NO180607B - Conductor circuit breaker with an electromagnetic trigger - Google Patents

Abstract

In the automatic cutout having an electromagnetic trip (3) designed as an impact armature system, an energising winding (3a) is surrounded by a frame-shaped magnet yoke (5) formed by a ferromagnetic sheet-metal strip. Said yoke has an integrally arranged, horn-shaped fixed contact point (5d), which merges into an arc guide rail (5f) and interacts with a moving contact lever (8), which is arranged on the side of the trip (3) and in front of the end of an arc splitter stack (4a). In order structurally to simplify the magnet yoke (5), and to construct it in a material-saving manner, it is folded from one piece to form a frame-shaped closed iron return path surrounding the energising winding (3a). To this end, the magnet yoke (5) has a U-limbed region (5a, 5b, 5c), which is located above and on both end surfaces of the energising winding (3a) and is constructed at one limb end, together with the contact horn (5e), with a fixed contact point (5d), which is arranged without a transition and projects in the form of an ear. Connected thereto is a bent-back arc guide rail (5f) which, with the end of the free limb (5a), forms a rectangular frame corner without mutual contact, so that the shape of the magnet yoke (5), which is folded in one piece is completed. <IMAGE>

Description

The invention relates to a circuit breaker with an electromagnetic release device designed as an impact armature system, the magnetization winding of which is enclosed by a frame-shaped magnetic yoke formed from a ferromagnetic plate strip, which in turn has a one-piece, horn-like, fixed contact point that transitions into an arc runner rail and with a an extinguishing chamber arranged below the trigger element with extinguishing plates arranged parallel to the impact anchor system as well as a vertically oriented, movable contact device arranged on the side of the trigger element and in front of the end side of the extinguishing plate stack.

Such a coupling device is known from DE-30 31 549 Al. Here, a frame-shaped, closed magnetic yoke completely surrounds the magnetizing winding of the release device. The fixed contact piece that goes into an arc guide plate is connected to the magnetic yoke by the fact that this part is punched in its entirety into a piece of a plate strip of stainless steel and folded. To form the closed frame of the magnetic yoke, the legs on the side of the fixed contact piece overlap each other and are also riveted together. The disadvantage of this magnetic release is the considerable volume-wise additional consumption of relatively expensive material, as well as a necessary mechanical work process.

Furthermore, a small electric circuit breaker is known from DE-OS 1 966 598, where a rear end plate which surrounds the release magnets simultaneously serves as a carrier for the fixed contact piece and is provided with an arc arrester horn. The latter is located at a great distance from the magnetic yoke and is also bent obliquely to the axis direction of the trigger. Such an extinguishing chamber is not suitable for switches with the high switching capacity common today.

The purpose of the invention is, with a circuit breaker of the kind mentioned in the introduction, to structurally simplify the release member's magnetic yoke, to perform it with material savings and at the same time in the adjacent extinguishing chamber and contact area of the switch to give it an optimal design so that the arc can quickly run away from the contact point and that a commutation of the arc on the fixed contact side must therefore be excluded.

This purpose is achieved with a circuit breaker with the characteristic features as stated in claim 1. Further developments and advantageous embodiments of the invention appear from the non-independent claims.

The invention is advantageous in so far as a cost-effective arc extinguishing device can be produced with low material costs, which also ensures a high speed of the switching arc in the pre-chamber area. In this connection, the arc is driven straight and fast, particularly in the critical area in front of the extinguishing plates at the fixed contact piece and the arc runner rail, both of which predominantly consist of ferromagnetic material. Due to the special device, the magnetic flux of the short-circuit current surrounding the arc runner rails is reinforced in the area of the antechamber space, and the highly effective blowing created here ensures a rapid arc progression from the contact point. Furthermore, the proposed measures significantly reduce the breaker's propensity to re-ignite.

In connection with the drawing, the invention will be explained in more detail below.

fig. 1 schematically shows a circuit breaker with an open housing cover in the area of the release device and the extinguishing chamber,

fig. 2 shows a section through the extinguishing chamber according to

to the line II-II in fig. 1,

fig. 3 shows the release device with a different design

magnetic yoke,

fig. 4 shows the same seen from the side, and

fig. 5 and 6 show further, alternative possible embodiments of the magnetic yoke within the scope of the inventive concept.

