BG62189B1 - Device for vacuum power breaker, in particular in a three-pole configuration - Google Patents

Abstract

The device is used in minimum oil power breakers. In it theprocess of braking commences by the actuation, for example, of oneelectric magnet by a pin of a release shaft fitted to "cut-out" inwhich case the shaft is revoled in such a way so that travelroller (3) of the switching lever (1) can pass along it. Therefollows the process of cutting out after which lever (1) isrevolved back and the crank-lever systems come out of extendedposition. When passing by shaft (6), lever (1) hits it. In orderto reduce the wearing out of shaft (6) caused by the impact, andthat the preceding contact system (11') is actuated only afterswitching off, thus increasing the number of reswitching cycles,lever (1) has a circular segment (7) by means of the peripheralsurface (9) of which, in every position of lever (1), shaft (6) isin effective connection, and a releasing bracket (11) rests on it,capable of disconnecting, in order to be able to switch the systemon and off.

Description

Technical field

The invention relates to a drive for a vacuum power switch, in particular in a three-pole embodiment, wherein a cam mounted on an actuating shaft which is under the action of a tensile actuating spring in the process of switching on after release of a thumb mounted on the switch shaft, rotates about 180 ". The cam is functionally connected to the driving roller of one switch lever in such a way that when rotating it about one point of rotation, the crank arm of the first pole of the switch is pressed off. To lock the actuator lever, it is provided with a second, fixedly mounted on it, a running roller which first passes along the area of the blower of the shut-off actuating shaft, which is under the influence of a return spring and after changing the direction of rotation of the actuating lever stops in the area of the blower of the shut-off actuator shaft.

BACKGROUND OF THE INVENTION

Both the switching process and the shutdown process are uniquely controlled in electrical switchgear as well as in high-voltage circuit breakers. This is due to the actuator being placed in standby mode, which, when starting a switching process by activating an electromagnet or button, provides the process of switching on and off. In this embodiment of the actuator, a large number of switching cycles are possible. Drivers that meet these requirements are known in a number of embodiments.

One example of such a device is the known switching device for electrical switches known in EP 521 585 A1, in particular for power switches, comprising a pull-out mechanism designed as a crank mechanism acting on the switching unit by means of actuators. A coupling mechanism is mounted between the crank lever and the actuators. In addition, the actuator has a means of resetting the switch unit. The switching unit is actuated by an actuating mechanism, whereby the actuators move the switching unit under the action of accumulated energy into the crank-pull mechanism.

Another such solution of this kind is known from EP 450 194 A1 actuator for electrical circuit breakers with one or more separate switching nodes, comprising a combined actuator and actuating rod for actuating the crank mechanism acting indirectly on the switching node. In addition, a locking means is connected to the arm of the crank actuator rod to hold the switch unit in the on position.

A common disadvantage of these known solutions for actuators for circuit breakers is the limited resource to provide a sufficiently large number of switching cycles, due to the increased wear and tear in the main links of the lever mechanism.

In another known actuator for a three-pole vacuum power switch as partially disclosed in FIG. 18 from Holec's Vacuum circuit breakers 3994.047 / E 3.10.1-1-103-20-TP-GP, the actuation of the device is carried out by means of an electromagnet, respectively a button, after starting the process of switching on through one pin, which is connected to the shut-off shaft. In this case, the shut-off actuator in its middle is shaped like a blower and is functionally connected to a finger, which is 2 bearing, with the possibility of rotating on the opposite side of the vacuum power switch. While releasing this finger through this functional connection, a second finger is released simultaneously, mounted on the engagement shaft, wherein the engagement shaft is under the action of a tensile engagement spring. As a result, the crankshaft, on which the eccentric is mounted, is rotated. This rotates at about 180 ° and is fixed to the shaft including the cam, which presses on a running roller of the switch lever, made as a double lever, which rotates about a point of rotation, and thus depresses the crank-lever system of the first pole of the switch. in the drawn position. If the crankshaft system is pressed into the extended position, the crankshaft systems of the second and third pole of the switch are pressed by means of switching rods. In this way, through the hinge mounted on each pole of the switch and the switch including a rocker mounted on each switch of the switch, a complete switching process can be carried out. In the event of the engagement lever being locked, a running roller fixed to the engagement lever stops movement in the half shaft of the shut-off actuator and rotates it against the action of a return spring. After stopping, the travel of the travel roller is followed by rotation of the switch lever and the travel roller strikes the area of the half-turn of the trip-actuating lever and blocks the switching process.

The actuation of the shutdown process by these known actuators is also accomplished by an electromagnet or button, respectively. By means of a pin fixed to the shut-off actuator, this shaft rotates until the travel roller can pass along the shut-off actuator. The switching lever can thus be rotated in the opposite direction and the crankshaft system exits the tensioned position. This enables the rocker arms to be rotated and, by the action of the clamping shut-off springs, which are mounted to each movable contact of the three poles of the switch and are tensioned during the switch-on process, the shut-off process takes place.

