RU2364002C1 - Electromagnetic drive for vacuum circuit breaker - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to electrical engineering, to electromagnetic drives of vacuum high-voltage circuit breakers. The electromagnetic drive is made from an imbricated core, actuating and tripping coils, armature and permanent magnets. The electromagnetic drive is provided with two magnetic latches, which hold the armature in its two extreme positions due to the effect of permanent magnets. The armature has frontal working gaps: one near the left end, and the other near the right end. The electromagnetic drive has several galvanically unconnected tripping coils with nominal power of not more than 0.33 kW each. Near one end in the zone of the tripping coil there two more lateral working gaps. Magnetic conductance of the lateral working gaps is several times more than magnetic conductance of the frontal working gap.

EFFECT: reduction of power consumed by the tripping coils several times; exclusion of pre-charged capacitors when tripping the drive.

3 dwg

Description

The invention relates to electrical engineering, in this case, to electromagnetic drives of vacuum high-voltage switches.

Known electromagnetic drives consist of an electromagnet (solenoid) and a mechanical holding device. [one].

The disadvantage of such drives is their large mass and multi-link kinematic connection system from the rod of the armature of the electromagnetic drive to the rods of the mechanisms for preloading the vacuum interrupter chambers.

The new generation of vacuum circuit breakers has a drive part with electromagnetic drives and permanent magnet holding devices.

According to the largest number of essential features similar to a number of important features of the proposed invention, the electromagnetic drive of the BP1 series vacuum circuit breaker of the BAT "RZVA" enterprise in Rivne was adopted as a prototype (Ukrainian Patent No. 35013A; 03/15/2001. Bull. No. 2, 2001).

The prototype, like the invention, consists of control coils (on and off), an armature, guides and permanent magnets, in which, with the help of on and off coils, the drive armature moves from one extreme position to the opposite, while the permanent magnets of the two-position electromagnetic drive form two magnetic circuits, the so-called "magnetic latches", in which the anchor is securely fixed. In this case, the armature of the electromagnetic drive in two extreme positions (“on” and “off”) is held by the magnetic field of two permanent magnets. The “on” or “off” operations occur only when the holding forces of the permanent magnets are canceled by the excitation of one of the coils of the electromagnetic drive. In this case, the permanent magnets are installed with the orientation of the poles of the same name in the direction of the armature, which is placed between these permanent magnets, coaxially with the on and off coils, as well as with the end gap relative to the magnetic circuit in one of the coils, depending on the position of the armature. The prototype with a minimum weight and size parameters has a relatively small turn-on current, high resource and reliability. The disadvantage of the prototype is that its electromagnet contains one trip coil, and this coil consumes a relatively large power of more than 4 kW, while existing circuit breakers have one or more trip electromagnets, the coils of which have a rated power of not more than 0.33 kW . To adapt the prototype in modern circuit breakers, the power of a powerful coil disconnecting its electromagnet is carried out from pre-charged capacitors. To ensure that the circuit breaker is tripped in operation, it is necessary to keep these capacitors charged at all times. In the event of a prolonged (more than 10 hours) lack of supply voltage to these capacitors, their self-discharge may occur and the circuit breaker will not be able to trip. To prevent self-discharge in such cases, various technical devices are used in operation that feed the capacitor from other energy sources. All this complicates the design of the circuit breaker and reduces its reliability. In addition, the presence of an analogue with only one tripping coil complicates the circuit breaker circuit, which has several galvanically separated tripping circuits, including current protection circuits, which are powered by current transformers according to a decoupling circuit. In this regard, testing the health of secondary circuits of a circuit breaker by means of automatic control is complicated. Another disadvantage of the prototype is that the switch in which it is integrated contains a large capacitor as a source of hazardous voltage that persists for a long time after it is disconnected from the network during maintenance of the switch.

The basis of the present invention is the creation of an electromagnetic drive of a vacuum circuit breaker, in which its design would allow the use of several galvanically unconnected trip coils, as well as reduce the power consumption of each trip coil to a value of not more than 0.33 kW.

