DE19637076A1 - Magnetic release, especially for a residual current circuit breaker - Google Patents

Abstract

A magnetic release or trip includes a magnetic circuit fed by a permanent magnet (11) and containing a U-shaped yoke (9) and an armature (5) bridging the ends of the 'U' of the yoke in the closed state of the magnetic circuit; also included is a pre-tensioned spring element for biasing the armature against the force of the permanent magnet. At least one coil-spring (19,20) of the spring element (18) has a winding axis aligned in the extension of the tilting edge (23) for hinge-mounting of the armature and including two limbs (24,25), the first (24) being held stationary and the second (25) being mounted in a retainer of the armature (5).

Description

TECHNICAL AREA

The invention is based on a magnetic release, especially for a residual current circuit breaker (FI switch), according to the preamble of claim 1. Such a magnet Solver has a magneti fed by a permanent magnet circle with a U-shaped yoke and with a in the closed state of the magnetic circuit, the ends of the U bridging hinged anchors. When a trigger size occurs, about a fault current, is in one on one of the two Leg of the U inserted trigger coil fed a signal. This signal creates a magnetic in the trip coil Flux, which is the magnetic generated by permanent magnets Continuous flow at the anchor location weakens. The one of a leader The spring-loaded anchor is weakened when the magneti constant flow lifted from the yoke and around a bearing axis pivoted. Here he loosens a plunger for mechanical Actuation of a device. With an FI switch, this works Pestle on a key switch, which is opening a contact arrangement of the FI switch.

STATE OF THE ART

The invention takes on a prior art of magnetic tripping sern for FI switch reference, as in DE-A1-38 38 444th is described. With this magnetic release, the anchor is on the ver attachment bridge of a U-shaped leaf spring attached, whose legs are held on an anchor bearing. When triggered  reaches the anchor loaded by a preloaded tension spring after a very short distance a bearing edge of the anchor bearing and tilts then around this bearing edge. This magnetic release also needs the tension spring generating the preload additionally one relatively complicated trained leaf spring.

A magnetic release described in DE-A1-41 11 092 has one by means of an armature bracket shaft rotatably and with a preloaded tension spring loaded anchor. The wave has a rectangular mandrel caulked in the anchor and is guided in two side guides of an anchor holder. This In addition to the pre-tensioned tension spring, the magnetic trigger also requires Lich the shaft and the anchor and the shaft non-positively coupling thorn.

SUMMARY OF THE INVENTION

The invention as set out in the claims the task is based on a magnetic release, in particular for an FI switch of the type mentioned at the beginning, which is characterized by a simple structure and the lowest possible Number of components distinguished.

In the magnetic release according to the invention by use a coiled spiral spring and by arranging the winding axis this spiral spring on the extension one for pivoting the Ankers required tilting edge parts, such as an additional spring or saved as rotatable bearing brackets. By using the spiral spiral spring stands for a force-transmitting Tappet available and can also be used to reload the Reload required after a triggering process energy can be effectively dampened. Above all, that forms spiral spiral spring but a bearing hinge for the anchor and positions the anchor using a simple bracket extremely effective at the same time. The anchor can then also be a  simple shape with evenly distributed mass. This gives good vibration resistance and good Setting bandwidth of the magnetic release according to the invention reached.

As for a yoke made from two sheets, the tipping edge by a magnetically insulating spacing of the two Yoke plates any bolts needed can be formed anyway does not apply to one equipped with such a yoke Magnetic trigger an additional component for the tipping edge. At the same time can then through the bolt between the two yokes a defined air gap can be set, which the Use an otherwise usually between the two yokes sheet-like disc-shaped diaphragm can be dispensed with makes.