By means of this known tripolar vacuum power switch actuator, the process of switching the vacuum power switch on and off is precisely controlled and a predetermined number of switching cycles is achieved.

The wear of the shut-off actuator is greatly influenced by the impact of the engagement lever in the shut-off actuator when passing it.

The actuation of the contact system mounted on the shut-off actuator shaft, which is required to signal during the switching process, is performed both during the on-off and off processes.

SUMMARY OF THE INVENTION

It is an object of the invention to provide a drive for a vacuum power circuit breaker, in particular in a three-pole design, to reduce wear and allow for a greater number of switching cycles. This refers to a cam that is mounted on the engagement shaft and is functionally connected to a drive roller of the engagement lever which, with a view to locking, is in contact with the shaft of the actuator of the shut-off actuator after the activation process is performed. The task is to reduce the resulting wear and tear that results from the passage of the engagement lever along the shut-off actuator shaft and associated shocks, and the contact system mounted on the actuator is only triggered during the shutdown process.

According to the invention, this problem is solved by a vacuum power switch actuator, in particular in a three-pole embodiment, wherein the switch lever above its rotational center, on the offset-oriented shaft, has an extension, which is shaped as a circular segment along in such a way that the shut-off actuator in each position of the engaging lever, as well as in the locked state, is in functional relation to the circumferential surface of the circular segment. In this case, a release clamp is mounted on the actuator shaft, which is released by the actuator shaft for switching on and off the switching contact system. When the shut-off process is triggered by a locking element connected to the shut-off actuator, the shaft rotates with its swell area to release the switch lever.

Thus, the already actuating shaft in any position it occupies, whether the switch lever is in the switching position "on" or "off", touches the peripheral surface of the circular segment of the switch lever, and the actuating switch the shaft is released due to the fact that when the switch lever moves past it, it hits the shaft. This means that the shut-off shaft in the design of the actuator is no longer a wear part, so that at this point of the actuator the prerequisites are reached to achieve safe switching cycles of the order of 40,000. fitted with the engaging lever to be mounted in the upper portion of the circumferential surface of the circular segment so that, when guiding the movement of the shut-off actuator, minor resistance to the periphery is overcome. Hernan surface of the circular segment of the closing lever.

On the other hand, fewer requirements are imposed on the switch contact system that is mounted on the shut-off actuator, as a releasing clamp, which can be disengaged from the actuator actuator, to switch the switch contact system on and off , when interacting with the locking element associated with the shut-off actuator, the switching contact system is only (barely) actuated during the shutdown process. As this causes the actuation of the switching contact system in the process of switching on, the requirement for the signaling contact system is halved so that the positive influence of the actuator according to the invention is fully manifested on the large number of switching cycles and thus on the long term of switching. operation of the vacuum circuit breaker.

In another embodiment of the invention, the release bracket, which is releasable on the shut-off actuator, is pivotably mounted on the neck of the release actuator, while the actuator-actuating shaft itself is rotatable both in the intermediate wall and in the front wall of the vacuum switch. In this case, on its upper side, oriented towards the center of rotation of the switch lever, the release clamp has a recess in which an electromagnet or button is engaged by the clamp, thereby providing secure guidance by pushing down the actuating clamp. On the opposite side of the recess, the release bracket is connected to a tension spring that is secured under the release bracket, preferably to the intermediate wall of the vacuum power switch so as to ensure that the release bracket returns to its original position by extending the tension bracket, an electromagnet or button is no longer trapped in the recess of the release clamp.

For the locking element associated with the shut-off actuator in its half-shaft area, it is natural to use any design element suitable for rotating the release bracket on the shut-off actuator shaft to secure it by means of a support in the release bracket to start the shutdown process by rotating the shut-off shaft. A preferred locking element is a pin that is radially connected to the shut-off actuator.

In order to influence the reduction of wear of the structural elements of the actuator, it is advantageous for the bearing of the crank-lever system to be connected to the engagement lever, whereby the lever of said system itself is formed by means of the lever to be a rolling bearing.

Description of the attached figures

The invention is explained in more detail by way of an exemplary embodiment, which is shown in the following figures:

Figure 1 is a view of the actuator in the area of the switch lever in the "on" position;

Figure 2 is a view of the actuator in the area of the switch lever in the "off" position;

FIG. 3 is a top plan view of a release clamp mounted on the actuator shaft of the actuator according to FIG. 1 and 2.

Examples of carrying out the invention

As shown in FIG. 1, the engaging lever 1, which is secured in its center with the possibility of rotation about the center of rotation 2, comprises at its upper part a running roll 3 which, at the beginning of the process of engagement, interacts with a cam 5 mounted on the engagement shaft 4. the side facing the shut-off actuator shaft 6, the lever 1 is provided with an extension shaped as a circular segment 7.

