EP2718950B1 - Switching device - Google Patents

Description

The invention relates to a switching device with a breaker path, which has a first and a second switching point with each movable contact pieces, wherein the first switching point is electrically connected in series via an axially displaceable contact pin with the second switching point and the first switching point as a vacuum interrupter is executed.

A switching device is for example from the European patent application EP 0 070 794 A2 known. The local switching device is equipped with a first and a second switching point, which are arranged axially one behind the other. The two switching points are electrically connected in series via a contact pin, wherein the contact pin is axially displaceable. Such a construction has the disadvantage that, due to the axial succession of the switching points, a comparatively long switching device is produced.

Furthermore, from the European patent application EP 1 109 187 A1 a so-called hybrid circuit breaker known, which also has two switching points. Also in this construction, a successive arrangement of the two switching points is provided. In order to produce a time staggering of switching times of the switching points in a switching operation, the arrangement of a transmission between the two switching points is provided in this construction. To accommodate the transmission additional space is required, which additionally increases the axial extent of the switching device.

From the US Patent Application Publication US 2002/0195425 A1 a switching device with a breaker gap is known, which has a first and a second switching point, wherein the first switching point is designed as Vakummschaltröhre. There, it is provided that contact pieces of the first switching point are used as an abutment for driving relatively movable contact pieces of the second switching point. Accordingly, to obtain the switching capacity for the design of the second switching point results in a subdivision into rated current and arcing contact pieces, wherein in addition to the electrically parallel-connected Nennstrom- and arcing contact pieces of the second switching point a blowing nozzle is provided.

Therefore, it is an object of the invention to provide a switching device, which allows for a simplified construction, an axially shortened design.

According to the invention the object is achieved in a switching device of the type mentioned in that in a switching operation, the first and the second switching point are forcibly operated and the first switching point works at a turn-off before the second switching point and a switch-on after the second switching point, wherein the Contact pin is a contact stem of a movable contact piece of the vacuum interrupter and the movable contact piece of the second switching point carried by the contact stem, slidably seated on the contact stem.

The two switching points are each limited by relatively movable contact pieces. In this case, the two switching points are electrically connected in series, with recourse being made to a displaceable contact pin for the interconnection. The contact pin can serve as the only element of an immediate contacting of contact pieces of the two switching points. However, it can also be provided that the contact pin is formed only as a portion of the two switching points connecting conductor track. A Aufsitzen a movable contact piece on the Contact pin allows a deviation from the known axially successive arrangement of the switching paths. For example, the second switching point can also use a space located radially around the contact pin. Sliding seating further allows the movable sliding contact piece to move together with or independently of the contact pin, thus providing a facilitated effect on time staggering of switching times of the two switch points. By a Aufsitzen the movable contact piece on the sliding contact pin is still given the opportunity to arrange the seated movable contact piece to the contact pin radially spaced, for example, to design radially circumferentially around the contact pin around, wherein the contact pin passes through the radially encircling contact piece. Thus, the possibility is still given to effect on the contact pin both a drive of the first switching point and a drive of the second switching point. This can be coupled via one and the same drive device, a movement on the movable contact pin and the contact pin a corresponding activation of the first or the second switching point are triggered. However, to achieve greater variability, the movements can also be controlled independently. For example, the movements can be based on different drives. However, it can also be provided that the same drive is used and takes place via appropriate gear coupling different motion sequences on the movable contact pin on the one hand and on the sliding on the movable contact pin seated movable contact on the other.

A breaker arrangement with a first and a second switching path makes it possible to form switch points designed in different ways, wherein different technical requirements exist due to a time staggering of switching times of the two switching points to the switching points. Thus, it is possible, for example, to allow for a switch-off at the first opening switching point, here the first switching point, a higher burden of expected Ausschaltlichtbögen, whereas the temporally switching switching point is less burdened with respect to occurring Ausschaltlichtbögen. Due to the series connection, it is possible, for example, that during a switch-off process, a switch-off arc first burns in the first switch point, whereupon an opening of the second switch point takes place.

This time scale can vary as needed. Thus, on the one hand, it may be provided that an opening of the second switching point takes place only when, with great certainty, an opening arc has already extinguished in the first switching point. Or it can also be provided that an opening of the second switching point already takes place when a burning of a Ausschaltlichtbogens in the first switching point is still to be expected.

