FR2835648A1 - ELECTRIC SWITCHING DEVICE HAVING A FIRST SWITCHING CONTACT AND A SECOND SWITCHING CONTACT - Google Patents

Abstract

The device includes a first drive contact element (4) and a first homologous drive contact element (5), and a second contact switch (3) having a second drive contact element (6) and a second homologous drive contact element (7), in which each of the drive contact elements is driven by a combination of control elements (9) and a scanning element cooperating with the control element. The scanning element is connected to each of the drive contact elements and a common control element cooperating with the scanning elements, is adapted to be rotated by the drive element.

Description

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 The invention relates to an electrical switching device having a first switching contact, comprising a first driving contact element and a first homologous driving contact element, and a second switching contact comprising a second driving contact element and a second switching element. homologous drive contact, in which each of the drive contact elements is drive by means of a combination of a control element and a scanning element cooperating with the control element.

 A switching device of this type is for example taught in the publication DE 196 15 912. A device described in the publication comprises several switching contacts which are arranged inside a switch housing. The switching contacts are associated with control elements which include control contours in the form of a groove. The control contours cooperate with control elements. Said control elements are shaped as studs arranged on crank arms. The crank arms are rotatably mounted on a common shaft. The special shape of the control contours allows the movable contact elements of the switching contacts to move forwards and backwards when the control elements are rotating.

 The individual switching contacts are arranged offset along the shaft to guarantee sufficient freedom of movement of the mobile modules. In addition to the expensive mechanical structure, the axial offset of the switching contacts with respect to each other necessitates a large construction space.

 The object of the present invention is to conform an electrical switching device of the prior art so as to allow a more compact arrangement of the switching contacts.

As regards the electrical switching device of the aforementioned technique, the object is achieved according to the invention in that a scanning element is connected to each of the drivable contact elements and a common control element cooperating with the sweep is adapted to be rotated by a drive device
The use of a common control element, which is associated with each of the drivable contact elements, makes it possible to reduce the number of components necessary to drive the contact elements

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 drivable. It is possible to reduce the volume of construction by reducing the components. In addition, the common control element makes it possible to reduce the lateral offset and therefore the size of the arrangement of the switching contacts. Ideally, there is no lateral offset between the switching contacts. In this case, the movement tracks of the drivable contact elements are in the plane in which the common control element is able to rotate. In particular, simple conformations are possible when the scanning elements and the control elements have different construction principles. Grooves, slides or ribs as well as the spacing studs of the scanning elements and the slides are for example provided as control elements as well as associated scanning elements It can thus be provided that the modules which form the element control elements in a first construction are used in a second construction as a scanning element, that is to say that the terms control element and scanning element are not defined for a given conformation.

 Advantageously, provision may be made for a recess in one of the control elements or of the sweeping elements to be shaped as a control contour.

 A control contour is particularly suitable for generating specific movements. The control contour can then control the time and speed profile of a movement of the drive contact element. A configuration of the control contour in a recess is a variant of construction which is simple and robust.

The recess can then be shaped both in a groove or in a blind bore as in a through hole or in an opening filled with a material.

 Another advantageous configuration provides for conforming a projecting control contour provided on one of the control elements or of the scanning elements.

 A control contour formed as a protrusion can be scanned in several planes. A single control contour therefore makes it possible to sweep, for example both in height and laterally. Likewise, as in the case of a conformation of the control contour in a recess, a conformation of a protruding or rib control contour must also be evaluated as a robust construction.

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 Advantageously, provision may also be made for a portion of the control contour to control both the first and the second drivable contact element.

 The common use of a portion of the control contour makes it possible to reduce the overall size of the control contour. Particularly compact conformations are thus obtained for the control contour and consequently also more compact dimensions for the control element or the scanning element.

 It can also advantageously be provided for the control contour to block in determined positions of a drive contact element a movement of the other drive contact element.

 For specific switching contacts, it is necessary that these can only be used depending on the switching position of another switching contact. Thus, switching contacts intended to earth a busbar section should only be able to be switched if the busbar section has been previously isolated by means of another switching contact. Mechanical locking of the drivable contact elements is particularly suitable for making locks of this type.

 To guarantee particularly fast switching or also switching without interruption, it is advantageous to move, for example, one of the contact elements to bring it already into its position in contact, while the other drivable contact element is moved by its position still in contact in its off-contact position. It can also be provided to move each of the drivable contact elements at the same time or immediately one after the other from its contact position to the non-contact position, and vice versa.

 Advantageously, it can be provided that a portion of the control contour extends concentrically around the control element or the common drive element.

 Such an arrangement makes it possible in a simple way to maintain in position the movable contact elements in spite of a movement of the control element or of the rotary scanning element. This is particularly necessary when it is necessary to move still other modules by means of the drive device intended to drive the control element without moving the drivable contact elements. The concentric portion

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 also allows to maintain in a simple way a drivable contact element in its rest position, during the movement of the other drivable contact element.

