The invention relates to an electric switching device with a first contact piece, a second contact piece, a first kinematic chain for the driving of the first contact piece, and a second kinematic chain for the driving of the second contact piece.
An electric switching device of this type is known, for example, from European Patent specification EP 1109185 B1. The electric switching device described therein is provided with a first and a second contact piece. The first contact piece is associated with a first kinematic chain. The second contact piece is associated with a second kinematic chain. The two contact pieces can be driven by means of the respective kinematic chains. By this arrangement, motive power can be communicated individually to each of the two contact pieces. Accordingly, the movements of the two contact pieces can be mutually synchronized in a simplified manner. Although this permits the simplified synchronization of movements, the axial span of the switching device is increased. In particular, this encumbers integration in existing installations.
A resulting object is therefore the proposal of an electric switching device with improved switching properties which can be incorporated into existing installations.
According to the invention, this object is fulfilled by an electric switching device of the above-mentioned type comprising a first switching point and a second switching point, which are connected in series, wherein the first contact piece is associated with the first contact point and the second contact piece is associated with the second contact point.
An electric switching device is a device which is used for the opening or closing of an electric current path. The first and second contact pieces are thus configured in a moveable arrangement, in order to permit the completion of a switching operation. The first and second contact pieces may be moveable in relation to each other. A switching operation may be completed by the interaction of the two switching points. A switching operation may constitute, for example, a “making operation” or a “breaking operation”. Although the first and the second contact pieces are constituent elements of an electric switching device, the two switching contact pieces may be associated with different switching points on the electric switching device. Advantageously, the two switching points should be electrically connected in series, whereby the first contact piece is associated with the first switching point and the second contact piece is associated with the second switching point. In a switching operation, both the first switching point and the second switching point may be actuated. This means that, in a breaking operation, both switching points may be opened, such that two series-connected break sections are formed at the switching points. Conversely, in a making operation, the first break section at the first switching point and the second break section at the second switching point are switched through, such that a closed current path on the electric switching device is formed via the first switching point and the second switching point. The first kinematic chain can be used to drive the first contact piece of the first switching point, and the second kinematic chain can be used to drive the second contact piece of the second switching point. Accordingly, each of the kinematic chains can control one of the switching points of the electric switching device and, in a mutually independent mechanical arrangement, actuate a movement of the moveable contact pieces (both the first and the second contact pieces). By this arrangement, it is possible for the motive power to be transmitted via each of the two kinematic chains to be reduced. For example, it is possible for each of the two kinematic chains to be configured with reduced dimensions, as each of the two kinematic chains is only required to deliver part of the necessary movements required for the switching of the electric switching device. In particular, it may be provided that both the first contact piece and the second contact piece are continuously maintained at one and the same electrical potential. However, the two contact pieces may be mutually arranged to move in relation to each other. In particular, during a switching operation, the motion delivered by the respective kinematic chain may drive the two contact pieces in opposite directions. In particular, it may be provided that the two contact pieces execute a linear motion, whereby the axes of motion of the first and second contact pieces lie in a near-parallel axis. In particular, the axes of motion may be configured in a mutually coaxial arrangement. The two contact pieces may respectively comprise a rated current contact piece or an arcing contact piece, or a combined rated current and arcing contact piece. In this case, the function of an arcing contact piece is essentially the conduction of an arc, in order to protect a rated current contact piece associated with the respective arcing contact piece against erosion. The function of the rated current contact pieces is the conduction of current. A protective function of this type may be achieved by the mutual contact of the arcing contact pieces in advance of the rated current contact pieces, such that pre-arcing occurs on the arcing contact pieces and, upon the contact of the rated current contact pieces, a low-arc switching of current from an arcing contact piece current path to a rated current contact piece current path is executed. In a breaking operation, conversely, it may be provided that the rated current contact pieces are separated first, such that a current flowing in the rated current contact piece current path is switched to the arcing contact piece current path and, upon the separation of the arcing contact pieces, any arc ignited is directed to the arcing contact pieces. An arrangement of this type is known, for example, in high-voltage power switches. However, it may also be provided that the first and/or the second contact piece combine a rated current function with an arcing function, such that the provision of separate arcing contact pieces and rated current contact pieces is not required.
