EP1276182A1 - Latch for residual current circuit breaker - Google Patents

Abstract

The switch mechanism has a switch-in button (10), cooperating with a linear displacement guide, for tensioning a switch-in spring (11), a pin (20) fitted in the switch-in button coupled to a resetting spring (50) providing a spring force with a component parallel to the linear displacement direction. The pin has a knee (21) cooperating with a retaining nose (31) of a switch bridge (30), the resetting spring separating the pin from the switch bridge by movement in a second direction. The resetting spring can be provided by the contact spring for the movable contact.

Description

TECHNICAL AREA

The present invention relates to the field of residual current protection. It affects a key switch for residual current devices and a residual current device with one Switch lock according to the preamble of claim 1.

STATE OF THE ART

Residual current protected plug or installation devices, such as safety plugs, safety intermediate plugs (Adapter) and safety sockets, prevent electrical accidents and Fires in electrical systems. They continuously monitor connected consumers and cut off the power supply before a fault current flows to earth can be dangerous for people, animals or things.

The functioning of a residual current circuit breaker is based on the fact that the magnetic flux of a differential current in the secondary winding of a summation current transformer one in one Wiring produces generated voltage which is above a threshold Magnetic release activated. By pressing a test button arrangement, a by the The size of a test resistor simulates a suitably dimensioned fault current that is intact Residual current circuit breaker causes the contact arrangement to open.

German Offenlegungsschrift DE 199 36 056 A1 describes a fault current protected Plug device shown, which combines compactness and simple manufacture. All functionally essential parts are easily accessible on a central molded part, the so-called support body. Parts of the test circuit and circuit are integrated as conductor tracks directly into the supporting body. With a safety socket it is possible, adapted to different national safety regulations and / or plug diagrams To produce variants by changing only one socket part, the actual one Residual current circuit breaker is adopted unchanged. Two switching points will be formed by a fixed and a movable contact, which with the consumer or network side are connected. The moving contact is on one attached free end of an electrically conductive leaf spring, and an insulating or Switching bridge mechanically connected to the other movable contact. When closed Switching points are held by an actuator that interacts with a trigger Switch bridge immediately fixed in a certain position, so that the moving contacts against the force of the then tensioned leaf springs against the fixed contacts be pressed. If a fault current occurs, the actuator is moved and disengaged the switching bridge while opening the switching points and led down.

PRESENTATION OF THE INVENTION

The object of the present invention is to provide a switching lock for residual current protective devices specify which is simple, space-saving and compact. This task is accomplished by a Switch lock for residual current devices with the features of claim 1 solved.

In the case of a switch lock according to the invention, the residual current device inhibits in the switched-on state an anchor a driver, which in turn is a switching bridge fixed and thus keeps a switching point closed. As soon as the device responds, the Anchor the driver free and a return spring counteracts one with a power button specified direction on the switching bridge and opens the switching point. core The invention is now the return spring for the previous separation of the driver and switch bridge to be used, which in a predetermined by the anchor Direction. The return spring is used to do this when the device is switched on cocked by pressing a power button.

In a first embodiment of the switch lock according to the invention, a separate return spring for opening the switching points or separating the driver and switching bridge dispensed with and led through the switching bridge for this purpose Contact springs, which are designed in particular as leaf springs, are used. Thereby the number of required parts of the key switch is reduced, which is therefore less expensive can be produced.

In a further embodiment, the driver and the switching bridge form a suitably inclined one or beveled adhesive surface, which deflects one in the tensioned Return spring allows stored spring force in a separating relative movement. It is therefore possible to use rollers with the driver and / or the switching bridge are connected to be waived.

Advantageously, drivers and switching bridge are designed so that they are in the Do not move the switch-on process relative to each other, i.e. that the angle between sticky surface and return spring does not change. This allows the adhesive forces that occur better predict and dose, so that the return spring is oversized is avoided. In this case, the switching bridge preferably moves parallel to Direction of movement of the power button and not on a segment of a circle.

