EP1949399A1

EP1949399A1 - Magnetostrictive electrical switching device

Info

Publication number: EP1949399A1
Application number: EP05806784A
Authority: EP
Inventors: Patrick Claeys; Joachim Becker; Ralf Weber; Richard Kommert
Original assignee: ABB AG Germany
Current assignee: ABB AG Germany
Priority date: 2005-11-15
Filing date: 2005-11-15
Publication date: 2008-07-30
Also published as: CA2624387A1; US20080284547A1; WO2007057030A1; CN101390180A

Abstract

The invention proposes an electrical switching device having at least one contact point having at least one drive, which opens the contact point directly and/or via a switching mechanism with a latching point and which drive has an element having a predetermined shape, which element consists of a shape memory alloy, which changes its shape under the influence of an electromagnetic field and, in the process, opens or closes a contact point or double contact point or unlatches a switching mechanism.

Description

MAGNETOSTRICTIVE ELECTRIC SWITCH

description

The invention relates to an electrical switching device having at least one contact point, which is opened by means of an actuator directly or via a switch lock with a Verklinkungsstelle, wherein actuator opens the Verklinkungsstelle and / or the contact point.

Electrical switching devices in this sense are Leitungsschulzschalter, residual current circuit breaker, motor protection switch and the like and contactors.

In circuit breakers, a switching mechanism is present, which has a Verklinkungsstelle, on the one hand by a thermal release, such as a bimetallic strip or a strip of a shape memory alloy is unlatched, so that the contact point is opened; the thermal release triggers when an overcurrent occurs. Since a circuit breaker must also switch off short circuits, an electromagnetic release is further provided which has a coil, a magnetic yoke, a magnetic core and an armature; If necessary, the armature strikes the contact lever of the circuit breaker via a spindle or rod and actuates the latching point via a coupling designed as a slide so that the contact lever is held in the open position after the contact lever has been opened by the armature because the latching point is unlatched. Miniature circuit breakers have to fulfill their task under load or when a short-circuit current occurs.

The same applies to motor-protective circuit-breakers. In these, however, the contact point is replaced by a double contact point, wherein two fixed contact pieces are provided, which are bridged by a contact bridge. In case of short circuit, the contact bridge is spent by the electromagnetic release in the open position and simultaneously solved the Verklinkungsstelle; due to an overcurrent will be like the circuit breaker exploited the deflection of a thermal release to open the Verklinkungsstelle.

Residual current circuit breakers have the task of opening a contact point when a fault current occurs. Since the feeder current is generally in the milli-ampere range, an electromagnetic release, as intended for a circuit breaker, at least in a mains voltage-independent release can not be used. The detection of a fault current via a residual current transformer, wherein the lines form the primary winding. The converter is associated with a secondary winding which is connected to an electromagnetic trigger. Such a trigger usually has a U-shaped yoke, the leg ends are covered by a hinged armature, which is acted upon by a spring permanently in the Ausschalttrichtung. The yoke is associated with a permanent magnet which generates a permanent magnet flux in the yoke, by which the armature is held in the closed position, that is, in a position in which the armature rests on the Jochschenkelenden. Via a coil associated with the yoke, which surrounds one of the yoke legs or the web, the voltage originating from the secondary winding of the converter is converted into a magnetic flux, which is directed opposite to the magnetic flux generated by the permanent magnet. As a result, the force of attraction on the armature is reduced and the armature is moved by the spring into the open position, whereby a latching mechanism is unlocked via a pin coupled to the armature so that the switching contacts of the residual current circuit breaker are brought into open position. The problem with such a trigger may be that an opening of the hinged armature is sometimes not possible, because on the yoke, from which the armature is withdrawn, due to environmental influences and other influences, a bonding process is possible, so that a residual current circuit breaker even when they occur of a fault current does not trip. Due to the sensitivity of such a trigger, it is also necessary to use this in a housing which must be sealed from the environment. However, it can not be prevented that moisture and the like can enter the interior of the housing through the opening through which the pin is guided to the outside. For this reason, it is recommended by all RCCB manufacturers to test the fault current by pressing a test button; The test button simulates a fault current that causes a tripping current in the secondary winding and in the Magnetic release associated coil is generated, so that the residual current circuit breaker is turned off.

Instead of such a permanent magnet release, a so-called magnetic trigger can also be used. In this holding magnet release, a yoke is present, which has a comparatively narrow portion in which, when a fault current occurs, the material reaches saturation, so that the armature can be pulled off the yoke by means of a spring.

In any case, the execution of such an electromagnetic release is quite expensive.

Electrical switching devices that only switch on and off are referred to as contactors, which usually iron a U- or E-shaped magnetic core, which is associated with an anchor, wherein the yoke is associated with a winding that attracts the armature when passing an electric current or a dropping de anchor generated, whereby a contact point can be opened or closed. In general, these contactors double contact points are provided, which are each bridged by a contact bridge.

