DE102004056281A1 - Switching equipment having electromagnetic trip device e.g. for line safety or motor-circuit switches, has housing, contact point which has fixed and mobile contact part and electromagnetic trip device - Google Patents

Abstract

The switching equipment (1) has a housing (2), a contact point (4) which has a fixed and a mobile contact part (8, 6) and an electromagnetic trip device (20, 20a, 20b), having a trip coil (22, 22a, 22b) and a hammer armature (26, 26a, 26b). The electromagnetic trip device has a snap body consisting of a material with magnetic shape memory properties, which interacts with the hammer armature. When a short-circuit occurs, the snap body is switched between two bi-stable positions by the influence of the magnetic field of the trip coil.

Description

The The invention relates to a switching device with a housing and comprising at least one of a fixed and a movable contact piece Contact point, and with an electromagnetic trigger, the a trip coil and having a percussion anchor according to the preamble of the claim 1. Further, the invention relates to the use of a material with magnetic shape memory effect in a trigger coil and a shock absorber having electromagnetic release for a switching device according to the preamble of claim 9, and further the use of a material with magnetic shape memory effect for short-circuit current tripping in one comprising a contact point and an electromagnetic trigger switchgear according to the generic term of claim 11.

In generic switching devices, such as circuit breakers or motor protection switches, the electromagnetic release is used to interrupt the current path between the input and output terminals in the event of the occurrence of a short-circuit current. The known in the art today electromagnetic triggers, such as in the DE 101 26 852 C1 or the DE 100 10 093 A1 described, all work on the principle that a trip arm on the occurrence of a short-circuit current is set on a magnetic core in motion, and in the course of this movement, the tripping armature strikes the movable contact piece from the fixed contact piece on a ram operatively connected to him Contact point away, so that thereby the contact point is opened. Known electromagnetic triggers include for this purpose a coil, which is usually made of helically wound wire, as well as a fixedly connected to the outside coil yoke magnetic core, which engages inside the coil. The trip anchor is designed either as a hinged armature or as a plunger anchor, the latter also being located inside the coil. The anchor is held by the core at rest by means of a compression spring at a distance. When the short-circuit current flows through the trip coil, the magnetic field generated by the trip coil causes the trip armature to be moved against the restoring force of the compression spring towards the core. After switching off the short-circuit current, the armature is moved back by the restoring force of the compression spring back to its original position.

Of the Structure of electromagnetic releases is very expensive today and high costs, because many items with tight tolerances manufactured and assembled.

It Therefore, the object of the present invention, a generic switching device easier to install and thus cheaper build.

The Task is solved through a switching device with the characterizing features of claim 1, by the use a material having a magnetic shape memory effect in a switching device according to the characterizing Features of claim 9 and by the use of a material with magnetic shape memory effect for short-circuit current tripping in a switching device according to the characterizing ones Features of claim 11.

Thus, according to the invention the electromagnetic trigger a standing with the impact anchor in operative connection snap body a material with magnetic shape memory effect, under influence the magnetic field of the trip coil in short-circuit current case the snap body in two bistable positions is redirected. In particular, the trip anchor of a ferromagnetic Shape memory alloy be formed of nickel, manganese and gallium.

Triggers comprising a snap body are known in the art today only as thermal triggers whose operation is based on the snap disc principle. The snap disk is a disc-shaped component with a plate-shaped curvature. Under mechanical deformation load changes the curvature when exceeding a - dependent on the elastic components parameters - dead point abruptly their orientation from their first to their second bistable position, from convex to concave or vice versa. Knob disc releases are known with snap discs of thermal bimetal or thermal shape memory alloys, such as Ni-Ti. The mechanical deformation load is caused in the thermally activated domes by the thermally induced change in shape with temperature change. In the case of thermostatic bimetal, the shape changes slowly as the temperature changes until the dead center is exceeded and the curvature direction suddenly changes the snap disc changes. In the case of snap disks of thermal shape memory alloys, the curvature is directed into the switch-on position below the transition temperature; above the transition temperature, the snap-action disk jumps over into the release position.