Further advantageous embodiments emerge from the dependent patent claims.

BRIEF DESCRIPTION OF THE FIGURES

The invention is explained in more detail below on the basis of exemplary embodiments in conjunction with the drawings. Show it
1 to 4 in section a part of a residual current device according to the invention, each in different operating states.
5 an oblique view of part of a residual current device according to the invention, in an operating state corresponding to FIG. 2.

The reference symbols used in the drawings are summarized in the list of reference symbols. In principle, the same parts are provided with the same reference symbols.

WAYS OF CARRYING OUT THE INVENTION

1 shows a section of a switched off or inactive residual current device shown. For a better understanding of the spatial arrangement of the following described components is also referred to Fig.5. A power button 10 and a closing spring 11 are surrounded by a first guide element 12 and in one first direction R1 movable. A driver 20 is at one, the upper end with the Power button 10 connected and has an S-shaped knee 21. The other, on average 1 hatched lower end of the driver 20 is fork-shaped and interacts with an armature 41 controlled by a magnetic release or actuator 40. The lower end of the driver 20 and the armature 41 are movable in a second Direction R2, which is approximately perpendicular to the first direction R1. A switching bridge 30 comprising a nose-shaped pawl 31 and wing 32 is switched off in one State of the device corresponding to the switch-off position shown. Only those in Section of the hatch 31 shown hatched is actually in the section plane that Wing 32 are in front or behind. Guide the wings 32 of the switching bridge 30 electrically conductive contact springs 50 shown in dashed lines.

Movable contacts 51, which have fixed contacts, are fastened on the contact springs 50 52 together represent a switching point and in a switch-on position of the switching bridge 30 form an electrical contact between the network and the consumer. For the better Understanding the current paths is also referred to in FIG. 3. fixed contacts 52, magnetic trigger 40 and other, not shown, and for a circuit or components and / or conductor tracks belonging to a test circuit are on or under an electrically insulating support body 60 or a circuit board 61 fastened thereon. Power button 10, driver 20 and switching bridge 30 form the so-called Switch lock of the residual current switch.

In Fig. 2 the key switch is shown during the switch-on process. The power button 10 is pressed and the closing spring 11 is maximally tensioned or compressed. By the anchor 41, the knee 21 of the driver 20 is pulled to the left and is now below the pawl 31 of the switching bridge 30. The switching bridge 30 is still in the off position, i.e. there is no connection to the consumer connections not shown Tension. On the other hand, the mains connections of the device are live, because only in this case the actuator 40 is energized and pull the armature 41 into the left position can.

In Figure 5 the same situation is shown in oblique view, here the one with the clearly visible fork-shaped end of the driver 20 cooperating anchor 41 of clarity was omitted for the sake of it. Can be clearly seen in the present case two wings 32, 32 'of the switching bridge 30.

3 shows the residual current device in the switched-on state. After this When the power button 10 is released, the power spring 11 has relaxed again while doing so The switching bridge 30 is pulled upward into the switch-on position via the driver 20. The switching points are thus closed and a consumer is supplied with electricity. The guide element 12 also acts on the switching bridge 30 such that the latter is in a linear movement parallel to the movement of the power button 10 moves. Are the contact springs 50, which are only fixed on one side, in the wings which are also hatched 32 of the switching bridge 30 is not firmly connected to the latter, but only performed the circled support point 53 of the contact springs 50 changes with the movement the switching bridge 30 running.

Fig. 4 finally shows the residual current circuit breaker at the moment of tripping. At the A fault current occurs or as soon as the power supply is interrupted on the mains side the magnetic release 40 releases the armature 41. This then moves on right, but without necessarily moving the driver 20. The movement, which separates the driver 20 from the switching bridge 30, could be shown with a broken line indicated, more or less in the predetermined by the movement of the armature 41 Return spring 70 acting in the direction of R2 can be accomplished. According to the invention is now a return spring connected to the switching bridge 30 for separating the driver 20 and switching bridge 30 is provided, which at the same time ensures that after said Isolation, the switching bridge 30 is moved in the direction of R1 while opening the switching point. The spring force of such a return spring can in principle be along any between the Direction R1 and R2 lying direction, the return spring is by the switch-on process, i.e. relaxing the stronger closing spring 11, loaded.