A further advantageous embodiment may provide that the contact pin part of a movable contact piece of is first switching point and the seated on the movable contact pin contact piece of the second switching point is assigned.

By using the contact pin as part of the movable contact piece of the first switching point and a seating of the movable contact piece on the contact pin a direct electrically conductive connection for producing a series connection between the two switching points is possible. The first switching point and the second switching point can be connected to each other electrically conductively, for example via a sliding contact arrangement. Thus, it is possible to connect the two switching points via a low-impedance connection current path with each other. An immediate Aufsitzen the movable contact piece on the contact pin also allows to arrange the two contact points spatially close to each other, so that an axial distance between them is reduced and a short-sized switching device is made possible. Optionally, the switching points can cover each other in the radial direction.

Furthermore, it is advantageously provided that the first switching point is designed as a vacuum interrupter.

A vacuum interrupter has the advantage that the switching point between the relatively movable contact pieces is arranged within a closed space. This prevents the ingress of dirt into the switching point. The enclosed space is evacuated. A vacuum has a high dielectric strength even at short distances. This makes it possible, with relatively small relative movements of the contacts of a switching point of a vacuum interrupter to control each other a high switching capacity.

By using a vacuum interrupter for the first switching point is given a possibility, the second switching point in an alternative cost-effective design embody. For example, may be provided for the second switching point a flooding with an electrically insulating gas or an electrically insulating liquid, wherein the second switching point passing through electrically insulating fluid should also flow around the vacuum interrupter of the first switching point. If desired, the electrically insulating fluid can be arranged within an encapsulating housing surrounding the switching points, within which the electrically insulating fluid is placed under an increased pressure. For example, insulating liquids, sulfur hexafluoride gas, nitrogen gas or other compressible electrically insulating gases are suitable as the electrically insulating fluid.

As an advantageous embodiment it is further provided that the contact pin is a contact stem of a movable contact piece of the vacuum interrupter.

A vacuum interrupter has a switching point in its interior. The switching point is limited by relatively movable contact pieces. In this case, a movement of at least one of the contact pieces is to be transmitted through a wall of the vacuum interrupter. It has proved to be advantageous to design the movable contact pieces with a slim contact stem, which pass through the wall of the vacuum interrupter. A contact stem is advantageously formed electrically conductive, so that on this one hand, an electrical contacting of the switching point is possible. On the other hand, thermal energy can be dissipated from the interior of the vacuum interrupter via the contact stem. If one now uses a contact stem of a vacuum interrupter for carrying a movable contact piece of the second switching point, one can use the construction of the vacuum interrupter to mechanically stabilize the second switching point itself. This accounts for example leadership and holding elements for the movable contact piece of the second switching point. By a seating of the movable contact piece of the second switching point on the Konstusststengel the movable contact piece of the vacuum interrupter is given the opportunity to use guide elements together for moving parts of the first and the second switching point. This can be a compact design switching device are formed, which builds short due to the seating of the movable contact piece on the contact pin in the axial direction and reduces the complexity of the switching device to each other by a common support and mechanical guidance of the switching points.

Figur 1

eine erste Schaltstelle und eine zweite Schaltstelle jeweils im geöffneten Zustand, die

Figur 2

die erste Schaltstelle in einem Zwischenzustand und die zweite Schaltstelle im geschlossenen Zustand und die

Figur 3

die erste Schaltstelle und die zweite Schaltstelle jeweils im geschlossenen Zustand.

In the following, an embodiment of the invention is shown schematically in a drawing and described in more detail below. It shows the

FIG. 1

a first switching point and a second switching point in the open state, the

FIG. 2

the first switching point in an intermediate state and the second switching point in the closed state and the

FIG. 3

the first switching point and the second switching point in each case in the closed state.

The following is based on the FIG. 1 initially basically described the structure of a switching device according to the invention.