The circuit breaker shown in narrow construction has one of two covers la, lb formed, with several rivets lc joined together housing 1, which in the upper part occupies a merely indicated switching mechanism 2. In the middle part of the housing there is arranged an electromagnetic release device 3, while the plinth area below it is predominantly designed as an extinguishing chamber 4. This is for the most part filled with extinguishing plates 4a arranged parallel to the bottom surface of the circuit-breaker and stack-like below each other, connected at a distance, and with the extinguishing plates limited on their narrow sides by arc runner rails 5 and 6 respectively flanking the extinguishing plates on both sides. In this connection, the upper arc runner 5f forms part of a magnetic yoke 5, which frames a magnetizing winding 3a as an iron field hoop. Within the magnetization winding, a shock armature system 3b is arranged around the iron core, which finally emits the repulsive blow to the electromagnetic release means of the thruster 3c by a short-circuit current.

The magnetic yoke 5 is produced in a piece of a plate strip and has a U-shaped leg area with a free leg 5a, a connection yoke 5b and a contact side leg 5c, at the end of which leg an ear-like is formed seamlessly , projecting fixed contact point 5d with a backwardly bent contact horn 5e, which finally merges into the upper arc runner rail 5f. In this connection, the magnetic yoke with its sections 5a, 5b, 5c, 5f forms an almost iron-enclosed, square frame around the magnetization winding 3a. As can be readily seen in the figures, the end of the contact side leg 5c in the transition to the fixed contact point 5d and the contact horn 5c, which is led obliquely in front of the end contour of the upper extinguishing plate, in the transition to the arc runner rail 5f is situated almost right up to the corner, while the end of the free leg 5a at the opposite frame corner extends towards the free end of the arc runner rail 5f, without however touching this. A partition, not shown, in the housing between the magnetization winding and the arc runner rail 5f ensures that, in the event of a short-circuit current, no conductive connection can occur between the leg 5a and the arc runner rail 5f under the influence of the magnetic forces. This is significant to the extent that, upon contact in this frame corner, there will be a reversal of the current direction and thus an obstacle to the magnetic blowing.

Furthermore, the magnetizing coil 3a is on the one hand preferably electrically conductively connected to an output terminal 7 and on the other hand to the leg 5c on the contact side by welding, so that it is in series with the fixed contact point 5d which is especially marked by a soldered-on small contact plate 5d' . Against this works an exclusively schematically shown, movable contact arm 8 which, via a flexible wire 8a, a thermal trigger 9 and a connecting wire 10a, is connected in series with an input terminal 10. The thermal trigger 9 in the form of a bimetal is in a manner not shown connected to one end of the arc guide rail 6 and adjustable there.

In the preferred embodiment, the two arc runner rails 5f, 6 are provided with a longitudinal, transversely profiled groove 5f, 6' (Fig. 1, Fig. 2) which is impressed protruding approximately in the middle of each arc runner rail, i.e. approximately in the swing plane of the movable contact arm 8. The track on the upper light-arc runner rail 5f therefore begins directly below the small contact surface 5d' and preferably ends at the same height as this. Thus, it is ensured that in the event of a disconnection sequence of the switching arc which, under the effect of the magnetic blowing field, extends from the contact points 5d', 8<*> with its base points along the track, is subjected to good guidance in the extinguishing plate stack, so that further measures effect a lateral limitation of the switching arc. ;The same applies to the opposite foot point of the switching arc, which when the contact arm 8 is opened under the effect of the magnetic blowing field jumps onto the lower ferromagnetic arc runner rails 6 and there the groove 6<*> can enter the extinguishing plate stack. In this connection, the arc is safely and efficiently driven in the critical area of the antechamber space and in front of the extinguishing plates 4a, then due to the integrated magnetic yoke in the contact area 5d, 5e consisting predominantly of ferromagnetic material and in the transition to the upper arc runner rail 5f, the magnetic flux surrounding these parts is amplified. A rapid arc progression from the contact corner along the two arc runner rails in the extinguishing plate stack is thus ensured, without re-ignition at the contact point.

In a modified embodiment (Fig. 3, Fig. 4), the release member 3 in the area below the magnetization winding 3a is provided with a separation section or longitudinal slot 5g in the magnetic yoke, so that next to it, in relation to the legs of the yoke 5a, 5b, 5c, which are made narrower arc runner rail 5f, which is only located in the middle plane of the switch, remains a longitudinal step 5h on one side, which close to the end of the leg 5c on the contact side is bent at an angle in the direction of the free leg 5a while omitting the contact point area and lies directly against end of this free leg. This results in a completely closed iron frame around the magnetization winding. The actual arc runner rail 5f is guided roughly parallel at a distance next to the longitudinal step 5h and, in addition to having the planar design shown, can also be provided with a cross-profiled track as in fig. 1 and 2.