 In addition, it can be particularly advantageous if the axis of rotation of the control element or of the common drive element is surrounded by a U-shaped control contour.

 A U-shaped control contour makes it possible to have a particularly very elongated control contour on a very compact surface which is capable of being swept. In particular when the center of rotation is inside the region limited by the sides of the U-shaped control contour, the space required for a rotational movement is limited to a small size.

Advantageously, provision may be made for the control element to comprise a slide and for the sweeping element to comprise a stud.
Sweeping and control elements of this type are inexpensive and reliable.

 An exemplary embodiment of the invention is described in detail below with reference to the drawings in which: FIG. 1 represents a variant configuration of an electrical switching device comprising a first switching contact and a second switching contact in a first switching state, FIG. 2 represents the first variant of conformation in a second switching state, FIG. 3 represents the first variant of conformation in a third switching state, and FIG. 4 is a schematic representation of a second variant of conformation.

 The electrical switching device 1 represented in FIG. 1 comprises as an initial switching contact an electrical disconnector 2 as well as as a second switching contact an earthing switch 3. The isolating switch 2 comprises a first contact element 4 which can be driven as well as 'a first homologous contact element 5. The earthing switch 3 comprises a second contact element 6 which can be driven as well as a second homologous contact element 7 The first contact element which can be driven 4 as well as the second contact element driven 6 have a substantially shaped outer contour

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 cylindrical. The first drive contact element 4 and the second drive contact element 6 are movable in translation along their cylinder axis. To bring the first drivable contact element 4 into electrical contact with the second drivable contact element 6, and guide said contact elements mechanically, the drivable contact elements 4,6 are concentrically surrounded by contacting and guiding elements 8a, 8b. Electrical conductors, which can be brought into contact with each other by means of the associated drivable contact elements 4,6, can be connected respectively to the homologous contact elements 5,7 as well as to the contacting and guiding elements 8a, 8b. The homologous contact elements 5,7 as well as the contacting and guiding elements 8a, 8b are shaped as a shell in order to control the electric field.

 A driving device, not shown, is intended to move the first driving contact element 4 as well as the second driving contact element 6. This driving device rotates a driving shaft 11 around an axis of rotation 10 A control element 9 is integral with the drive shaft 11. The control element 9 is substantially disc shaped. A slide 12 is inserted in the control element 9. The slide 12 is shaped as an opening entirely traversed by the control element 9.

 The faces, opposite to the homologous contact elements 5,7, of the drivable contact elements 4,6 each have a slot formed on the front side, extending through their longitudinal cylinder axes and intended to receive the control element 9 which extends parallel to the plane of the drawing. Through holes, extending perpendicular to the slots, are formed in the bifurcated ends formed by the slots. A first stud can be inserted and immobilized in the holes of the first drivable contact element 4. A second stud can be inserted and immobilized in the holes of the second drivable contact element 6. The arrow bearing the reference 13 indicates the place of insertion of the first stud. The arrow bearing the reference numeral 14 indicates the place of insertion of the second stud. In Figures 1 to 3, we omitted to represent the first stud and the second stud to bring out more clearly the slide 12 and its portion of the path 12a The first stud and the second stud are introduced into the holes

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 formed in the respective drivable contact elements 4,6 In addition, the first stud and the second stud are introduced into the opening of the slide 12 of the control element 9. The first stud and the second stud play the role of 'scanning elements in this conformation. The control element 9 is guided in the front slots of the drivable contact elements 4,6.

 A rotary movement of the control element 9 is now effected during a rotary movement of the rotation shaft 11 A movement of the slide 12 takes place accordingly. From the first switching state shown in FIG. 1 (disconnector 2 open, earthing switch 3 open), a rotation of the drive shaft 11 clockwise is first carried out in order to contact the earthing switch 3. A movement of the second drivable contact element 6 is carried out along its cylinder axis in the direction of the second homologous contact element 7 due to the U-shaped contour of the portion of trajectory 12a and of the cooperation of the second stud with the slide 12. The contact process of the earthing switch 3 is isolated when the second drivable contact element has reached the contact position (FIG. 2, second switching state) The concentric conformation of the trajectory portion 12a and of the slide 12 relative to the axis of rotation 10 makes it possible to maintain the first contact element 4 in its position out of contact t during the contacting process of the earthing switch 3. The contour of the slide 12 does not allow the first movable contact element 4 to move when the earthing switch 3 is in contact In other words, the first drive contact element 4 is locked.