The FIG. 1 shows the switching device in a schematic representation. The switching device has a first switching point 1 and a second switching point 2. The first switching point 1 is part of a vacuum interrupter. The vacuum interrupter is equipped with a fluid-tight housing 3, which acts, for example, electrically insulating. The housing 3 is penetrated by relatively movable contact pieces 4, 5 of the first switching point 1. In this case, the first switching point 1 has a fixed contact piece 4 and a movable contact piece 5. The two contact pieces 4, 5 of the first switching point 1 are opposite each other frontally arranged. The fixed contact piece 4 is rigidly connected to the housing 3 and passes through this housing 3 fluid-tight. At the located outside of the housing 3 end of the fixed contact piece 4 of the first switching point 1, a first contact point 6 of the interrupter unit is arranged. The movable contact piece 5 also passes through the housing 3. It is provided that the housing 3 has a shape-variable portion 7, so that a relative movement of the movable contact piece 5 of the first switching point 1 relative to the fixed contact piece 4 of the first switching point 1 is made possible. In the present case, the variable-shape section 7 is designed in the manner of a bellows, which is permeated by the movable contact piece 5 of the first switching point 1 in a fluid-tight manner. The two contact pieces 4, 5 of the first switching point 1 have at their ends facing radially enlarged portions which limit the switching point 1. At the areas facing away from each other, the two contact pieces 4, 5 of the first switching point 1 are each equipped with contact posts 8a, 8b. The contact posts 8a, 8b respectively pass through the housing 3. The first contact point 6 of the interrupter unit is arranged on the contact stem 8a of the fixed contact piece 4 of the first switching point 1. The two contact pieces 4, 5 are movable relative to each other along a longitudinal axis 9. The longitudinal axis 9 lies in each case in the longitudinal axis of the two contact posts 8a, 8b. The movable contact piece 5 of the first switching point 1 with its contact stem 8b is axially displaceable along the longitudinal axis 9. For this purpose, at the end facing away from the first switching point 1 end of the contact stem 8b of the movable contact piece 5, an insulating rod 10 is coupled. About the insulating rod 10 is a movement in the direction of the longitudinal axis 9 on the movable contact piece 5 of the first switching point 1 transferable, so that a relative movement between the two contact pieces 4, 5 of the first switching point 1 is possible. The insulating rod 10 connects to the end facing away from the first switching point 1 end of the contact stem 8b of the movable contact piece 5 of the first switching point 1.

At a lying outside of the housing 3 of the vacuum interrupter end of the contact stem 8b of the movable contact piece 5 of the first switching point 1, a movable contact piece 11 of the second switching point 2 is arranged. The movable contact piece 11 of the second switching point 2 has a sleeve 12, which surrounds the contact stem 8b of the movable contact piece 5 of the first switching point 1 on the shell side. Between the mutually facing portions of the sleeve 12 and the contact stem 8b of the movable contact piece 5 of the first switching point 1 is a sliding contact arrangement, for example, reversibly deformable contact fingers or otherwise formed spring elements arranged. Alternatively or additionally, another electrical contacting of the movable contact piece 11 of the second switching point 2 and the movable contact piece 5 of the first switching point 1 may be provided. Angle rigidly connected to the sleeve 12 extends a radially from the main axis 9 fortragendes support member of the movable contact piece 11 of the second switching point 2. At the radially forrolling support member, for example, an annular peripheral contact surface 13 is arranged. About the annular contact surface 13 of the movable contact piece 11 of the second switching point 2 contacting with a counter-shaped contact surface of a fixed contact piece 14 of the second switching point 2 is possible. Between the contact surfaces of the fixed contact piece 14 and the movable contact piece 11 of the second switching point 2, a switching path of the second switching point 2 is arranged. The contact pieces 11, 14 of the second switching point 2 are substantially annular and coaxial with the longitudinal axis 9, wherein the two contact pieces 11, 14 of the second switching point 2 are penetrated by the contact stem 8b of the movable contact piece of the first switching point 1.

With the stationary contact piece 14 of the second switching point 2, a second contact point 15 of the interruption path of the switching device is electrically connected.

About the two contact points 6, 15, the breaker gap with the two switching points 1, 2, which are arranged electrically connected in series between the two contact points 6, 15, can be inserted into a power grid. By means of the interruption distance of the switching device so a current path between the two contacting points 6, 15 of the interruption distance can be separated or produced.

The movable contact piece 11 of the second switching point 2 is pressed for example by means of a spring 18 against a located on the contact stem 8b of the movable contact piece 5 of the first switching point 1 stop 17. The force of the spring 18 is directed such that the movable contact piece 11 of the second switching point 2 is pressed against the stop 17 in the direction of the fixed contact piece 14 of the second switching point 2. Thus, the possibility is given to transmit a movement to the movable contact piece 11 of the second switching point 2 during a movement of the insulating rod 10 and the coupled thereto contact stem 8b of the movable contact piece 5 of the first switching point. The position of the stop 17 is chosen such that at a power-up first, the contact pieces 11, 14 of the second switching point 2 touch each other.