In the present case, the tensioned when the device is switched on Contact springs 50 the role of the return spring. The spring force F1 of the contact springs 50 presses the switching bridge 30 down over the support points 53. Through a specially trained, 3 is circled in Figure 3 by this spring force F1 the driver 20 pushed away to the right, whereupon the switching bridge 30 down can move. The adhesive surface 71 is not necessarily a flat surface over which driver 20 and switching bridge 30 touch and which in the sectional drawings 3 is only recognizable as an S-shaped line in projection. To the one addressed To enable force conversion, it is sufficient that the adhesive surface 71 in the by the Directions R1 and R2 spanned plane (i.e. in the sectional plane of Fig. 1-4) one has an average inclination which lies between the two directions R1 and R2. Essential is also that at no point of the adhesive surface 71 said inclination is vertical to the direction of the spring force F1.

In the present case, the contact spring 50 is designed as a leaf spring, but it can be just as well can be realized by a spiral spring. It doesn't necessarily have to be itself be electrically conductive, the movable contact 51 carried by them can also via a additional, non-self-resilient conductors can be produced. The adhesive surface 71 respectively the surfaces of the driver and the switching bridge that form them are to be realized the required adhesive and frictional forces, especially smooth or slippery educated. The residual current device is either a residual current protected socket intended for permanent installation with permanent wiring of the mains connections or as a mobile residual current protected adapter. The latter is on the network side equipped with pluggable connections and especially for retrofitting existing electrical installations.

LIST OF REFERENCE NUMBERS

10

Power

11

Closing

12

guide element

20

takeaway

21

knee

30

jumper

31

pawl

32

wing

40

magnetic release

41

anchor

50

Konaktfeder

51

movable contacts

52

fixed contacts

53

support point

60

supporting body

61

circuit board

70

Return spring (state of the art)

71

adhesive surface

Claims (7)

Switch lock for a residual current device, comprehensive a) a switch-on button (10) with a switch-on spring (11), which switch-on button (10) can be guided linearly in a first direction (R1) by a guide element (12), and which switch-on spring (11) is initially tensioned and then relieved during a switch-on process becomes, b) a driver (20), which is installed on one side in the power button (10), c) a switching bridge (30) for guiding at least one contact spring (50) carrying a movable contact (51), d) a return spring element (50) which is connected to the driver (20) and whose spring force (F1) has a force component parallel to the first direction (R1), characterized in that e) the driver (20) can be guided in a second direction (R2) different from the first direction (R1) through an armature (41) of a trigger (40) and has a shaped knee (21), f) the switching bridge (30) has a nose-shaped pawl (31) into which the knee (21) of the driver (20) can be hung, and g) the return spring element (50) is a means for separating the driver (20) and switching bridge (30) in the second direction (R2). Key switch according to claim 1, characterized in that the return spring element (50) is the contact spring (50). Switch lock according to claim 1, characterized in that the pawl (31) of the switching bridge (30) and the knee (21) of the suspended driver (20) touch along a common adhesive surface (71) which is not perpendicular to the first direction (R1) is aligned. Key switch according to claim 3, characterized in that the pawl (31) and the knee (21) remain in the same position relative to each other when the switch-on spring (11) is relaxed and the common adhesive surface (71) does not change. Switch lock according to Claim 4, characterized in that the switching bridge (30) can be guided in the first direction (R1) by the first guide element (12) and moves parallel to the switch-on key (10) when the switch-on spring (11) is released. Residual current device with a switch lock according to one of claims 1-5. Residual current device according to claim 6, characterized in that the residual current device is a mobile residual current protected adapter.

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