WO2003073456A1 - Magnetic actuator for a circuit breaker - Google Patents

Abstract

Disclosed is a magnetic actuator (1) for a circuit breaker (6), comprising a stationary magnetic body (2) generating a permanent magnetic field, a soft magnetic armature (9) which is movably guided between a contact position and a separating position parallel to the magnetic field and is connected to an actuating rod (5), and means (17) for moving the armature (9) in the permanent magnetic field. In order to make the inventive magnetic actuator (1) more compact while reducing the difficulties associated with the design thereof, the armature (9) is kept at a distance from the magnetic body (2) by the actuating rod (5) exclusively counter to the attraction of the magnetic body (2) when the armature (9) is in the contact position, and an air gap (19) is configured between the armature (9) and the magnetic body (2). Also disclosed is a circuit breaker comprising one such magnetic actuator.

Description

description

Magnetic drive for a circuit breaker

The invention relates to a magnetic drive for a circuit breaker with a fixed magnetic body for generating a permanent magnetic field, a soft magnetic armature which is movably guided between a contact position and a separation position parallel to the magnetic field and which is connected to a drive rod, and means for moving the armature in the permanent magnetic field.

The invention further relates to a circuit breaker for switching electrical currents, in particular in the medium voltage range.

Such a magnetic drive and such a circuit breaker are already known from EP 0 305 321 AI. The magnetic drive for a circuit breaker disclosed therein comprises a soft magnetic armature, a drive rod, a permanent magnet which generates a permanent magnetic field for holding the armature in a rest position, as well as a main winding and an auxiliary winding which is set up to strengthen the magnetic field of the permanent magnet. The armature is axially movably mounted to a stationary magnet body, which consists of the ring-shaped permanent magnet and a cylindrical pole piece, which extends partially through the ring-shaped permanent magnet. The pole piece is connected to a winding body by means of suitable thread means, on which the main and secondary windings are arranged concentrically. The axially movable armature, which is fixedly connected to the drive rod, extends partially within these two coils. The known magnetic drive also has a screw the one that is supported on the one hand on the axially movable armature and on the other hand on the pole piece. In a contact position, the magnetic field generated by the auxiliary winding as well as by the permanent magnet via the pole shoe is large enough to move the armature against the spring action of the helical spring into the interior of the windings towards the pole shoe and to hold it there. The armature is torn off by a current flowing through the main winding, as a result of which the magnetic field of the permanent magnet is weakened, so that the armature is moved into the disconnected position by the spring force of the prestressed coil spring.

In the case of the known magnetic drive, the magnetic field generated by the respective coils must be coordinated with regard to its force effect on the spring force, which makes the construction and design of the magnetic drive more difficult.

From DE 43 04 921 Cl a bistable magnetic drive for an electrical AC switch is known which has an armature made of laminated soft iron sheets to avoid eddy currents. The armature is surrounded by a rectangular soft magnetic yoke. Two permanent magnets are arranged between the yoke and the armature, which face the armature with the same poles and together with the yoke form a magnetic body. Furthermore, two coils are disclosed which weaken the magnetic field of the magnetic body when current flows, so that the armature can be moved axially again due to the spring force of a prestressed spring. The movement removes the contact between the armature and the yoke and increases the air gap between these two components, while the air gap between the yoke and armature on the other side of the armature becomes smaller until it there is an attraction between anchor and yoke with the help of which a further compression spring is pretensioned until the anchor strikes the yoke. This magnetic drive is also complex in terms of its construction and design.

A bistable magnetic drive is known from US Pat. No. 4,533,890, which has permanent magnets which are guided in a longitudinally movable manner and are permanently connected to an armature which is also longitudinally movable. The armature can be moved between two positions by the excitation of coils, in which it rests on stop shoulders. The permanent magnets are held in these stop positions by the armature at a distance from a magnetizable yoke.

The object of the invention is to provide a magnetic drive and a circuit breaker of the type mentioned, which are compact and simple in their design and construction.

The invention solves this problem starting from the magnetic drive mentioned in the fact that in the contact position of the armature by the drive rod alone against the attraction of the magnetic body at a distance from this and an air gap is formed between the armature and the magnetic body.