If there is now an opening for the earthing switch 3 (FIG. 2), the drive shaft 11 and the control element 9, rigidly connected to the drive shaft 11, performs a rotation movement counterclockwise. The second drive contact element 6 is returned to its non-contact position (FIG. 1). The first drivable contact element 4 is also kept in its non-contact position.
If the earthing switch 2 is brought into contact, the drive shaft 11 is rotated counterclockwise from the first switching state (FIG. 1). The cooperation of the first stud with the slide 12 of the control element 8 now allows the

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 first drive contact element 4 to move from the non-contact position to the contact position. The bringing into contact of the first homologous contact element 5 makes it possible to isolate the process of bringing the disconnector 2 into contact (FIG. 3, third switching state) During the movement of the first drivable contact element 4, the second drivable contact element 6 is kept in its contactless position. The second stud then partially scans the same portion, arranged concentrically with the axis of rotation 10, of the slide just like the first stud during the process of bringing the grounding switch 3 into contact. When the disconnector 2 is contacted, contacting the grounding switch 3 is not possible. The second drive contact element 6 is locked by the slide 12 of the control element 9. To switch off the disconnector 2, the control element 9 must rotate clockwise.

 Figure 4 is a schematic representation of the same switching device as in Figures 1,2 and 3. Figure 4 shows an embodiment of the control element and the scanning element which is different from the first example of production. A lever 15 is now rigidly fixed to the drive shaft 11. The lever 15 comprises a lever stud 16. A first slide 18 of the second variant of configuration is disposed on the first drive contact element 17 of the second variant of conformation. The first slide 18 is mounted in the form of a groove in the surface of the end, flattened and opposite to the associated homologous contact element 5a, of the first drivable contact element 17 of the second variant. A second slide is mounted on the second drive contact element 19 of the second variant of configuration at the flattened end opposite the associated contact element 7a. Each of the drivable contact elements now includes a scanning element in the form of a groove. The lever stud 16 is provided as a common control element. From the switching state shown in FIG. 4, a movement in a counterclockwise direction makes it possible to introduce the lever stud 16 into the first slide 18 of the second variant of configuration and the cooperation of the first slide 18 with the lever stud 16 makes it possible to bring the movable contact element 17 of the second variant of conformation into its position in contact. A movement of the lever stud 16 in the direction

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 time now causes a reversal of the movement of the first drive contact element 17 of the second variant of configuration so that the switching state shown in Figure 4 can be obtained again. If the lever stud 16 is moved further clockwise, it then comes into active contact with the second slide 20 of the second drive contact element 19 of the second variant of conformation. The cooperation of the lever stud 16 with the slide 20 of the second variant of configuration makes it possible to bring the second drive contact element 19 of the second variant of configuration into its position in contact. When the direction of rotation of the shaft 11 is then reversed, an inversion of the switching movement of the second drive contact element 19 of the second configuration variant is carried out. As in the first variant of configuration shown in FIGS. 1 to 3, only one of the entrainable contact elements of the second variant of configuration is each time displaced during the rotation of the shaft.

Claims (9)

 CLAIMS 1. Electric switching device (1) having a first switching contact (2), comprising a first driving contact element (4) and a first homologous driving contact element (5), and a second switching contact (3 ) comprising a second drivable contact element (6) and a second homologous drivable contact element (7), in which each of the drivable contact elements (4, 6) can be driven by means of a combination of a control element (9) and a scanning element cooperating with the control element (9) characterized in that a scanning element is connected to each of the drive contact elements (4,6) and a control element (9 ) common cooperating with the scanning elements is adapted to be rotated by a drive device. 2. An electrical switching device (1) according to claim 1, characterized in that a recess in one of the control elements (9) or of the scanning elements is shaped as a control contour (12). 3. An electrical switching device (1) according to claim 1, characterized in that a control contour (12) has a projecting shape provided on one of the control elements or of the scanning elements. 4. Electrical switching device (1) according to one of claims 2 or 3, characterized in that a portion of the control contour controls both the first and the second drivable contact element (4,6) 5. Electrical switching device (1) according to one of claims 2 or 3, characterized in that the control contour (12) is shaped so as to lock in determined positions of one of the drivable contact elements (4, 6) a movement of the other entrainable contact element (6,4). 6. Electrical switching device (1) according to one of claims 2 to 5, characterized in that the drive contact elements (4,6) are partially mobile at the same time. 7. Electrical switching device (1) according to one of claims 2 to 6, characterized in that a portion of the control contour extends concentrically with the axis of rotation (10) of the common control element . <Desc / Clms Page number 10>  8. Electrical switching device (1) according to one of claims 2 to 6, characterized in that the axis of rotation (10) of the common control element (9) is surrounded by a control contour (12 ) U-shaped. 9. An electrical switching device (1) according to one of claims 2 to 8, characterized in that the control element (9) comprises a slide and the scanning element comprises a stud.