An additional simplification of the magnetic release after the Invention is achieved in that the two yoke sheets are V-shaped are angled, and that the permanent magnet as Prismatoid is shaped with flat pole faces and with its Pole faces each on one of the two legs of the V. The permanent magnet then positions itself in the Magnetic release automatically, because it works through the action of the magnetic circuit guided continuous flow to the legs of the V is pressed. Unavoidable air gaps between the Pole surfaces of the magnet and the associated counter surfaces of the This significantly reduces yokes. Hence the coupling of the permanent magnetic flux in the yoke significantly improved. At the same time, the undesirable magnetic leakage flux becomes extreme kept low. There is no need to fix the permanent magnet, because the magnet automatically moves into the correct position in the V brings. In addition, the preferred direction of the magnet is now slightly too recognize and can run the magnet isotropically or anisotropically be.

BRIEF DESCRIPTION OF THE DRAWING

A preferred embodiment of the invention and the so achievable further advantages are described below with the aid of Drawings explained in more detail. Here shows:

Fig. 1 is an exploded view of a preferred exporting approximate shape of the magnetic release according to the invention,

FIG. 2 shows a perspective view of the magnetic release according to FIG. 1 after a part of its housing has been removed before a release process, FIG.

Fig. 3 shows a somewhat modified perspective view of the magnetic release according to FIG. 2 after a tripping operation, and

FIG. 4 shows a view of the magnetic release according to FIG. 2, executed in the direction of the winding axis of a spiral spiral spring, after its housing has been completely removed.

WAYS OF CARRYING OUT THE INVENTION

In all figures, the same reference numerals refer to parts with the same effect. The magnetic release shown in an exploded view in FIG. 1 has an insulating material housing consisting of a trough-shaped bottom 1 and a cover 2 . An opening 3 is provided in the cover 2 , which serves for the vertical guidance of a cylindrical plunger 4 . The plunger 4 has a thickened lower end, which is seated on a rectangular armature 5 of a magnetic circuit. The upward end of the plunger 4 acts via a switch lock, not shown, on a contact arrangement of an FI switch, not shown.

The magnetic circuit also has a two sheets 7 , 8 containing, U-shaped yoke 9 . The two yoke sheets are fixed with the aid of a bolt 10 made of non-magnetic material, for example a nickel alloy, for example by welding at a distance of typically 50 to 100 μm to one another. The mechanical stability of the yoke 9 can be increased by additional magnetically non-conductive welding, soldering or gluing points. The air gap formed by the distance takes over the function of a diaphragm which is usually used in the form of a film.

The two yoke plates 7 , 8 are each angled such that the yoke 9 has a V-shape in the region of the bend. Between the two legs of the V, a permanent magnet 11, formed as a prismatoid, with flat pole faces is arranged. The two pole faces each rest on one of the two legs of the V. Such an arrangement is characterized in that, on the one hand, the permanent magnetic flux is coupled into the yoke 9 particularly well and without significant scattering losses, and on the other hand, the permanent magnet 11 is automatically positioned in the correct position without additional aids. The magnet 11 can have a triangular or trapezoidal base area, the base of the triangle or trapezoid not necessarily being straight, but optionally also curved, for example in the form of a circular arc. In any case, however, the side surfaces of the triangle or the trapezoid are assigned to the pole surfaces of the magnet.

The reference number 12 denotes an intermediate floor made of insulating material. This intermediate floor has two webs 13 , 14 running parallel to one another on its upper side. Between the two webs there is an opening (not shown) and a material cutout (also not shown), which serve to carry out the end sections of the U contained in the yoke 9 . A trigger coil 16 that can be excited by an electrical signal is plugged onto a leg 15 of the U formed by the yoke plate 7 . This tripping coil is supplied with electrical power by means of two current connections 17 which are led through the base 1 and which is formed in the event of a fault current in a summation current transformer.