at magnetic shape memory alloys In the martensitic phase, a change in shape can occur due to the transition between two crystal structure variants of a twin crystal structure be caused, with the transition between the crystal structure variants by an external magnetic field is controlled. The magnetic field strength, at this phase transition is also referred to below as "transition field strength." These materials are therefore used as magnetic shape memory alloys or "Magnetic Shape Memory Alloys "(MSM) designated.

magnetic Shape Memory Alloys are advantageously as ferromagnetic shape memory alloys made of nickel, manganese and gallium. More detailed explanations on the structure and operation of ferromagnetic shape memory alloys for example, based on nickel, manganese and gallium WO 98/08261 and WO 99/45631 can be removed.

By the corresponding alloy composition can be determined at which orientation of the external magnetic field the maximum extent is reached; e.g. can the magnetic field perpendicular or transverse to the MSM material stand to reach the maximum extent.

Changes in shape, achieved with MSM materials under the influence of an external magnetic field can, can linear expansion, bending or twisting (torsion).

One electromagnetic according to the invention trigger comprises a snap-action disc composed of suitably assembled MSM material. The magnetic field is through a current flowing through Coil generated.

The strain The MSM material is proportional to the coil current at low current. The snap-action disc is in its unlocked state in its first bistable position. She is in terms of her elastic Design dimensioned so that they exceed a certain transition magnetic field strength, the is reached at a certain short-circuit current through the coil, just passed her dead center has and jumps into their second bistable position.

Of the Advantage of the invention is that in a switching device according to the invention the structure of the magnetic trigger is greatly simplified. The magnetic trigger according to the invention can be more compact and space-saving realize than a magnetic release according to the state of the technique. Thus, an inventive switching device with a magnetic according to the invention trigger easier and more compact to build.

One Another advantage of a switching device according to the invention the speed of the magnetic release. It must be accelerated no inertial mass, the shape change due to the magnetic shape memory effect almost happens delay.

One Another advantage of a trigger according to the invention is that he, due to the snap disc principle, triggers highly accurate and little sensitive to manufacturing variations of both the mechanical tolerances as well as the material composition. Since only a few parts are needed is only a small space in the housing required.

One Another advantage of a switching device according to the invention lies in that the spatial Assignment of the tripping coil to the snap body made of ferromagnetic shape memory metal diverse adaptable to the geometry requirements within the switchgear housing is.

Of the latching body can be designed as a snap disc and in its edge area in one with the housing connected snap-action bearing be held. The snap body is outside in an advantageous embodiment the trip coil attached in their vicinity.

According to one Another advantageous embodiment of the snap body of the trigger according to the invention as Snap disc trained and within a the trigger coil carrying coil winding body held. The snap body is then advantageously covered by the trip coil.

The Snap disk can in its center frictionally or positively with be connected to the impact anchor. In an advantageous embodiment The invention, the snap element is doing with a Umsteuern in the two bistable positions supporting return spring in operative connection.

Consequently is optimal space utilization within the switchgear housing accessible, which leads to smaller and therefore more cost-effective designs of the switching devices.

It become fewer parts with less requirement for their dimensional accuracy for the electromagnetic trigger needed and mounting an electromagnetic actuator with a snap element ferromagnetic shape memory metal is therefore easier and cheaper.

Further advantageous embodiments and improvements of the invention and Further advantages can be found in the further subclaims.

Based of the drawings, in which three embodiments of the invention are shown, the invention and further advantageous Embodiments of the invention in more detail explained and described.

