EP1473751A1 - Electromagnetic trip device - Google Patents

Abstract

The electromagnetic trigger or release device has a coil (3) and an armature (6) movable within the coil. It also has a magnet yoke (4) formed integrally with a magnet core (5) which engages at least partly in the coil. A spring (12) biases the armature. The magnet core and the armature are arranged symmetrically within the cross section of the coil. A core surface at least approximately normal to the coil axis lies opposite an armature surface which is bent out at right angles from the main armature body which runs parallel to the coil axis.

Description

The invention relates to an electromagnetic release, especially a circuit breaker with a coil, one in this movable anchor and a magnetic yoke, which in one piece with an at least partially in the coil engaging magnetic core is formed, as well as with a spring for the tension of the anchor. Such an electromagnetic Trigger is known for example from DE 101 26 851 C1.

The electromagnetic release known from DE 101 26 851 C1, especially for a circuit breaker a magnetic core formed in one piece with a magnetic yoke on which is arranged within the cross section of the trip coil is and with a central opening for implementation a plunger connected to a movable anchor is. Within a circuit breaker, such as a circuit breaker, is often the electromagnetic trigger due to the relatively large diameter of the trip coil the component that the minimum width of the circuit breaker pretends.

The invention has for its object an electromagnetic Triggers, especially for a circuit breaker, to specify which one with a simple construction is narrow.

According to the invention, this object is achieved by an electromagnetic Trigger with the features of claim 1. This trigger points, in principle comparable to one conventional electromagnetic release with submersible anchor, a coil, an armature slidable in it, a magnetic yoke with a core, as well as an anchor with a force against the direction of actuation spring. In contrast to known magnetic releases, the armature is and the core of the magnet yoke is not symmetrical in the Cross section of the coil arranged. Rather, the magnetic core points an asymmetrically arranged in the coil cross-section, at least core surface oriented approximately normal to the coil axis on which the magnet armature is opposite with an anchor surface. This anchor surface kinks at least approximately at right angles from an armature main body that is in the coil is displaceable parallel to the coil axis. Are in the coil the magnetic core lies side by side and the anchor main body. The anchor or a with this cooperating plunger does not penetrate the magnetic core or the magnetic yoke. This enables a special narrow construction of the coil, the inner width only marginal the width of the armature and the width of the magnetic core must exceed. Both the armature and the magnetic core are preferred as single-layer sheet metal components, preferably with the same or similar thickness. Both sheet metal components The armature and core preferably point within the coil a rectangular cross-section, the respective Facing narrow sides. Overall, the inside height is the approximately rectangular inner cross section of the coil more than twice, preferably more than three times the inside width.

The magnet armature is preferably composed as a one-piece component formed with a plunger and penetrates axially the entire coil. So one side is out of the spool outstanding anchor as a plunger for actuation in particular a moving contact and / or an unlatching device a circuit breaker can be used while on the opposite side of the coil from this protruding Part of the anchor is preferably used to attach the spring. This spring is preferred in a particularly space-saving manner formed as a conical compression spring, which between the coil or another immovable component, especially one rigid housing structure and a molded on the anchor main body Spring bearing legs, somewhat asymmetrical to the coil axis, is clamped. Alternatively, the spring can, for example also designed as a coil spring or spring of other geometry his.

While the magnetic core is invariably arranged in the coil is the anchor main body, which is also the plunger forms, slidable in the coil past the magnetic core. Around ensure that the magnet armature can move freely preferably between this and the magnet armature within the Coil arranged a partition made of non-magnetic material. This partition is structurally advantageous preferably part of a bobbin carrying the coil.

Is the switchgear with the electromagnetic release in particular circuit breakers with an arc quenching chamber is an arc guide rail preferably in a manner known per se to the magnetic yoke formed. A particularly space-saving construction is given by the arc guide rail in cross section is arranged at right angles to the magnetic core. A number of deion sheets an arc quenching chamber are in this Embodiment also at right angles to the magnetic core and arranged to the magnet armature. Because typically the width the deion sheets is less than the height of the deion sheets formed stack, is therefore preferably approximately rectangular coil cross section along to through the Normals of the main direction of extension given the deion sheets aligned with the arc quenching chamber. In the transverse direction, i.e. The trigger, on the other hand, builds in the plane of the deion sheets narrow. This enables it to be standardized within a Housing of a modular device, in particular with a Width of 18 mm, two electromagnetic releases of the same To accommodate the design side by side.