All types of drives are fundamentally different in principle, with only similarities in a circuit breaker and a motor protection switch are present. However, a trigger for a residual current circuit breaker is neither suitable for a contactor nor for a circuit breaker; conversely, an electromagnetic trip device, which may be housed in a circuit breaker, at least suitable for a residual current circuit breaker, when the trigger is to address mains voltage independent.

The object of the invention is to provide a trigger that can be used for all types of such switching devices, the basic design should be the same and adjustments can be made only on the current.

This object is achieved by the features of claim 1. Thus, according to the invention, the actuator comprises an element of a predetermined length consisting of a shape memory alloy that changes its length under the influence of an electromagnetic field.

In this case, the element may be located in direct proximity to an electromagnetic field generating device, so that this field affects the element.

In another advantageous embodiment, the device may be a coil which surrounds the element formed as an elongate spindle.

Such shape memory alloys are known from WO 98/08261, see p. 2 - 5, end of the second paragraph. It is also indicated at which electric field strength the material responds; about applications is initially not stated.

Another document describing such shape memory alloys. have been published under number WO 99/45631.

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

Reference to the drawing, in which some embodiments of the invention are shown, the invention and further advantageous refinements and improvements and other advantages will be explained and described in detail.

Show it

1 is a switching device in a schematic representation in closed position,

2, the switching device of FIG. 1, in, off state,

3 is a schematic representation of a residual current circuit breaker,

4 is a schematic representation of a contactor in the on position,

Fig. 5 is a remote drive for an electrical switching device and

6 shows a remote drive according to a further embodiment of the invention

Reference is made to FIG. 1. In Fig. 1, a switching device 1 is schematically shown with a housing 2, an electromagnetic release 20 and a switching mechanism 36 in the untripped condition. In Fig. 2, the switching device of FIG. 1 is shown in the tripped state, wherein the same or similar-acting assemblies or parts are designated by the same reference numerals. Between an input terminal 14 and an output terminal 16 a current path via a movable strand 18, a mounted in a contact lever bearing 12 contact lever 10, a located on the contact lever 10 movable contact piece 6 and a fixed contact piece 8 comprehensive contact point 4, and a trip coil 22 runs. In the switching position shown in Fig. 1, the contact point 4 is closed. With the trip coil 22 and the fixed contact piece 8, a yoke 40 is connected via an oh-renförmigem intermediate piece 42.

Not shown in some switching devices additionally contained thermal release, which acts on occurrence of an overcurrent to the rear derailleur, so that this then permanently opens the contact point.

The electromagnetic actuator 20 includes the trip coil 22 and a trip arm 24, which is here bar-shaped and arranged inside the trip coil 22 so that the coil longitudinal axis and the trip anchor longitudinal axis coincide.

At a first, fixed end 24 ', the trigger armature 24 is held in a trigger armature bearing 28 connected to the housing 2. At its second, free end 24 "of the trigger armature 24 is in operative connection with a plunger 26. The operative connection is shown here as a positive connection, but alternatively, non-positive or cohesive connections can be realized.

At its free end 24 ", the tripping armature 24 has a notch 25 into which engages a tripping lever 30 mounted in a tripping lever bearing 32, for example with a fork located at its first free end 30. The second free end 30" of the tripping lever 30 engages in a recess 35 in a slide 34, which is in operative connection with the rear derailleur 36 via a line of action 38.

The trigger anchor 24 is made of a ferromagnetic shape memory alloy based on nickel, manganese and gallium. Such ferromagnetic shape memory alloys are known in principle and available, they are 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 Niβs-x- _y Mn ₂₀₊ χGa i _{5 + y} , where x is between 3 atomic percent and 15 atomic percent and y is between 3 atomic percent and 12 atomic percent , The ferromagnetic shape memory alloy used herein has the property that in its martensitic phase, that is, the phase occupying the material below the thermal transition temperature, a transition occurs between two crystal structure variants of a twin crystal structure under the action of an external magnetic field on a microscopic scale is associated macroscopically with a change in shape. In the embodiment of the release anchor chosen here, the change in shape is in a linear strain in the direction of the longitudinal axis of the beam.

The thermal transition temperature in the ferromagnetic shape memory alloys used here is in the range of room temperature and can be adjusted by varying the atomic percentages x and y within a bandwidth. Thus, the working temperature range within which the electromagnetic actuator operates within a range by selecting the material composition is adjustable.

Flows through the switching device 2 in the event of a short circuit, a high short-circuit current, the trip armature 24 expands due to the effect described above, and as a result, the plunger 26, the movable contact piece 6 away from the fixed contact 8, so that the contact point 4 is opened and triggered the switching device is as shown in Fig. 2. The expansion of the ferromagnetic shape memory material happens very quickly and almost without delay. The delay time as the time difference between the occurrence of the short-circuit current and the maximum length of the trip armature 24 is typically on the order of one millisecond.