It demonstrate:

1 1 shows a schematic representation of a first embodiment of a switching device according to the invention with a snap body of ferro-magnetic shape memory metal held in a snap-action bearing connected to the housing, arranged next to a trip coil, in the resting state,

2 in a schematic representation of the first embodiment according to 1 in the triggered state,

3 a schematic representation of a second embodiment of a trigger according to the invention with a arranged in the interior of a tripping coil winding body arranged disk-shaped snap body of ferromagnetic shape memory metal, arranged next to a trip coil, and

4 a schematic representation of a third embodiment of a trigger according to the invention with a arranged inside the trolley coil winding body arranged disk-shaped snap body of ferromagnetic shape memory metal, arranged in the interior of a trip coil.

In 1 is schematically a switching device 1 with a housing 2 and an electromagnetic trigger 20 shown in the untriggered state. In 2 is the switching device, after 1 shown in the tripped state, wherein the same or similar-acting assemblies or parts are designated by the same reference numerals.

In addition to the electromagnetic release 20 includes the switching device 1 another thermal overcurrent release. This is essentially formed from a bimetallic strip 44 , which with its first, fixed end 44 ' on a bimetallic bracket 48 is attached, and its second, movable end 44d '' in a recess 35 in a slider 34 intervenes.

Between a (not shown here) input terminal and a (also not shown) Ausgangsklemmstück runs a current path via a movable wire 18 , one in a contact lever bearing 12 mounted contact lever 10 , one on the contact lever 10 located movable contact piece 6 and a fixed contact piece 8th comprehensive contact point 4 , a trip coil 22 , the bimetallic bracket 48 , the thermo-bimetal strip 44 and a second movable wire 18 ' , In the in 1 shown switching position is the contact point 4 closed. With the trip coil 22 and the fixed contact piece 8th is over an ear-shaped intermediate piece 42 another yoke 40 connected.

The electromagnetic trigger 20 includes the trip coil 22 and a snap disk formed of ferromagnetic shape memory metal 24 , This is on the front side of the trip coil 22 arranged so that the snap disc center moves when snapped on an imaginary line in extension of the Auslösespulenlängsachse. The snap-disk 24 is on its outer circumference in one with the housing 2 connected snap-action disc bearings 28 held. In the in 1 shown untriggered state has its curvature in the direction of the trip coil 22 , At its center is the snap disc 24 in operative connection with a percussion anchor 26 , The active compound is shown here as a positive connection, alternatively could. However, non-positive or cohesive connections can be realized.

The snap disk of ferromagnetic shape memory metal based on nickel, manganese and gallium is located outside the trip coil 22 , Their spatial arrangement in relation to the trip coil 22 is chosen so that a good magnetic coupling to the trip coil 22 given is. A suitable design of the trip coil 22 and the magnetic circuit can be made by a person skilled in the art with the aid of his normal knowledge and supported by systematic experiments.

The snap-disk 24 consists of a ferromagnetic shape memory alloy based on nickel, manganese and gallium. Such ferromagnetic shape memory alloys are known and available in principle, for example, from the Finnish company AdaptaMat Ltd. manufactured and sold. A typical composition of ferromagnetic shape memory alloys for use in switching devices according to the invention is given by the structural formula Ni _65-xy Mn _{20 + x} Ga _{15 + y} , where x is between 3 atomic% and 15 atomic% and y is between 3 atomic% and 12 atomic%. The ferromagnetic shape memory alloy used here has the property that in its martensitic phase, that is, the phase containing the material below. takes the thermal transition temperature, under the effect of an external magnetic field on a microscopic scale, a transition between two crystal structure variants of a twin crystal structure takes place, which is associated macroscopically with a change in shape. In the embodiment of the snap-action disc chosen here, the change in shape is in a bend towards the shape of the second bistable snap-action disc position.

The thermal transition temperature for the ferromagnetic used here Shape Memory Alloys is in the range of room temperature and is due to variation of Atomic percentages x and y within a bandwidth adjustable. This is the working temperature range within which the electromagnetic trigger works within a range by choice of material composition adjustable.