The reference numeral 18 denotes a spring element designed as a double spring. This spring element 18 contains two cylindrical, mirror-symmetrically arranged coil springs 19 , 20 with typically up to 10 turns each. As described below, the double spring is subjected to bending. Instead of the coil springs, other coiled spiral springs, such as spiral springs, can therefore also be used. Instead of a double spring, a simple spiral spiral spring can also be used as spring element 18 in the magnetic release according to the invention. Each spring 19 or 20 is mounted in a material recess 21 or 22 which is molded into the web 13 or 14 . The spring element 18 loads the armature 5 with a pretensioning force before the magnetic release is triggered.

As can be seen from FIGS. 2 and 4, the armature 5 rests on the ends of the U before the magnetic release is triggered and the armature 5 is then loaded with a prestressing force by the spring element 18 . The magnetic circuit is then closed and the permanent magnetic flux is guided by permanent magnets 11, for example via the yoke plate 7 , the leg 15 of the plate 7 , the armature 5 and the yoke plate 8 (FIG. 1) back to the permanent magnet. When a fault current occurs, the magnetic field of a current signal fed into the trip coil 16 weakens the field of the magnetic circuit in the area of the armature 5 . The armature 5 is tilted under the action of the spring element 18 and, as can be seen from FIG. 3, leads the plunger upwards, which then causes the FI circuit breaker to be switched off by striking the switching lock (not shown).

From FIGS. 2 and 4 it can be seen that the armature 5 is pivotally mounted on a tilting edge 23 formed by the bolt 10 and that at least the winding axis of the coiled spiral spring 19 is aligned in the extension of the tilting edge 23 . It can also be seen from these figures and FIG. 3 that the spiral spiral spring 19 has two legs 24 , 25 , of which the leg 24 is held fixed in the material recess 21 of the web 13 and - as can be seen in particular from FIGS. 2 and 3 can - the leg 25 is mounted with an axially guided section 26 in a bracket 27 designed as a groove of the armature 5 . In the state of the magnetic trigger which can be seen from FIG. 2 before the triggering, the spiral spring 19 , which can be seen in the counterclockwise direction from the plane of the drawing, is tensioned in the winding direction, so that the outer surfaces of the windings are subjected to tension and press the two legs 24 and 25 downward . As a result, the leg 24 is fixed on a wall of the material recess 21 and the leg 25 acts on the armature 5 with a torque.

When triggered, the armature 5 is then tilted counterclockwise around the tilting edge 23 and the plunger 4 is guided upwards out of the housing until the state of the magnetic release shown in FIG. 3 is reached. Since the winding axis of the spiral spiral spring 19 is aligned in an extension of the tilting edge 23 , and since the spiral spiral spring is fixed with its leg 24 in the material recess 21 and the armature 5 is at the same time held on the axially guided section 26 of the leg 24 , the spiral spiral spring 19 acts as a bearing hinge for the anchor 5 . An undesirable sliding of the armature 5 on the tilting edge 23 when triggered and when reloading the magnetic release is largely avoided. Since the spiral spiral spring 19 not only serves to support and hold the armature, but at the same time also generates force for the plunger 4 and dampens the reloading energy mechanically supplied from the outside, parts such as additional springs or pivot bearings can be saved in the magnetic release.

A particularly symmetrical and therefore force-free mounting of the armature 5 is achieved if the spring element 18 instead of a spiral spiral spring has the two spiral spiral springs 19 and 20 integrated in a double spring, as shown in FIG. 1. These two springs are wound in opposite directions and arranged mirror-symmetrically in the material recesses 21 , 22 . The axially aligned sections of the legs of these springs acting on the armature 5 are part of a connecting web 28 shown in FIG. 3 and held in the groove 27 .

A particularly secure mounting of the two spiral springs 19 , 20 is achieved if they are each designed as a cylindrical screw benfeder and are each held on an axially guided fixed bearing pin. Such a bearing pin can be molded into the intermediate base 12 holding the two spiral bending springs 19 , 20 . In FIG. 4, such a bolt supporting the coiled spiral spring 19 is designated by the reference symbol 29 .