A further variant of the object of the invention, especially at high currents, is the use of a composite material as the starting material for the magnetic yoke 5. In this connection, the plate strips are made of an iron alloy provided with a coating 5' of well-conducting material, preferably copper which can be at most half the thickness to the strip (fig. 5). The coated outer side of the plate strip with a total thickness of approx. 1 mm faces away from the magnetization winding 3a and is thus in good conductive connection with the contact point 5d and 5d' respectively. In order to also connect the magnetizing winding directly to the coated material in a production-friendly way, a connecting ear 5i is preferably on the contact side leg of the magnetic yoke bent inwards, so that one winding end with the coated material side is in contact with the ear. A low resistance is thus obtained between the magnetizing winding and a contact point, which is advantageous at high nominal currents.

A similar beneficial effect is obtained by the embodiment of

fig. 6, where a bridge part 5k of well-conducting material is arranged between the magnetization winding and the contact point. The bridge part follows the outer contour of the magnetic yoke in the ear-shaped, protruding contact point area 5d and lies there close to the outer side, so that one end is connected to the magnetizing winding 3a, while the other end can be made directly as a contact point. This can be realized, for example, by a 5k silver coating on the bridge part's base material of copper, so that an extra small contact plate is omitted. The function of the separately iron-enclosed magnetic yoke is also completely achieved with this design, as it has already been stated in the introduction.

Claims (10)

1. Circuit breaker with an electromagnetic release device designed as an impact armature system, the magnetization winding of which is surrounded by a frame-shaped magnetic yoke formed by a ferromagnetic plate strip, which in turn has a horn-like, fixed contact point arranged in one piece that merges into an arc runner rail, and with an extinguishing chamber arranged below the release device with extinguishing plates arranged parallel to the impact anchor system and with a vertically oriented, movable contact device arranged on the side of the release device and in front of the end side of the extinguishing plate stack, characterized in that the magnetic yoke (5) which extends from a U-shaped area (5a, 5b, 5c) formed above and on both end surfaces of the magnetization winding (3a) at one leg end is made with ear-shaped, protruding fixed contact points arranged without any transition ( 5d) as well as of contact horn (5e) and is, with the help of the arc runner rails (5f) connected to it, folded back in one piece into a frame-shaped, closed iron field hoop that surrounds the magnetization winding (3a). 2. Switch according to claim 1, characterized in that the free leg end (5a) of the magnetic yoke (5) which faces away from the fixed contact point (5d) and the free end of the arc runner rail (5f) are led at right angles to each other, but without touching each other, so that there is no continuous corner section in the frame-shaped hoop. 3. Switch according to claims 1 and 2, characterized in that the free end of the arc runner rail (5f) is independently extended over the free leg (5a) of the magnetic yoke (5a) and at a distance from the leg end thereof. 4. Switch according to claims 1 - 3, characterized in that the arc runner rail (5f) and the contact horn (5e) are provided with a cross-profiled groove (5f) in the longitudinal direction. 5. Switch according to claim 4, characterized in that the groove (5f) is arranged approximately in the pivoting plane of the movable contact device (8) and impressed, projecting in the direction of the extinguishing plate (4a). 6. Switch according to claim 4 or 5, characterized in that the groove (5f) is formed directly below a small contact plate (5d') at the fixed contact location, and has this so that the groove (5f) on the contact side from the beginning has the same height as the contact plate (5d'). 7. Switch according to one of the claims 1-6, characterized in that around the arc runner rail (5f) by means of a separation slot in the axial direction of the magnetization winding (3a) an approximately parallel longitudinal step (5h) is formed which from the contact side leg (5c) of U-shaped magnetic yoke (5b) omitting the fixed contact point (5d) and the arc horn (5e) is immediately bent as a closed iron frame around the magnetization winding (3a). 8. Breaker according to one of claims 1-7, characterized in that the magnetic yoke (5a) is produced from a ferromagnetic plate strip with a coating (5') of a well-conducting material on one side, so that the ferromagnetic material side faces the magnetization winding (3a) . 9. Switch according to one of the claims 1-8, characterized in that on the contact side leg (5c) of the magnetic yoke (5) is designed a connection ear (5i) bent in the direction of the arc runner rail (5f) for a direct electrically conductive connection with the coating (5<1>) and the wire in the magnetization winding (3a). 10. Switch according to one of claims 1-8, characterized in that the fixed contact point (5d) and the end of the magnetization winding (3a) facing it are conductively connected by means of a bridge component applied to the ferromagnetic material of the magnetic yoke (5) ( 5k).