The invention further solves this problem with a circuit breaker for switching electrical currents, in particular in the medium-voltage range, with at least one interrupter unit having contact pieces and at least one magnetic drive of the aforementioned type, with an actuator required in contact position for the contact pieces of the interrupter unit pressure force is generated exclusively by the spaced mounting of the armature of the magnetic body.

The invention is based on the idea that the effect of a magnetic drive need not be limited to the pure movement of an armature between two stops. Rather, it is possible according to the invention to generate a magnetic force which is introduced as a contract pressure into the interrupter unit of the circuit breaker via suitable connecting means, so that the contact pieces of the interrupter unit are pressed against one another with the necessary pressing force in order to ensure a reliable current flow through the contact position Ensure interrupter unit. According to the invention, there is therefore no need to provide mechanical force storage elements such as compression springs or the like in the drive, which are pretensioned by the movement of the armature and which also exert a force effect after the armature strikes the magnetic body.

In the context of the invention, the pressing force is generated magnetically, specifically via an air gap between the magnet body and the armature. According to the invention, a fluid, that is to say a mechanical pressure escaping material with a reduced magnetic permeability compared to the metallic magnet body and the metallic armature, is located in the air gap. The magnetic resistance of the air gap is therefore comparatively high. Since the entire system would assume a more favorable energy state in the event of a gap closed by the armature, a magnetic force acts on the armature, which tends to convert it into this state and which can be determined by appropriate gradient formation. In the medium-voltage range, especially in the event of a short circuit, it is not unlikely that high currents will generate forces that cause the contact pieces of the interrupter unit to move apart. However, an uncontrolled movement apart can result in an electric arc that generates a lot of heat, which can damage the interrupter unit. In addition, it may also be desirable after a short circuit to initiate a disconnection of the contact pieces of the interrupter unit only after a short period of time, for example 3 seconds, in order to

Switches of smaller subnet areas to give priority when switching off, so that there are less far-reaching consequences in the event of a short circuit. The magnetic drive according to the invention therefore has a characteristic curve, in particular in the medium-voltage range, which meets the requirements of practice in practice, and which increases until the armature touches the magnetic body with a decreasing distance between these two components and thus with an increasing stroke of the magnetic drive according to the invention, its maximum value in the contact position has not yet reached. The magnetic drive according to the invention can therefore be used to generate a sufficiently high pressing force solely by magnetic forces, which prevents the contact pieces of an interrupter unit from moving apart even at high currents. In addition, a yielding or setting of the fixed contact piece can be compensated for, the distance between the armature and magnetic body being reduced.

In this context, it is also possible according to the invention that the armature is configured in a wedge shape in longitudinal section and projects into a shape-complementary recess of the magnet body in the contact position. For example, the end of the armature facing the magnetic body can be tapered, so the anchor is one against the actuator stem

Has tip which extends into a corresponding recess of the magnetic body. The air gap is thus formed between two surfaces which are slanted with respect to the direction of movement. With a stroke of the armature that is the same in relation to the right-angled embodiment, the air gap is smaller in this further development of the invention and thus the pressing force is increased. In an embodiment which differs from this, the wedge tip of the armature forms a ring which projects axially, that is to say in the direction of movement of the armature, and is arranged concentrically with the drive rod and at a radial distance from it.

In view of the manufacturing costs, it is advantageous if the air gap is filled with air. However, other insulating gases such as sulfur hexafluoride, nitrogen, helium or the like can also be used. The use of liquid, non-conductive oils is also possible within the scope of the invention.

A magnet body, for example, is a soft magnetic yoke or a pole piece connected to the yoke, which are provided on a permanent magnet or an electromagnet, and the yoke can be torn off by exciting a coil and also in connection with a compression spring. The means for moving the armature would thus comprise the coil and the compression spring. It is essential according to the invention, however, that the force for pressing the contacts of a circuit breaker is generated exclusively magnetically.

In a preferred further development of the invention, the means for moving the armature are a switch-off coil which is spaced from the armature in a direction of movement, wherein the armature in the contact position can be moved into the opening coil by a magnetic field. Due to the spaced arrangement of the switch-off coil from the magnet body, the armature can also be moved from the contact position into the disconnected position exclusively magnetically, specifically by the magnetic force of a coil. The magnetic force results from the coil's endeavor to completely pull a highly permeable armature into its internal magnetic field. In addition, with a correspondingly strong magnetization, the polarity of the armature can be reversed and the armature can therefore be repelled by the magnet body, which is now of the same polarity.