Flows through the switching device 1 In the event of a short circuit, a high short-circuit current, so the snap disc bends out of the first bistable position until the dead center is exceeded and suddenly changes the buckling direction of the snap disc in the second bistable position. As a result, the plunger strikes 26 the movable contact piece 6 from the fixed contact piece 8th away, leaving the contact point 4 opened and the switching device is triggered, as in 2 shown. The bending of the ferromagnetic shape memory material happens very fast and almost instantaneously. The delay time as the time difference between the occurrence of the short-circuit current and the reaching of the dead center is typically of the order of one millisecond.

The release can, of course, as usual in switchgear engineering and not shown here, supported by a release lever, the one the permanent opening the contact point locking derailleur operated.

After tripping of the switching device, the current path is interrupted and the magnetic field of the tripping coil 22 breaks down again. As a result, the snap disc will 24 move back to its first bistable position, causing the impact anchor 26 back to the starting position, as in 1 shown, moved back. The contact point 4 is now kept permanently in the open position by a rear derailleur.

In support of the recovery of the snap disc 24 after collapse of the magnetic field of the trip coil 22 as a result of the contact opening in the case of triggering in the embodiment according to 1 and 2 a return spring 46 appropriate. This is designed here as a spiral spring and includes the impact anchor 26 , But it could also be designed as a leaf spring or in any other suitable manner. The return spring 46 is in a non-triggered state ( 1 ) relaxed. It is supported at one end by a spring bearing connected to the housing 50 from, and with its other end to the central portion of the snap disc 24 , In the case of triggering ( 2 ), it is snapped by the snapped in its second bistable position 24 pressed together.

The switching device 1 in the embodiment according to 1 and 2 includes in addition to the electromagnetic release 20 another thermal overcurrent release. This is essentially formed from a bimetallic strip 44 , which with its first, fixed end 44 ' on a bimetallic bracket 48 is attached, and its second, movable end 44 '' in a recess 35 in the slide 34 one attacks. In the case of an overcurrent bends the bimetallic strip 44 in the direction indicated by the directional arrow B, so that the slider 34 in the direction of its longitudinal axis, indicated by the directional arrow S, is displaced and cooperates via a (not shown here) line of action with the (here also not shown) switching mechanism, which then the contact point 4 permanently opens. In the case of a short-circuit current, tripping takes place by means of the electromagnetic release 20 as described above.

In 3 is another embodiment of a trigger according to the invention 20a shown for use in a switching device according to the invention. The same or equivalent components or components are given the same reference numerals as in 1 respectively, supplemented by the letter a.

The trip coil 22a is wound up here on a cylindrical bobbin. The winding body consists of a magnetically non-shielding material, for example of a ceramic or a suitable plastic. At its end facing the contact point of the bobbin is bulged like a bulb, such that in its interior a cavity 55a arises, by the lateral boundary of the snap-action bearing 28a is formed and in which the snap disk 24a is recorded and stored. In an execution 58a at the contact point facing end side of the bobbin 56a is the anchor 26a guided smoothly. Also inside the cavity is the return spring 46a stored. The winding body 56a may for example consist of two halves divided longitudinally along the median plane of the winding body, between which the cavity forming parts after assembly the snap disc with the return spring and the impact armature is used before the two halves to the winding body 56a be assembled.

The winding body 56a is fixedly connected to the housing inner wall of the switching device, so that the storage of the snap disc not in the housing, but in the interior of the winding body 56a he follows. This creates a very compact release assembly few items.

Another embodiment of a trigger according to the invention 20b for use in a switching device according to the invention is in 4 shown. The same or equivalent components or components are given the same reference numerals as in 1 or 3 respectively, supplemented by the letter b. The embodiment according to 4 differs from the one after 3 insofar as the former in the bobbin 56b formed cavity 55b and thus the snap disc 24b inside the trip coil 22b located.

The in the 1 to 4 illustrated and described embodiments are an exemplary, non-exhaustive representation of possible inventive switching devices using an electromagnetic release with a snap body of a ferromagnetic shape memory alloy. It is also possible to produce switching devices according to the invention from all other switchgear variants with electromagnetic triggers known from the prior art by the use according to the invention of a ferromagnetic shape memory alloy for forming a snap body. In particular, an inventive trigger using a snap body of ferromagnetic shape memory metal with a suitable design of the elastic properties and the coupling with the impact anchor even without the return spring 46 . 46a . 46b be built and operated.