As can be seen from FIG. 2, the shut-off shaft 6 is positioned in the area of the blower 8 at each position of the engaging lever 1 on the circumferential surface 9 of the circular segment 7, so that when it passes the engaging lever 1, it no longer hits the actuating shaft 6. this, in the engaged position of the shutter lever 1, the shut-off shaft 6 is supported on a running roller 10, 1θ which is located in the upper region of the circumferential surface 9 of the circular segment 7 such that, in the position shown, the shut-off drive shaft 6, the switch lever 1 is locked. As can be seen from FIG. 3, a releasing clamp 11 is mounted on the shut-off actuator 6, which is capable of being released from the shut-off shaft 6 for switching the switch contact system 1D on and off. This release is achieved by releasing the release clamp 11 on the neck 12 of the shut-off actuating shaft 6, wherein the actuating shut-off shaft 6 is pivotally supported both in the intermediate wall 13 and in the front wall 14 of the vacuum switch. A locking element 15 is attached to the shut-off actuator 6 in the form of a pin, which rests in the release bracket 11 when no electromagnet 11 is produced due to the start of the shutdown process in the recess 16 of the release bracket 11. Thus, the release bracket 11 is rotated. on the shut-off actuator shaft 6 through the locking element 15 in the form of a pin, in which the shaft rotates accordingly so that the release of the engagement lever is achieved

1. By unlocking, the engaging lever 1 is released and rotated about the center of rotation 2 in the manner shown in FIG. 2 position. The lower arm 18 of the engaging lever 1 together with the second lever 19 forms a crank-lever system 20. The second lever 19 is mounted in the center of rotation, in which the guide lever 22 is also engaged, also in the center of rotation 2. In addition, by rolling bearing 24, the lower arm 18 is connected to a leading switching rod 25 of the adjacent switching pole, such connection being provided to the third pole. Thus, when the locking lever 1 is released by the shut-off actuator, the shaft 6 and the three switching poles of the vacuum switch are essentially switched off simultaneously.

If the release bracket 11 is released again after actuation by the electromagnet 11, then the release bracket 11 returns through the expansion spring 17 in the manner shown in FIG. 2 position. This means that, in the process of starting already started, in which by turning the engagement shaft 4 through the cam 5 on the engagement shaft 4, the engagement lever 1 is pressed over the running roll 3 of the one shown in FIG. 2 shows the position in the result of FIG. 1 is also in the on position, and although the shut-off actuator shaft 6 is then rotated again, the release clamp 11 is not activated. In this way, the switching contact system 11 is not activated during the switching process.

Claims (7)

Claims A vacuum power switch actuator, in particular in a three-pole embodiment, wherein a cam (5) is mounted on an actuating shaft (4), which is actuated by a tensile actuating spring, which is a cam (5). being able to rotate about 180 ° during the engagement process after releasing a thumb, also located on the engagement shaft (4), and which the cam washer (5) is functionally connected to the drive roller (3) of the engagement lever (1 ) in such a way that when the switch lever (1) is rotated about the center of rotation (2) the crank-lever system (20) of the first pole of the switch is pressed into a drawn position, in which it is provided with a second roller (10) extending first past the region to lock the switch lever (1). of the shaft (8) of the shut-off shaft (6), which is influenced by the return spring and which the roller (10) stays against the area of the shaft (8) of the shut-off shaft (6) after reversing the direction of rotation of the switch lever (1), characterized in that the lever (1) has over its own the center of rotation of the extension of its side oriented to the side of the shut-off shaft (6), which extension is shaped as a circular segment (7) in such a way that the shut-off shaft (6) is in any position of the switch lever (1), and also in the locked state, it is functionally connected to the peripheral surface (9) of the circular segment (7) and that a release clamp (11) is released on the actuator which is released by the actuator ( 6) to toggle switching on and off If the contact system (1D) is started, and at the start of the shutdown process, by means of a locking element (15) connected to the shut-off actuating shaft (6), this shaft (6) is rotated with the section of its half (8) to release the engaging lever (1). Propulsion device according to claim 1, characterized in that the releasing bracket (11) is pivotably mounted on the neck (12) of the shut-off actuator (6), while the actuator-operated shaft (6) is bearing-able rotation both in the intermediate wall (13) and in the front wall of the vacuum switch. Propulsion device according to claims 1 and 2, characterized in that the release clamp (11) on its upper side, oriented to the center of rotation (2) of the switch lever (1), has a recess (16) in engages the actuating release clamp (11) electromagnet (11 ”) or button. Propulsion device according to claim 1, characterized in that the release bracket (11) is connected on its side opposite to the recess (16) with a tensile spring (17) which is attached below the release bracket (11) in the intermediate vacuum circuit breaker wall (13). Propulsion device according to claim 1, characterized in that the locking element (15) connected to the shut-off actuator (6) in its region of the half shaft (8) is designed as a pin. Propulsion device according to claim 1, characterized in that the second running roller (10) with which the engaging lever (1) is provided is located in the upper portion of the circumferential surface (9) of the circular segment (7). Propulsion device according to claim 1, characterized in that the bearing (24) of the crankshaft system (20) that attaches to the engagement lever (1) is a rolling bearing such that one arm (18) of the crankshaft the lever system (20) is the lever (1) itself.