The problem is solved in that in the electromagnetic drive of the vacuum circuit breaker, made of laden magniprovod and containing an armature mounted with the ability to move from one extreme position to the opposite, two permanent magnets mounted on the middle part of the magnetic circuit symmetrically, on both sides of the armature and oriented by the same name poles to the side of the armature, on and off coils mounted coaxially with the armature, and two magnetic latches made to hold the armature both of its extreme positions by the force of attraction to the magnetic circuit as a result of the action of permanent magnets, moreover, one magnetic latch is made in the form of two symmetric magnetic switching circuits and holds the armature in the on position, and the other in the form of two symmetrical magnetic disconnecting chains and holds the armature in the disconnected position, according to the invention, it has one or more galvanically disconnected tripping coils, as well as in each magnetic tripping circuit, except for the end working gap, between Tzom armature and the yoke has an additional side running clearance between the side surface of the armature and the yoke, and in the closed position of the electromagnetic actuator permeance lateral working gap is several times the magnetic conductivity of said mechanical working gap.

The indicated technical features of the proposed electromagnetic drive of the vacuum circuit breaker belong to the essential ones because their combination provides a positive technical result, that is, they are in a causal relationship with this result. Thus, the presence in the magnetic circuit of the electromagnetic drive trip, in addition to the end working gap, additionally the lateral working gap (the analogue does not have a lateral working gap) leads to an increase in the total magnetic conductivity of these working gaps, since they form parallel connected branches in the magnetic trip circuit. Due to the fact that in the switched on position of the electromagnetic drive, the magnetic conductivity of the side working gap is n times greater than the magnetic conductivity of the end working gap, the total magnetic conductivity of the magnetic trip circuit increased by approximately n + 1 times compared to the analogue that does not have side working gaps. And this, in turn, makes it possible to reduce by n + 1 times the magnetomotive force (hereinafter referred to as M.D.S.) of the trip coil (in comparison with the analog) to provide the same as the analog, attenuation of the magnetic flux and magnetic latch force, which keeps the electromagnetic drive on. As is known, a decrease in M.D.S. Coil n + 1 times allows you to reduce n + 1 times the cross-sectional area of the wire that wound this coil, and therefore, increase n + 1 times the number of turns while maintaining the cross-sectional area of the coil. That is, the active resistance of the trip coil can be increased (n + 1) ² times. Since the coils of an electromagnet with magnetic latches are designed only for direct current, as a result of increasing the resistance of the coil by (n + 1) ² times, we have a decrease in the current consumption and power of the trip coil by (n + 1) ² times. So in an electromagnetic drive built into a single-pole switch, at n = 4, the power of the trip coil was reduced by 25 times compared to the analogue and amounted to 0.22 kW.

Another significant technical feature is that the proposed electromagnetic drive of the vacuum circuit breaker may contain several galvanically unconnected disconnecting coils. This makes it possible to trip the electromagnetic drive independently of any of these coils. The galvanic isolation of these coils allows the use of different power sources for these coils, including current transformers. The small power (less than 0.33 kW) of the consumption of trip coils allows them to be powered directly (without a capacitor) from the low-power operational power circuits of existing switchgears.

All this significantly increases the reliability of the electromagnetic drive of the vacuum circuit breaker, simplifies its electrical circuit, increases the safety of maintenance (large capacitors are not used as a source of hazardous voltage).

Other objectives and advantages of the present invention will become apparent from the following detailed description of examples of its implementation and drawings, in which:

figure 1 shows the electromagnetic drive in the on position;

figure 2 - diagram of the circulation of magnetic flux when you turn on the electromagnetic drive;

figure 3 - diagram of the circulation of magnetic flux when disconnecting the electromagnetic drive.

The electromagnetic drive (figure 1) consists of a magnetic circuit 1, two permanent magnets 2, armature 3, guides 4 and 5, trip coils 6, power coils 7 and insert 8. Anchor 3 has the ability to move axially in guides 4 and 5 to stop in the magnetic circuit 1 with the right end (as shown in figure 1), or the left end. The design of the electromagnetic drive forms two symmetrical magnetic switching circuits and two symmetric magnetic switching circuits, the contours of which are shown in Fig. 1 in bold lines. The circuits of the magnetic switching circuits penetrate the switching coil, and the circuits of the magnetic switching circuits pierce all the switching coils. With de-energized on and off coils in these magnetic circuits, only permanent magnets are the sources of MDS.

In magnetic switching circuits, the electromagnetic drive has an end working gap between the end of the armature (in Fig. 1, the right end of the armature) and the magnetic circuit.