The following is based on in the FIG. 1 Shut-off position of the first and the second switching point 1, 2 described a sequence of a turn-on described. By means of the insulating rod 10, a movement in the direction of the longitudinal axis 9 is transmitted to the contact stem 8b of the movable contact piece 5 of the first switching point 1 and consequently also to the sleeve 12 of the movable contact piece 11 of the second switching point 2. A movement in an engagement is provided in the direction of arrow 16. According to the movement of the insulating rod 10, a movement of the movable contact piece 11 of the second switching point 2 takes place in the direction of the fixed contact piece Parallel to a movement of the movable contact piece 5 and the contact stem 8b of the movable contact piece 5 of the first switching point 1 in the direction of the fixed contact piece 4 of the first switching point 1. Due to an offset arrangement of the movable contact piece 11 of the second switching point 2 The Kontaktstengel 8b it comes first to a contacting of the two contact pieces 11, 14 of the first switching point 1. Thus takes place at a switch first contacting the contact pieces 11, 14 of the second switching point 2. The contact pieces 4, 5 of the first switching point 1 have each other approached, but is still no contact between the two contact pieces 4, 5 of the first switching point 1 before. After contacting the contact pieces 11, 14 of the second switching point 2, a movement of the insulating rod 10 and the contact stem 8b against the force of the spring 18 is continued (see. Fig. 2 ). The movement of the insulating rod 10 in the direction of the longitudinal axis 9 is continued until a contacting of the two contact pieces 4, 5 of the first switching point 1 is carried out. With a contact of the contact pieces 4, 5 of the first switching point 1, a closing movement of the interruption distance of the switching device is completed.

In a turn-off, a movement of the insulating rod 10 together with the attached thereto contact stem 8b with respect to a switch-on movement with reversed sense of direction. Due to the arrangement of the two switching points 1, 2 and the respective fixed contact pieces 4, 14 and the movable contact pieces 5, 11 of the first switching point 1 and the second switching point 2 first separate the contact pieces 4, 5 of the first switching point 1, whereas the movable contact piece 11 of the second switching point 2 is pressed by the spring 18 against the fixed contact piece 14. Thus, if necessary Ausschaltlichtbögen are first performed on the two contact pieces 4, 5 of the first switching point 1. With a progress of a distance of the contact pieces 4, 5 of the first switching point 1 from each other and a striking of the sleeve 12 against the stop 17 can now also the movable contact piece 11 of the second switching point 2 are lifted from the fixed contact piece 14 of the second switching point 2.

Now, the contact pieces 4, 5; 11, 14 of the first switching point 1 and the second switching point 2 are moved completely into their switch-off positions. Following this, the breaker unit is in turn ready to move from its off position, as in FIG. 1 shown in their closed position, as in FIG. 3 shown to be moved.

As an alternative to the embodiment described above, it can be provided that the movable contact piece 11 is movable independently of a movement of the contact stem 8b or of the movable contact piece 5 of the first switching point 1. For this purpose, the movable contact pieces 5, 11 of the first and second switching point 1, 2 can be moved by separate drives or special gear arrangements.

Claims (2)

1. Switching device having an interrupter path that comprises a first switching site (1) and a second switching site (2) having in each case contact pieces (4, 5; 11, 14) that can move relative to one another, wherein the first switching site (1) is electrically connected in series to the second switching site (2) by way of an axially displaceable contact pin (8b) and the first switching site (1) is embodied as a vacuum interrupter, characterized in that during a switching process the first switching site (1) and the second switching site (2) are actuated by force and during a switching-off process the first switching site (1) operates before the second switching site (2) and during a switching-on process said first switching site operates after the second switching site (2), wherein the contact pin (8b) is a contact stem (8b) of a movable contact piece (5) of the vacuum interrupter and the movable contact piece (11) of the second switching site (2), supported by the contact stem (8b), is located on the contact stem (8b) in a sliding manner.
2. Switching device according to Claim 1,
   characterized in that the contact pin (8b) is a part of a movable contact piece (5) of the first switching site (1) and the contact piece (11) that is located on the movable contact pin (8b) is allocated to the second switching site (2).

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