Both the anchor combined with the plunger and the one with Magnetic yokes combined in the magnetic core are preferred as rational Stamped parts or stamped and bent parts to be produced. Is the magnetic yoke with an arc guide rail combined, this part is to avoid unnecessary waste when stamping preferably shaped such that it is not bent condition an elongated, essentially straight Has shape. The angular offset between the magnetic core and the arc guide rail by 90 ° can still be implemented, by a crease line between the magnetic core and the arc guide rail is provided, which in the final state of Component with both the magnetic core and the arc guide rail encloses an angle of 45 ° each.

The advantage of the invention is in particular that due to the asymmetrical arrangement of a magnetic core and one Magnetic armature in a coil of a magnetic release with a essentially rectangular internal cross-section whose width almost to the thickness of those manufactured as single-layer sheet metal components Parts magnetic core - combined with a magnetic yoke - and anchor - combined with a plunger - is limited.

FIG 1

im Querschnitt ein erstes Ausführungsbeispiel eines elektromagnetischen Auslösers,

FIG 2

eine Vorderansicht des Auslösers nach FIG 1,

FIG 3

eine Draufsicht auf den Auslöser nach FIG 1,

FIG 4

eine perspektivische Ansicht des Auslösers nach FIG 1,

FIG 5a bis d

in verschiedenen Ansichten ein Magnetjoch des Auslösers nach den FIG 1 bis 4,

FIG 6

im Querschnitt ein zweites Ausführungsbeispiel eines elektromagnetischen Auslösers,

FIG 7

eine Vorderansicht des Auslösers nach FIG 6,

FIG 8

eine Draufsicht auf den Auslöser nach FIG 6,

FIG 9

eine perspektivische Ansicht des Auslösers nach FIG 6, und

FIG 10a bis d

in verschiedenen Ansichten ein Magnetjoch des Auslösers nach den FIG 6 bis 9.

Two exemplary embodiments of the invention are explained in more detail below with reference to a drawing. Show here:

FIG. 1

in cross section a first embodiment of an electromagnetic release,

FIG 2

2 shows a front view of the trigger according to FIG. 1,

FIG 3

2 shows a plan view of the trigger according to FIG. 1,

FIG 4

2 shows a perspective view of the trigger according to FIG. 1,

5 a to d

in different views a magnetic yoke of the release according to FIGS 1 to 4,

FIG 6

in cross section a second embodiment of an electromagnetic release,

FIG 7

6 shows a front view of the trigger according to FIG. 6,

FIG 8

6 shows a plan view of the trigger according to FIG. 6,

FIG. 9

a perspective view of the trigger of FIG 6, and

10a to d

in different views a magnetic yoke of the release according to FIGS 6 to 9.

Corresponding or identical parts are in all Figures with the same reference numerals.

1 to 4 show an electromagnetic in different views Trigger 1 of a not shown Switching device, for example a circuit breaker, Motor protection switch, circuit breaker, contactor or relay, preferably in the form of a DIN rail mounted device. basics Components of the trigger 1 are one on a sleeve-shaped Coil body 2 mounted coil 3, a magnetic yoke 4, which is formed in one piece with a magnetic core 5, and an armature 6 which can be moved in the coil 3. This acts at the same time as a plunger for actuating a not shown interacting with a contact piece 7 on the magnetic yoke 4 Moving contact. One towards the magnetic yoke 4 from the Coil 3 projecting end face of the armature 6 is used as a plunger surface Designated 8. This tappet surface 8 limits one elongated armature main body 9, which the entire coil 3 penetrates and on the other side by a spring bearing leg 10, which is perpendicular to the anchor main body 9 is molded, is limited. The spring bearing leg 10 has a nose 11, the attachment of a conical compression spring trained spring 12, which on the other hand on a rigid structure, not shown, or directly is mounted on the bobbin 2 and the armature 6 counter biases the direction of actuation R.

When actuated, i.e. electromagnetic triggering of the armature 6 becomes an air gap 13 between a magnetic core 5 in the coil 3 delimiting, perpendicular to the coil axis A aligned core surface 14 and an opposing core surface Anchor surface 15 closed. The anchor surface 15 is surface an armature arm 16, which is part of the armature 6 kinked at right angles from the anchor main body 9. The anchor 6 has thus an overall F-shape with the spring bearing leg 10 and the arm 16 as a parallel F-leg. The armature 6 is a sheet metal stamped part with a thickness d manufactured, which is at least approximately the thickness of the magnetic core 5 corresponds and is slightly smaller than the inside width b of the coil 3. In contrast, the inner height h of the coil 3 is essentially given by the sum of the core width k des Magnetic core 5 and the plunger width s of the armature 6. The core width k corresponds approximately to the width of the anchor surface 15 and has a direct influence on the magnetic force between the core surface 14 and the anchor surface 15. The ram width s the anchor main body 9, however, is of primary importance for the mechanical stability of the anchor 6. The Core width k, the direct influence on the impact of the Has magnet armature 6, the plunger width s exceeds by more than 50%. Is located between the armature main body 9 and the magnetic core 5 one formed integrally with the bobbin 2 Partition 17, preferably made of plastic, which the free Mobility of the armature main body 9 relative to the magnetic core 5 ensures. The inner height h of the coil 3 is in the embodiment more than three times the inside width b. Due to the small internal width b, the total width is B of the trigger 1, which is only slightly the width of the coil 3rd exceeds, dimensioned such that two similar triggers 1 find space next to each other in an 18 mm wide housing.

