upper horizontal section of the stationary part of the magnetic conductor 2 becomes greater than its force of attraction to the lower horizontal section and the movement of the armature begins in the opposite - off stable position. After moving the armature to the disabled stable position, the device 7 for controlling the bistable electromagnet de-energizes the windings of both coils C and 4, and the armature is held in this position by the forces created by the permanent magnets 5.

The results of experimental studies performed on prototypes designed and manufactured on the basis of the claimed technical solution confirmed the functionality of the proposed bistable electromagnetic drive as part of switching devices and obtaining the specified technical result. In particular, the use of the drive of the proposed design allows to ensure the necessary traction force of the electromagnet when reduced by 20-30

Fo of the total current in the windings of the turn-on and turn-off coils in comparison with electromagnetic drives made with alternating windings. The activation time of the electromagnetic drive when turning on and off the switching device is reduced by approximately the same amount. The specified technical result is achieved by simultaneously ensuring the reliability and safety of operation of the switching device.

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Claims (2)

FORMULA OF THE INVENTION 1. Bistable electromagnetic drive of the switching device, which contains a bistable electromagnet consisting of a stationary part of the magnetic circuit with on and off coils located in it and at least one permanent magnet, and a moving part 35 of the magnetic circuit, made with the possibility of connection with the executive mechanism of the switching device, and a device for controlling a bistable electromagnet, made with the possibility of connecting the windings of the on and off coils to at least one source of direct or rectified current, characterized in that the device for controlling a bistable electromagnet includes at least one element for forming a set current value in 40 windings of the coils and is made with the possibility of simultaneously connecting the windings of the on and off coils to a direct or rectified current source when turning on and off the electromagnetic drive, while when the electromagnetic drive is turned on, the winding of the on coil is connected to the by a source of direct or rectified current, and the winding of the cut-off coil is connected to the mentioned current source through an element for forming a set value of current in the windings of the coils, when turning off the electromagnetic drive, the winding of the cut-off coil is connected to the source of direct or rectified current, and the winding the switching coil is connected to the mentioned current source through an element for forming a given current value in the windings of the coils. 2. The bistable electromagnetic drive according to claim 1, which is characterized by the fact that the device for controlling the bistable electromagnet 50 is made with the possibility of simultaneously connecting the windings of the on and off coils to a common or to separate sources of direct or rectified current.