By dividing a contact gap in the electric switching device into a first switching point and a second switching point, it is possible, for example, to divide switching arcs generated between a number of contact gaps, such that the simplified extinction of said switching arcs is facilitated accordingly. Moreover, each of the switching points can be optimally designed in respect of its anticipated respective switching arc, such that each of the switching points is only required to control a partial arc. Correspondingly, further to the extinction of an arc in the two break sections, an expanded contact gap is formed, as the two break sections are electrically connected in series. Moreover, the respective throw of the two contact pieces, which are moveable by means of the two kinematic chains, is reduced in relation to a simple and correspondingly expanded switching point. A twin drive arrangement of the two contact pieces also provides a simple option for increasing a contact break speed, such that an electrically isolating contact gap in the electric switching device is achieved more rapidly. Moreover, by means of division into a number of break sections, the mass of the moving components in each kinematic chain can be reduced, such that the motive power to be transmitted via the two kinematic chains can be reduced accordingly. In particular, it should advantageously be provided that the two switching points are of identical construction such that, for example, both the first and the second contact pieces can be of identical design. For example, the two switching points can be identically configured by the configuration, for example, of two identical switching devices arrange in opposite directions, such that the first contact piece and the second contact piece are permanently in mutual and electrically conductive contact. For example, the two switching devices may be mounted, at least partially, on a series-contacting node point of the two switching points.
It may also be advantageously provided that the first switching point is configured with a third contact piece and the second switching point is configured with a fourth contact piece, whereby the first contact piece is moveable in relation to the third contact piece, and the second contact piece is moveable in relation to the fourth contact piece.
For the configuration of the first switching point, a third contact piece is associated with the first contact piece. For the configuration of the second switching point, a fourth contact piece is associated with the second contact piece. The first contact piece and the third contact piece should be of diametrically opposite design. The second contact piece and the fourth contact piece should also be of diametrically opposite design, such that galvanic contact between the first and the third contact piece, or between the second and the fourth contact piece, is possible. To this end, at least the first and the second contact pieces should be moveable, and mounted for propulsion by the respective kinematic chain such that, at both the first switching point and at the second switching point, a break section can be formed for the electrical isolation of the first and third contact pieces, or of the second and fourth contact pieces. The third and fourth contact pieces, for example, may be arranged in a stationary position. For the generation of a relative movement between the first and third, or between the second and fourth, contact pieces it may also be provided that the third contact piece is mounted in a moveable arrangement and/or that the fourth contact piece is mounted in a moveable arrangement. Accordingly, at the first and/or at the second switching point, it is possible to execute a switching motion by a movement of the first and third or of the second and fourth contact pieces.
As a result, for example, the contact opening speed or contact closing speed between the first and third contact pieces at the first switching point and/or between the second and fourth contact pieces at the second switching point can be further increased. For example, the first contact piece, which is actuated by means of the first kinematic chain, may be associated with an insulating material component which communicates a movement from the first switching point to the third contact piece. Likewise, on the second switching point, provision may be made for the use of an insulating material component which communicates a movement from the second contact piece via the second switching point to the fourth contact piece. Preferably, a gearing arrangement is applied in each case which converts the movement of the respective insulating material component, in particular by the inversion thereof, such that an inverse movement between the first and third or between the second and fourth contact pieces is dictated accordingly. In each case, for example, the insulating material component employed may be an insulating material nozzle which surrounds a switching point, or at least sections thereof. The insulating material nozzle can also be used to control a flow of a switching gas. For example, switching gas may be fed via the insulating nozzle to the area of the contact gap, such that any arc ignited at this location in association with a breaking operation is blown-out and cooled. It is therefore possible that each of the two switching points is provided with contact pieces which are moveable in relation to each other, whereby the contact pieces arranged respectively on either side of the respective switching point are set in motion during a switching operation. Accordingly, the contact opening speed at each of the two switching points can be further increased and, overall, the switching speed of the electric switching device which is provided with the two series-connected switching points can be increased.
Advantageously, it may be provided that the first contact piece and the second contact piece are arranged to move relatively to each other.
The first and the second contact pieces may be arranged to move relatively to each other. In particular, the two contact pieces may be mounted to move in opposite directions. By this arrangement, for example, it is possible, centrally on the electric switching device, to combine a movement of the first kinematic chain and a movement of the second kinematic chain in the electric switching device and, in the area of electrical contact (node point) of the two switching points, to communicate a movement to branches of the electric switching device which incorporate the first switching point or the second switching point. Accordingly, an essentially symmetrical electrical switching device can be produced, the axially opposite ends of which can be maintained free of driving means of the kinematic chain. The driving means/kinematic chains preferably engage with the electric switching device in radial directions. The electric switching device should preferably extend longitudinally in an essentially cylindrical arrangement (for example, a cylindrical base component), with a shell-side coupling of the kinematic chain or a shell-side arrangement of driving means. Accordingly, the end faces of the electric switching device can be maintained free of driving means or kinematic chains.