At the magnetic yoke 4 is an arc guide rail in one piece or arc rail 18 formed, which an arc quenching chamber limited. The geometry of the magnetic yoke 4 with the Arc guide rail 18 is particularly shown in FIGS 5a to 5d clearly. Both the arc guide rail 18 and the magnetic core 5 also integrally formed on the magnetic yoke 4 are aligned parallel to the coil axis A, but by 90 ° twisted against each other. Despite this twist, the magnetic yoke is 4 including the magnetic core 5 and the arc guide rail 18 as a stamped and bent part from a stamped Sheet metal strip made, which was originally an elongated straight shape. The twist of the magnetic core is possible by 90 ° relative to the arc guide rail a crease line 19, which with each of the parts mentioned 5.18 each includes a 45 ° angle. This is the magnetic yoke 4 can be produced with minimal waste during the punching process.

An alternative embodiment of an electromagnetic Trigger 1 show FIGS 6 to 9. The difference to the above explained first embodiment consists essentially in the form of the magnetic yoke 4, which is shown in FIG 10a to 10d is shown in more detail. In this case, that Stamped part from which the magnetic yoke 4 including the Magnetic core 5 and the arc guide rail 18 is bent, an L-shape, the shorter L-leg through the magnetic core 5 is formed. By fitting the individual L-shaped stampings are also low-waste Manufacturing possible. In addition, the bending process is particularly special simple.

In both embodiments, the trigger 1 is distinguished due to a simple structure with few rationally producible Items from, both the anchor 6 and that Magnet yoke 4, as explained in more detail above, are multifunctional. There is one in connection with this multifunctionality Saving on soldering, welding or other connection points. The electromagnetic release 1 is therefore also very good for manual assembly is suitable.

Claims (13)

Electromagnetic release with a coil (3), an armature (6) which can be displaced therein and a magnetic yoke (4) which is formed in one piece with a magnetic core (5) which at least partially engages in the coil (3), and a spring (12) for tensioning the armature (6),
characterized in that the magnetic core (5) and the armature (6) are arranged asymmetrically within the cross section of the coil (3), with a core surface (14) of the magnetic core (5) arranged at least approximately normal to the coil axis (A) within the coil (3) an armature surface (15) which bends at least approximately at right angles from an armature main body (9) running parallel to the coil axis (A) is opposite. Trigger according to claim 1,
characterized in that the armature main body (9) axially penetrates the entire coil (3). Trigger according to claim 1 or 2,
characterized in that the coil (3) has an elongated cross section with an inner width (b) and an inner height (h) which is more than twice the inner width (b). Trigger according to one of claims 1 to 3,
characterized in that the magnetic core (5) is designed as a single-layer sheet metal component. Trigger according to one of claims 2 to 4,
characterized in that the magnetic core (5) has an at least approximately rectangular cross section with a thickness (d) which corresponds approximately to the inner width (b) of the coil. Trigger according to one of claims 1 to 5,
characterized by a partition (17) made of a non-magnetic material and arranged in the coil (3) between the armature main body (9) and the magnetic core (5). Trigger according to one of claims 1 to 6,
characterized in that the spring (12) is arranged asymmetrically relative to the coil cross-section, essentially parallel to the coil axis (A). Trigger according to claim 7,
characterized by a spring bearing leg (10) formed on the anchor main body (9) and arranged at least approximately at right angles to it. Trigger according to claim 7 or 8
characterized in that the spring (12) is designed as a helical spring. Trigger according to claim 7 or 8
characterized in that the spring (12) is designed as a conical compression spring. Trigger according to one of claims 1 to 10,
characterized by an arc guide rail (18) integrally formed on the magnetic yoke (4). Trigger according to claim 11,
characterized in that the arc guide rail (18) has an at least approximately rectangular cross section, which is rotated by 90 ° relative to the cross section of the magnetic core (5). Trigger according to claim 12,
characterized in that the magnetic yoke (4) together with the arc guide rail (18) is formed from an elongated, essentially straight sheet metal strip.

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