The triggering is supported here by the release lever 30, which rotates in the extension of the trigger armature 24 in a clockwise direction about the trigger lever bearing 32 while the slider 34 in its longitudinal direction, indicated by the direction arrow S, shifts, so that the slide 34 on the Wirklinie 38 the rear derailleur 36 is actuated. After the 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 trigger armature 24 will contract again to its original dimensions, whereby the trigger lever 30 is moved back to the starting position, as shown in Fig. 1, back. The contact point 4 is now kept in the open position by operating lines, not shown here, by the switching mechanism 36.

Fig. 3 shows a residual current circuit breaker, in a schematic representation.

A schematic representation of this arrangement is shown in FIG. 13. Through a transducer core 60 primary conductors 61 and 62 are passed, which contact points 63 and 64 have. Arranged around the transducer core 60 is a secondary winding 65, which is connected to a coil 66 in which a plunger 67 made of a material having a magnetic, but possibly also a magnetic and thermal shape memory effect, is penetrated. This plunger 67 acts according to the direction of arrow P1 on a switching mechanism 68 and after unlatching the switching mechanism corresponding to the direction of the arrow P2 acts on the contact points 63, 64. Compared to the arrangement of Figure 1, the plunger 67 in Figure 1 has the reference numeral 24. 1, the reference numeral 36, the coil 66 in the arrangement of FIG. 1, the reference numeral 22, and, as can be seen, lacks a plunger element 26, because a direct action on the contact points 63, 64 at a Such residual current circuit breaker is not common.

Reference is now made to FIG. 4.

Fig. 4 shows a contactor or parts of a contactor 70 with two spaced apart, arranged on contact carriers 71 and 72 fixed contact pieces 73 and 74, which are bridged by a contact bridge 75, are mounted on the movable contact pieces 76, 77. Fig. 4 shows the contactor 70 in the on state, when the contact pieces 73, 76; 74, 77 touch.

Coupled to the contact bridge is a plunger 78 made of a material having a magnetic shape memory effect, which is designed as a longitudinally extending plunger whose one end is connected via a contact current spring 79 to the contact bridge 75 and whose other end is mounted in a bearing 80 which is mounted in a housing. is held stationary. The plunger 78 is surrounded by a solenoid system 81.

Now, if the switch is to be opened, then deforms the material of the plunger with the electromagnetic shape memory effect; Of course, there is also the possibility that in the normal state, ie in the de-energized state, the plunger 78 is arranged so that the contact points 73/76; Due to a control current, the plunger will expand due to the magnetic shape memory effect due to the magnetic field generated by the coil 81, and close the contact points, the contact pressure spring 79 is pressed slightly together when switched on in the usual way.

In the embodiment of FIG. 5, a ram 82 of magnetic shape memory material is surrounded by a coil 83, the coil 83 being energized via access lines 84 and 85 via a high pass formed by a capacitor 86 and a resistor 87. When the plunger 82 expands due to the magnetic field, it actuates a contact lever 88 and opens a contact 91 formed from a movable contact lever 88 and a fixed contact 90.

Fig. 6 shows an insight into a circuit breaker, with only the significant parts of the invention are shown.

The circuit breaker has a total of the reference numeral 92 with a front front surface 93, from which the switching handle 94 protrudes at 95 rotatably mounted switch knob 96. The switching handle 94 is formed on a rotatable hub 97. Mounted at hub 97 at 98 is a plunger 99 which is coupled to an elongated member 100 of magnetic shape memory material. The element 100 is surrounded by a coil 101, and when current flows, the length of the element 100 changes, so that the plunger 99, the hub 97 and thus the switching handle 94 is actuated. Since in a circuit breaker usually the switching handle is linked and connected to the switching mechanism, the switching device is switched on in this way via the element 100 with the plunger 99.

Claims

claims

1. Electrical switching device having at least one contact point with at least one drive, which opens the contact point directly and / or via a switch lock with a latching point, characterized in that the drive comprises an element having a predetermined shape, which consists of a shape memory alloy, which changes its shape under the influence of an electromagnetic field and thereby opens or closes a contact point or double contact point or unlocks a switching mechanism.

2. Electrical switching device according to claim 1, characterized in that the element is located in close proximity to an electromagnetic field generating device, so that the field influences the element.

3. Electrical switching device according to claim 2, characterized in that the device is a coil which surrounds the elongated spindle formed as an element.

4. Electrical switching device, characterized in that the element changes its length or is twisted.

5. Electrical switching device according to one of the preceding claims, comprising a switching mechanism, a movable contact lever with a movable contact piece, which cooperates with a fixed contact piece, characterized in that the element changes its shape under the influence of an electromagnetic field generated by a short circuit.

6. claims according to one of claims 1 to 4, characterized in that the element changes its shape under the influence of a generated by a fault current electromagnetic field.

7. Electrical switching device according to one of claims 1 to 4, characterized in that the element is part of a contactor, which changes its shape under the influence of an electromagnetic field generated by a surge.

8. Electrical switching device, which is switched on or off by an electrical pulse fem, characterized in that the under the influence of an e- lektromag genetic field due to a shock pulse shape changing element for switching off or on a contact lever and / or the switching handle also acts to its switching on and off.