In a preferred further development of the invention, a switch-on coil is provided, which is arranged in the longitudinal direction between the release coil and the permanent magnet, the armature being movable into the switch-in coil in the disconnected position by a magnetic field. If the armature protrudes only partially into the closing coil in the disconnected position or if it is only aligned with the inside of the closing coil without even partially protruding into it, the longitudinal pull already described in connection with the opening coil occurs when the closing coil is excited to a magnetic force that accelerates the armature into the closing coil. In addition, the switch-on coil expediently magnetizes the armature in such a way that a magnetic pole is formed in the end face of the armature facing the magnet body and is attracted to the facing pole of the magnet body.

The armature and the magnet body are advantageously configured in a cylindrical shape and arranged coaxially to the drive rod. Such a further development according to the invention is characterized by a particularly straightforward and compact design.

In a further development in this regard, the armature, the magnet body and the drive rod are arranged in the interior of a current-carrying conduit. The conduit is designed as a hollow cylinder and carries the current over its outer wall. The encapsulation of the components of the magnetic drive increases the compactness and safety of the magnetic drive even further. In order to conduct the current essentially exclusively via the conduit, the conduit expediently consists of a material which is more conductive to the magnet body and the armature and, for example, of copper.

In order to further reduce the intrinsic weight of the magnetic drive, it is also advantageous if the drive rod is designed as a hollow cylindrical drive tube.

In a preferred further development of the invention, locking means are provided for fixing the drive rod in the disconnected position, which comprise a fixed locking body arranged concentrically to the drive rod with recesses on its circumference and locking balls, openings being provided on the circumference of the drive rod and the locking balls being in a locking position Holding means are fixable in a position in which they simultaneously penetrate the openings of the drive rod and the recesses of the locking body. The locking body can be hollow cylindrical, the drive rod extending into the cavity of the locking body. In a preferred embodiment, however, the locking body is designed as a solid cylindrical bolt with a round cross section, which projects into the drive tube.

The holding means are advantageously radially projecting input shoulders of a recess provided in the armature. This recess is open on one side and is provided for receiving one end of the drive tube. The input shoulders rest on the outer wall of the drive tube. If the locking balls are countersunk in the recesses of the locking body, the drive rod is firmly connected to the locking body and thus held stationary. The entry shoulders in the disconnected position prevent the locking balls from escaping while the positive fit is canceled. When the armature is moved longitudinally, the input shoulders move away from the locking balls and enable the drive rod to be unlocked.

In a preferred embodiment, the magnetic body is a permanent magnet. The magnetic field generated by the permanent magnet is therefore not conducted via a pole shoe located on the end face of the armature. Rather, the attraction between permanent magnet and armature takes place directly. This also allows a slim, material-saving and compact design.

In order to increase the effectiveness of the magnetic drive, it is advantageous if the drive rod consists of a soft magnetic material that only offers a low magnetic resistance to the magnetic field. A further increase in effectiveness is achieved according to the invention if the switch-on and switch-off coils are placed in a soft Are embedded net yoke, which is arranged for example outside the conduit and consists of two E-shaped opposite sections.

Further expedient refinements and advantages of the invention are the subject of the following description of exemplary embodiments of the invention with reference to the figures of the drawings, corresponding components being identified by the same reference symbols.

1 to 3 show an exemplary embodiment of the magnetic drive according to the invention for a vacuum switch in a sectional side view in several movement positions to illustrate the switch-on process,

FIGS. 4 to 6 the magnetic drive according to FIGS. 1 to 3 in several movement positions to illustrate the switch-off process.