It is advantageous to mount the leg 25 in the vicinity of the armature, since its axially directed section 26 is then short and at the same time undesirable radially and axially acting forces are largely kept away from the spring. A particularly safe power transmission of the springs 19 , 20 is ensured if the two legs of the springs 19 , 20 each apply tangentially to their turns. At the same time, such a spring is particularly easy to manufacture. For a secure mounting of the springs 19 , 20 , however, it is advantageous, as can be seen from FIGS. 2 to 4, to attach the leg 24 radially to the windings.

Reference list

1 floor
2 lids
3 opening
4 pestles
5 anchors
7 , 8 yoke sheets
9 yokes
10 bolts
11 permanent magnet
12 intermediate floor
13 , 14 webs
15 legs
16 trip coil
17 power connections
18 spring element
19 , 20 coiled spiral springs
21 , 22 material recesses
23 tilting edge
24 , 25 legs
Section 26
27 groove
28 connecting bridge
29 bearing bolts

Claims (11)

1. Magnetic release, in particular for a residual current circuit breaker, with a magnetic circuit powered by a permanent magnet ( 11 ), containing a U-shaped yoke ( 9 ) and a bridging the ends of the U in the closed state of the magnetic circuit and when opening the magnetic Circle on a tilting edge ( 23 ) pivotably mounted armature ( 5 ), and with a prestressed spring element ( 18 ) for loading the armature ( 5 ) against a force generated by the permanent magnet ( 11 ), characterized in that the spring element ( 18 ) has at least one Coiled spiral spring ( 19 , 20 ) has a winding axis aligned in the extension of the tilting edge ( 23 ) and two legs ( 24 , 25 ), of which a first (24) is held stationary and a second (25) with an axially guided section ( 26 ) is mounted in a holder of the armature ( 5 ). 2. Magnetic release according to claim 1, characterized in that the holder has an axially extending groove ( 27 ). 3. Magnetic release according to one of claims 1 or 2, characterized in that the at least one spiral bending spring ( 19 , 20 ) is designed as a cylindrical coil spring. 4. Magnetic release according to claim 3, characterized in that the second leg ( 25 ), which is preferably initially guided in the tangential direction, is attached to the windings of the at least one helical spring ( 19 , 20 ) on the armature side. 5. Magnetic release according to one of claims 4 or 5, characterized in that the at least one cylindrical coil spring ( 19 , 20 ) is held on an axially guided fixed bearing pin ( 29 ). 6. Magnetic release according to claim 5, characterized in that the bearing pin ( 29 ) in one of the at least one cylindri coil spring ( 19 , 20 ) holding, fixed intermediate floor ( 12 ) is formed. 7. Magnetic release according to claim 6, characterized in that the intermediate floor ( 12 ) has at least one groove-shaped material recess ( 21 , 22 ) which serves to receive the windings and the first leg ( 24 ) of the at least one cylindrical coil spring ( 19 , 20 ) . 8. Magnetic release according to one of claims 1 to 7, characterized in that the spring element ( 18 ) two coiled springs ( 19 , 20 ) spaced apart from one another in the axial direction, each with a second leg ( 25 ) containing the axially guided section ( 26 ). and each has a first leg ( 24 ). 9. Magnetic release according to claim 8, characterized in that the axially guided sections ( 26 ) are part of a in the holder of the armature ( 5 ) mounted connecting web ( 28 ). 10. Magnetic release according to one of claims 1 to 9, characterized in that the tilting edge ( 23 ) of a two magnetically insulated sheets ( 7 , 8 ) of the yoke ( 9 ) mechanically connecting bolts ( 10 ) is formed. 11. Magnetic release according to one of claims 1 to 10 with two magnetically insulated yoke plates ( 7 , 8 ), characterized in that the two yoke plates are angled V-shaped, and that the permanent magnet ( 11 ) is shaped as a prismatoid with flat pole faces and with the pole faces each on one of the two legs of the V.