In magnetic tripping circuits, the electromagnetic drive has an end working gap between the other end of the armature (in Fig. 1 the left end of the armature) and the magnetic circuit, as well as additional side working gaps between the side surfaces of the armature and the magnetic circuit. In the on position of the electromagnetic drive, shown in Fig. 1, the magnetic conductivity of the side working gaps is several times greater than the magnetic conductivity of the end working gap, which is ensured by the shorter (several times) length of the side working gap from the end working gap at the corresponding cross-sectional areas of these gaps.

With deenergized on and off coils, magnetic fluxes F1 circulate in magnetic tripping circuits (Fig. 1), and magnetic fluxes F2 in magnetic switching circuits. These fluxes are the result of permanent magnets.

The inclusion of the electromagnetic drive is as follows. When applying a direct current direct current coil in the direction shown in FIG. 2, magnetic fluxes Ф3 and Ф4 additionally appear in the electromagnet, enhancing the action of magnetic flux Ф2, which increases the anchor traction force to the right. At the same time, the magnetic flux Ф3 weakens the action of the magnetic flux Ф1, which reduces the strength of the magnetic latch on the left end of the armature. As a result, the armature 3 (Fig. 1) moves to the extreme right (on) position all the way to the magnetic circuit 1. After that, the switching coil is de-energized, but the armature is held in the on position by the force of the magnetic latch acting on the right end of the armature.

Disabling the electromagnetic drive occurs as follows. When applying a dc disconnection coil to any coil in the direction shown in FIG. 3, magnetic fluxes F5, F6 and F7 additionally arise in the electromagnet. Magnetic flux Ф7 enhances the effect of magnetic flux F1 and increases the traction force of the armature to the left. At the same time, the magnetic fluxes F5 and F6, circulating through the magnetic inclusion circuit, weaken the action of the magnetic flux F2, which reduces the strength of the magnetic latch on the right end of the armature. The magnitude of the magnetic flux Φ6 passing through the lateral working gap is much larger than the magnitude of the magnetic flux Φ5 passing through the left end working gap due to different values of the magnetic conductivity of these working gaps. Therefore, the action of the magnetic flux F6 (and therefore the presence of a lateral working gap) in the process of opening the circuit breaker is dominant.

After reducing the force of the magnetic latch, the armature of the electromagnetic drive under the influence of the prevailing forces of the circuit breaker spring and the spring of the vacuum chambers of the switch poles pointing to the left moves to the left (disconnected) position all the way to the magnetic circuit. After that, the trip coil is de-energized, and the anchor is held in the off position by the force of the magnetic latch acting on its left end.

Such an electromagnetic drive was developed by High-voltage Union - Ukraine LLC. The electromagnetic drive has two galvanically disconnected disconnect coils, each of which is rated for a rated power of 0.22 kW, which makes it possible to trip the electromagnetic drive in two independent from each other low power channels directly from existing switchgears. The drive does not use pre-charged capacitors. All this has increased reliability and safety of servicing the drive, as well as greatly simplifying the electrical circuit of the secondary circuit breakers in which such drives are used.

The source of information

1. Afanasyev V.V., Yakunin E.N. "Drives for circuit breakers and high voltage disconnectors." L .: Energoatomizdat. Leningrad branch. 1982 g.

Claims (1)

The electromagnetic drive of the vacuum circuit breaker, made of burdened magnetic wire and containing an anchor, mounted to move from one extreme position to the opposite, two permanent magnets mounted symmetrically on the middle part of the magnetic circuit, on both sides of the armature and oriented by the same poles towards the anchor, the switching coil and shutdowns mounted coaxially with the anchor, and two magnetic latches, made with the possibility of holding the anchor in both its extreme positions by force pressure to the magnetic circuit as a result of the action of permanent magnets, moreover, one magnetic latch is made in the form of two symmetrical magnetic switching circuits and holds the armature in the on position, and the other in the form of two symmetric magnetic disconnecting circuits and holds the armature in the disconnected position, characterized in that it has one or more galvanically disconnected disconnecting coils, and also in each magnetic tripping circuit, in addition to the end working gap between the end of the armature and the magnetic circuit, there is an additional an additional lateral working gap between the lateral surface of the armature and the magnetic circuit, and in the on position of the electromagnetic drive, the magnetic conductivity of the lateral working gap is several times higher than the magnetic conductivity of the specified end working gap.

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