Figure 1 shows an embodiment of the magnetic drive 1 according to the invention in a locked disconnected position. The magnetic drive 1 has a permanent magnet 2 which is fixedly connected to a current-carrying, hollow-cylindrical conduit 3 serving as a guide element, which is sealed off from the outside by an electrically shielding insulating layer 4 made of silicone rubber or the like. The cylindrical permanent magnet 2 is provided with a central through opening, through which a drive tube 5 extends. The conduit 3 is firmly connected to the permanent magnet 2. Outside the conduit 3, a vacuum tube 6 can be seen, the moving contact of which is not shown in the figure is firmly connected to the drive tube 5 via extension means 7. In order to ensure constant current contact when the drive tube 5 moves along its extension direction, for example towards the vacuum tube 6, a roller contact 8 is arranged inside the conduit 3 between the drive tube 5 and the extension means 7, which is connected to the by both spring elements by undetectable spring elements Line pipe 3 is supported as well as on the extension means 7, whereby the necessary contact pressure is generated.

An armature 9 is provided on the side of the permanent magnet 2 facing away from the vacuum switch 6, which armature has a displacement body 10 on its side facing away from the permanent magnet 2. A recess 11 is provided in the displacement body 10, into which an end of the drive tube 5 extends. The recess 11, which is circular in profile, has input shoulders 12 which delimit an opening whose inner diameter is only slightly larger than the outer diameter of the drive tube 5. This ensures that the drive tube 5 is received as precisely as possible. At its end, which extends in the recess 11, the drive tube 5 also has through openings 13 which allow the detent balls 14 to pass through. The locking balls 14 are arranged in recesses or recesses 15 of a locking bolt 16, the input shoulders 12 of the displacement body 10 preventing the locking balls 14 from escaping from the recesses 15. The drive tube 5 is thus firmly connected to the locking bolt 16, which is immovably coupled to the conduit 3. An undesired displacement of the moving contact of the interrupter unit is thus avoided. A switch-off coil 17 is provided outside the conduit 3 and is spaced from the permanent magnet 2 in the direction of displacement of the armature 9. A switch-on coil 18 can be seen between the switch-off coil 17 and the permanent magnet 2. To switch on the vacuum switch 6, the switch-on coil 18 is excited and thus generates a magnetic field in the longitudinal direction of the drive tube 5 from the coil, which magnetizes the armature 9 in such a way that a pole is generated on its end facing the permanent magnet 2, which pole faces the facing pole of the permanent magnet 2 is opposite. Because of this contradiction, an attraction is created. Since the armature 9 only partially extends within the closing coil 18, this magnetic attraction force is increased by a longitudinal pull with which the closing coil 18 pulls the soft magnetic armature 9 into its interior.

FIG. 2 shows the magnetic drive in a position in which the armature 9 has moved so far towards the fixed permanent magnet 2 due to the magnetic forces described above that the bottom of the recess 11 comes into contact with the end of the drive tube 5. The armature 9 is firmly connected to the locking body 10, so that from this point in time the movement of the armature 9 is coupled with a movement of the drive tube 5. Furthermore, it can be seen in FIG. 2 that the input shoulders 12 are no longer arranged above or below the locking balls 14, so that the locking balls 14 can emerge from the recesses 15 of the locking bolt 16 into the radially widened region of the recess 11 , In this way, the locking caused by the locking balls 14 between the locking bolt 16 and the drive tube 15 is canceled. FIG. 3 shows the magnetic drive according to FIG. 1 in a contact position, in which the armature 9, however, is not in contact with the permanent magnet 2. Rather, the maximum stroke of the contact pieces of the vacuum switch 6 is selected such that they come into contact with one another before the armature 9 strikes the permanent magnet 2. Since the moving contact of the interrupter unit 6 is rigidly connected to the armature 9 via the connecting means 7 and the drive rod 5, the armature 9 is held at a distance from the permanent magnet 2. An air gap 2 with a high magnetic resistance is created between armature 9 and permanent magnet 2. There is a magnetic attraction between armature 9 and permanent magnet 3, which is introduced via the rigid coupling by the connecting means 7 as a pressing force into the contact pieces of the vacuum switch 6. The closing coil 18 and the closing coil 17 are de-energized and are consequently not excited in the contact position. This also applies to the disconnected position. In this way, energy can be saved according to the invention.

Figure 4 shows the magnetic drive as Figure 3 in the contact position. The opening coil 17 is energized to separate the contacts. The opening coil 17 generates in its interior a magnetic field which is also parallel to the drive rod 5 and has a field strength which reverses the polarity of the magnetizable armature 9. The anchor 9 is thus facing

Pole of the permanent magnet 2 repelled and also pulled into the opening coil 17 due to the longitudinal pull that occurs due to the magnetic field inside the opening coil 17.