In a further advantageous configuration, it may be provided that the first kinematic chain and the second kinematic chain operate in a mutually independent mechanical arrangement.
Independent operation of the kinematic chains ensures that each of the two switching points can be controlled and moved in an independent mechanical arrangement from the other switching point. For example, movements on each of the two switching points can be synchronized, independently of each other. In particular, in the event of malfunctions on one of the kinematic chains, the other kinematic chain can remain in service. In a breaking operation, for example, it is therefore possible for at least one of the switching points to be opened by one of the kinematic chains, whereas the other switching point may be blocked in a fault position. To this end, the kinematic chains are mechanically independent of each other. By means of further devices, however, for example control devices, the movements of the kinematic chains can be synchronized relatively to each other. For example, a control device may compare progress in the movement of one of the kinematic chains with the progress of the other kinematic chain, thereby ensuring a secure switching of the electric switching device.
It may also be advantageously provided that the first kinematic chain is provided with a first driving means and the second kinematic chain is provided with a second driving means.
The function of the first kinematic chain is the communication of a movement to the first contact piece. The function of the second kinematic chain is the communication of a movement to the second contact piece. The function of a kinematic chain is the transmission of a movement from a driving means of said kinematic chain to at least the first or the second contact piece. The driving means in the respective kinematic chains are designed for the generation, retention, intermediate storage or delivery of motive power. Appropriate driving means may include, for example, hydraulic driving means, electric driving means or mechanical driving means, such as spring-loaded drive systems. From the driving means, the respective kinematic chain is routed to at least the first or the second contact piece. Where applicable, the kinematic chain may be extended to further components including, for example, the third or fourth contact piece, a moveable shield electrode, a moveable compression device, etc. A kinematic chain may show a wide variety of configurations. For example, the kinematic chain may be provided with transmission rods, reversing levers, gearing, toothed wheels, cable pulls, toothed racks, etc., such that a movement generated by one of the respective driving means is transmitted, either correspondingly or reciprocally, by the action of gearing in the kinematic chain, to the first or the second contact piece.
In a further advantageous configuration, it may be provided that the first driving means and the second driving means are configured in a diametrically opposite arrangement to an axis of symmetry of the electric switching device.
A diametrically opposite arrangement of the two driving means relative to an axis of symmetry has the advantage that units of identical design can preferably be used for both the first and the second driving means. A symmetrical design permits a compact arrangement for the transmission of a movement from the first or second driving means via the respective kinematic chain to the respective contact piece. For example, the diametrically opposite arrangement of the driving means may be analogous to a diametrically opposite arrangement of the first and second switching points. For example, it is therefore possible, in the area of the series connection (node point) of the first and second switching points, to transmit a movement to both the first and the second contact pieces. In a corresponding diametrically opposite arrangement, the two contact pieces can move in opposite directions relative to the axis of symmetry.
In a further advantageous configuration, it may be provided that opposing movements are communicated by the kinematic chains to the first and second contact pieces.
By the opposing movement of the first and second contact pieces, it is possible for electric switching devices to be configured as compactly as possible, whereby, by the opposing movement of the two contact pieces during a switching operation, movement can be communicated centrally between the two contact pieces. An opposing movement may be linear, circular, swiveling, etc.
In a further advantageous configuration, it may be provided that the two kinematic chains are mechanically separated from each other, wherein the movements thereof are synchronized.
As a result of a mechanical separation of the two kinematic chains, mechanical faults on one kinematic chain cannot be transmitted to the other kinematic chain. For example, an immobilization of one kinematic chain will not cause consequential damage in the other kinematic chain. It is therefore still possible, for example, notwithstanding a mechanical fault on one of the kinematic chains, for the mechanism of the other kinematic chain to be actuated. Synchronization of both movements of the kinematic chain is advantageous, in order to prevent any overloading of one of the switching points. By the interaction of the two contact pieces of the two switching points, it is possible for a switching operation (making operation; breaking operation) to be controlled by the electric switching device. For example, sensors may be used to detect progress in a movement of one of the kinematic chains. Where applicable, in the event of a deviation in the movements of the contact pieces from predetermined patterns of movement, a characteristic associated fault can be identified in advance, such that the electric switching device, for example, may be locked out for further switching operations as a precautionary measure.
In a further advantageous configuration, it may be provided that the connection of the kinematic chains to the respective contact piece is effected between the switching points.