LIST OF REFERENCE NUMBERS

Claims (12)

Switching device ( 1 ) with a housing ( 2 ) and with at least one fixed and one movable contact piece ( 8th . 6 ) ( 4 ), and with an electromagnetic trigger ( 20 . 20a . 20b ), which has a trip coil ( 22 . 22a . 22b ) and a punch anchor ( 26 . 26a . 26b ), characterized in that the electromagnetic trigger ( 20 . 20a . 20b ) one with the impact anchor ( 26 . 26a . 26b ) operatively connected snap body ( 24 . 24a . 24b ) comprises a material having a magnetic shape memory effect, wherein under the influence of the magnetic field of the trip coil ( 22 . 22a . 22b ) in the short-circuit current case of the snap body ( 24 . 24a . 24b ) is reversed in two bistable positions. Switching device according to claim 1, characterized in that the snap body ( 24 . 24a . 24b ) is formed of a ferromagnetic shape memory alloy of nickel, manganese and gallium. Switching device according to one of claims 1 to 2, characterized in that the snap body ( 24 ) formed as a snap-action disc and at its outer periphery in a snap-action disc bearing ( 28 ) is held. Switching device according to one of claims 1 to 2, characterized in that the snap body ( 24a . 24b ) formed as a snap-action disc and within a the trigger coil ( 22a . 22b ) carrying coil winding body ( 56a . 56b ) is held. Switching device according to one of claims 1 to 4, characterized in that the snap disc ( 24 . 24a . 24b ) in the region of their center frictionally or positively with the impact anchor ( 24 . 24a . 24b ) connected is. Switching device according to one of claims 1 to 5, characterized in that the snap body ( 24 . 24a ) outside the trip coil ( 22 . 22a ) is mounted in their vicinity. Switching device according to one of claims 1 to 5, characterized in that the snap body ( 24b ) from the trip coil ( 22b ) is included. Switching device according to one of claims 1 to 7, characterized in that the snap element ( 24 . 24a . 24b ) with its reversing in the two bistable positions supporting return spring ( 46 . 46a . 46b ) is in operative connection. Use of a material having a magnetic shape memory effect in a trigger coil (US Pat. 22 . 22a . 22b ) and a punch anchor ( 26 . 26a . 26b ) having electromagnetic release ( 20 . 20a . 20b ) for a switching device ( 1 ), characterized in that the snap body ( 24 . 24a . 24b ) of the electromagnetic actuator comprising a snap body ( 20 . 20a . 20b ) is formed from the material having a magnetic shape memory effect, wherein under the influence of the magnetic field of the tripping coil ( 22 . 22a . 22b ) in the short-circuit current case of the snap body ( 24 . 24a . 24b ) is reversed in two bistable positions. Use of a material with magnetic shape memory effect according to claim 9, consisting of a ferromagnetic shape memory alloy nickel, manganese and gallium. Use of a material having a magnetic shape memory effect for short-circuit current tripping in a contact point ( 4 ) and an electromagnetic trigger ( 20 . 20a . 20b ) comprehensive switching device ( 1 ), characterized in that the snap body ( 24 . 24a . 24b ) of a trip coil ( 22 . 22a . 22b ) and a snap body ( 24 . 24a . 24b ) having electromagnetic release ( 20 . 20a . 20b ) is formed from the material having a magnetic shape memory effect, wherein under the influence of the magnetic field of the tripping coil ( 22 . 22a . 22b ) in the short-circuit current case of the snap body ( 24 . 24a . 24b ) is reversed in two bistable positions. Use of a material with magnetic shape memory effect for short-circuit current tripping according to Claim 11, consisting of a ferromagnetic shape memory alloy nickel, manganese and gallium.