Figure 5 shows the magnetic drive 1 in a position in which the locking balls 14 are displaced in the longitudinal direction to the recesses 15 of the locking bolt 16 and only have a radial distance from them. With another shutdown Impact of the armature 9 from the permanent magnet 2, the input shoulders 12 therefore press the locking balls 14 into the recesses 15, so that the input shoulders 12 can slide over the locking balls 14. The armature 9 is thus unlocked from the drive rod 5.

FIG. 6 shows the magnetic drive 1 in the locked end position according to FIG. 1, in which both the opening coil 17 and the closing coil 18 are not energized. In this position, the input shoulders 12 prevent the

Exit of the locking balls 14 from the recesses 15. Thus, the locking between the fixed locking bolt 16 and the drive tube 5 is restored, so that accidental contact is prevented, for example, solely due to the attractive force between armature 9 and permanent magnet 2.

LIST OF REFERENCE NUMBERS

1 magnetic drive

2 permanent magnet 3 conduit

4 insulating layer

5 drive tube

6 vacuum switches

7 extension means 8 roller contact

9 anchors

10 displacement body

11 recess

12 entrance shoulder 13 through opening

14 locking balls

15 deepening

16 locking bolts

17 opening coil 18 closing coil

19 air gap

Claims

claims

1. Magnetic drive (1) for a circuit breaker (6) with a fixed magnetic body (2) for generating a permanent magnetic field, a soft magnetic armature (9) which is movably guided between a contact position and a disconnected position parallel to the magnetic field and which is connected to a drive rod ( 5) is connected, and means (17) for moving the armature (9) in the permanent magnetic field, characterized in that in the contact position the armature (9) by the drive rod (5) only against the attractive force of the magnetic body (2) kept at a distance from this and an air gap (19) is formed between the armature (9) and the magnetic body (2).

2. Magnetic drive (1) according to claim 1, characterized in that the means for moving the armature (9) are in a direction of movement of the armature (9) spaced from this opening coil (17), the armature (9) in the contact position can be moved into the opening coil (17) by a magnetic field.

3. Magnet drive (1) according to claim 2, characterized in that a switch-on coil (18) is provided, which is arranged in the direction of movement of the armature (9) between the magnet body (2) and the switch-off coil (17), the armature (9) in the disconnected position can be moved into the switch-on coil (18) by a magnetic field.

Magnet drive (1) according to claim 1 or 2, characterized in that the armature (9) and the magnet body (2) are cylindrical and are arranged coaxially to the drive rod (5).

Magnet drive (1) according to one of the preceding claims, that the armature (9), the magnet body (2) and the drive rod (5) are arranged in the interior of a current-carrying conduit (3).

Magnetic drive (1) according to one of the preceding claims, so that the drive rod (5) is a hollow cylindrical drive tube.

Magnetic drive (1) according to claim 5, characterized in that locking means are provided for fixing the drive rod (5) in the disconnected position, said locking body (16) being arranged concentrically to the drive rod (5) and having recesses (15) on its circumference and Include detent balls (14), openings (13) being provided on the circumference of the drive rod (5) and the detent balls (14) being fixable in a locking position by holding means (12) in a position in which they simultaneously open the openings (13) push through the drive rod (5) and the recesses (15) of the locking body (16).

8. Magnet drive (1) according to claim 7, so that the holding means are radially projecting input shoulders (12) of a recess (11) provided in the armature (9).

9. Magnet drive (1) according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the magnetic body is a permanent magnet (2).

10.Magnet drive (1) according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the drive rod (5) consists of a soft magnetic material.

11.Magnetic drive (1) according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the armature (9) is wedge-shaped in longitudinal section and protrudes in the contact position in a complementary shape of the magnet body (2).

12. Circuit breaker for switching electrical currents, in particular in the medium voltage range, with at least one interrupter unit (6) having contact pieces and at least one magnetic drive (1) according to one of claims 1 to 7, wherein a contact force necessary for the contact pieces of the interrupter unit (6) is generated exclusively by the spaced holding of the armature (9) by the magnetic body (2).