The area between the switching points is the area (for example the central node point) in which contact is formed by the switching points for the formation of a series connection. The two switching points should preferably be configured in a mutually spaced arrangement on a longitudinal axis, whereby movements of the kinematic chain are communicated to the first or second contact piece between the two switching points in relation to the longitudinal axis. This area between the two switching points is the area in which the two switching points, by means of electrical bonding, are maintained in continuous mutual conductive electrical contact, such that contact pieces which are bonded with said area, and which are moveable by means of the first or second kinematic chain, will also be at the same electrical potential. Accordingly, this area is a central area in the axial profile of the electric switching device, in relation to the longitudinal axis.
Hereinafter, one exemplary embodiment is schematically represented in a drawing and is then described in greater detail. Herein:
In the interior of the housing 1, the two phase conductors 5a, 6a may be mutually electrically bonded or separated at the first switching point 2 and the second switching point 3. To this end, the two switching points 2, 3 are electrically connected in series via a central node point 7. On the central node point 7 of the electric switching device, a first contact piece 8 and a second contact piece 9 are, firstly, electrically bonded with the node point 7 and, secondly, are mounted to permit axial displacement relative to the node point 7. The two contact pieces 8, 9 are of identical design. Schematically,
The first and second contact pieces 8, 9 are permanently bonded in a mutually electrically conductive arrangement via the second node point. For example, the contact pieces 8, 9 may be electrically bonded with the node point 7 by means of a sliding contact arrangement. On the first switching point 2, a third contact piece 11 is arranged opposite the first contact piece 8. Analogously, on the second switching point 3, a fourth contact piece 12 is arranged opposite the second contact piece 9. The third and fourth contact pieces 11, 12 are of diametrically opposite design to their associated respective first or second contact pieces 8, 9. In this case, the third contact piece 11 and the fourth contact piece 12 are configured as bushes, with which the relatively moveable contact piece 8 or the relatively moveable contact piece 9 are designed to engage, for the purposes of bonding. In this case, the third contact piece 11 and the fourth contact piece 12 are mounted in a stationary arrangement and are electrically insulated from the housing 1. The third contact piece 11 is provided with an electrically conductive bond to the phase conductor 5a of the first exterior bushing 5, and is bonded to the latter in a rigid angular arrangement. The fourth contact piece 12 is provided with an electrically conductive bond to the phase conductor 6a of the second exterior bushing 6, and is bonded to the latter in a rigid angular arrangement. The first switching point 2 and the second switching point 3 are arranged between the phase conductors 5a, 6a of the two exterior bushings 5, 6, whereby the two switching points 2, 3 (via the central node point 7) are electrically connected in series, such that a current path running via the phase conductors 5a, 6a of the exterior bushings 5, 6 may be closed or separated by means of the two switching points 2, 3.
The post insulator 10 is a rotationally symmetrically hollow body, the first end of which is bonded to the node point 7, and the second end of which is supported on the inner shell side of the housing 1. By means of the post insulator 10, the node point 7 is maintained in proximity to other components which are fitted thereto, such as, for example, the first contact piece 8 and the second contact piece 9. A first kinematic chain 13 is provided for the movement of the first contact piece 8. A second kinematic chain 14 is provided for the movement of the second contact piece 9. The first kinematic chain 13 is provided with a first driving means 15. The second kinematic chain 14 is provided with a second driving means 16. The two driving means 15, 16 generate a movement, which is communicated to the first or second contact pieces 8, 9 respectively via the first or second kinematic chains 13, 14 respectively. In this case, the two driving means 15, 16 are of identical design, and are arranged on the outer shell side of the first housing 1. In this case, the two driving means 15, 16 are each configured as spring-loaded drive systems, i.e. each of the two driving means 15, 16 is provided with at least one storage spring, which is tensioned, and the energy of which is then delivered upon release and communicated to the first or second contact pieces 8, 9. The kinematic chains 13, 14 each penetrate the barrier of the housing 1 in a fluid-tight arrangement, such that the driving means 15, 16 are arranged outside the housing 1, and movement can be transmitted to the interior of the housing 1 through the wall of said housing 1, whereby the fluid-tightness of the housing 1 is maintained. For example, the kinematic chains 13, 14 may each be provided with a rotatable shaft, which penetrates a wall of the housing 1 and is sealed by means of a rotary seal. Sealing elements for the maintenance of leak-tightness in respect of axial movements may also be used, in order to permit the translation of a movement to the interior of the housing 1 by means of a linearly displaceable element of the kinematic chains 13, 14.
Number | Date | Country | Kind |
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10 2013 210 136 | May 2013 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2014/058998 | 5/2/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2014/191154 | 12/4/2014 | WO | A |
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20160111234 A1 | Apr 2016 | US |