RU2566681C2 - Power circuit breaker drive system - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: power circuit breaker drive system has swing actuating arm (17) interacting with locking component (14) that has the first locking area (27) and the first unlocking area (28) moved into the area of swing actuating arm (17). Locking component (14) has the second area of unlocking (30) and the second area of locking (31), which interact with swing arm (13) of another switching device. Actuating (17) and swing (13) arms are installed so that they can be rotated round the respective rotary axes oriented in parallel towards each other.

EFFECT: development of the drive system wherein locking is implemented by durable structure, which demands less costs.

17 cl, 7 dwg

Description

The invention relates to a drive system of a power switch, comprising a rotary drive lever, as well as a locking element with a first blocking zone and a first unlocking zone for the rotary drive lever being moved to the drive lever turning zone.

For example, from the laid-out application DE 102008008479 A1, a drive system is known. In the known system, it is provided that several interlocking elements are located on the circuit breaker. One interlocking element corresponds to one switched pole of the circuit breaker. During the desired miniaturization of the circuit breakers, the available structural space is reduced more and more.

A drive system is known from DE 6891188T2, which comprises a locking element. In such a drive system, expensive mechanics are used to lock the pivoting drive arm with a blocking element using various types of pivoting arm arms and rotatable shafts. The overall design contains many sliding against each other thrust surfaces. Accordingly, there is an expensive drive system, which additionally requires high maintenance costs.

Therefore, the object of the invention is such an improvement of the known drive system so that blocking is realized by means of a robust construction requiring less cost.

The problem is solved according to the invention in a drive system of a type indicated at the beginning in that the locking element has a second unlocking zone and a second locking zone for a pivot arm of another switching apparatus, while the actuator arm is pivotally mounted about the first pivot axis, and the pivot arm is mounted with the possibility rotation around the second rotary axis, and both rotary axes are oriented essentially parallel to each other, while the locking element is mounted with the possibility of shifting about substantially parallel rotary axes.

The introduction of a second blocking zone and a second unlocking zone on the blocking element enables the use of the blocking element not only for the power switch, but also for another switching device. Thus, a stable design can be used not only to influence the movement of the drive lever, but also to control the mobility of the rotary lever of another switching device. Thus, in a small structural volume, additional functions can be performed with the help of a locking element. Based on the location of both release zones and both blocking zones on the same blocking element, it is easy to connect the function of the drive lever of the power switch as well as the function of the rotary lever of the other switching device and thereby, if necessary, interlock the power switch and another switching device. So, for example, based on the location of the release zones and the blocking zones on the blocking element, it is possible to control only one of both switching devices. So, for example, it can be provided that one switching action of another switching device is blocked when the circuit breaker is not just blocked by the blocking element. Naturally, a reverse action may also be desirable.

The release zone should preferably be limited to at least one ledge, which lies essentially across the direction of movement of the locking element. The location of the steps on both sides of the release zone relative to the direction of movement of the release zone may also be provided. Due to the ledge (s) any movement of the locking element is prevented when the pivot arm is immersed in the corresponding release zone. Due to the actuating levers protruding into the respective unlocking zones of the locking element, respectively, the pivoting levers, the locking element can be prevented from acting as stopping steps in at least one direction by the actuating levers or pivoting levers. Thus, with the help of the blocking zones, it is possible to prevent the pivoting movement of the drive arm, respectively, of the pivot arm, and with the help of the unlocking zones when the drive arms / pivot arms are immersed, limit the mobility of the lock member.

By arranging the rotary axes of the drive arm and the swing arm approximately parallel to each other, it is possible in a simple manner to enable the locking element to interact with both the drive arm and the swing arm. For this, the locking element can be mounted so that it can be shifted substantially parallel to the rotary axes. This makes it possible to block the corresponding lever using the corresponding blocking zones, i.e. using the first blocking zone, which is matched with the rotary drive arm, and using the second blocking zone, which is matched with the rotary lever. In accordance with the shape of the locking element, the drive levers provided for stopping in the respective blocking zones, respectively, the swing levers are provided with a complementary shape. Due to the stable implementation, it is ensured that even, for example, when trying to actuate a power switch, respectively, of another switching device, the drive forces are perceived by the blocking element without causing deformations of the blocking element.

In the parallel orientation of the pivot axes, the position of the drive arm or the pivot arm, and thus their pivot planes with axial displacement relative to each other, can preferably be provided. This makes it possible to arrange the blocking zones and the release zones on the blocking element at a suitable distance from each other and thereby planning the corresponding reserves. Thus, the entire system can be made of simple stable machine elements, while even with a small accuracy of dimensions, a reliable action of the blocking element is still ensured.

In another preferred embodiment, it may be provided that the first blocking zone is located in the first abutment surface and the second blocking region is in the second abutment surface, with both abutment surfaces being angled, in particular at right angles to each other.

The implementation of the blocking zones in the thrust surfaces provides the possibility of providing having a large surface areas of the drive arm, respectively, of the rotary arm, which abut against the corresponding thrust surfaces of the blocking zones. In this case, the thrust surfaces can have a different shape. However, it is preferred that the abutment surfaces are in the form of flat surfaces. In addition, curved or profiled thrust surfaces can also be used. In addition, due to the location of the abutting surfaces relative to each other, it is possible to use different from each other zones, namely, lying at an angle relative to each other zones, on the blocking element to block the drive lever, respectively, to block the rotary lever. Thus, it is possible to carry out individual coordination of the blocking zones of the blocking element. Based on the location of the thrust surfaces on different, lying at an angle relative to each other sides of the locking element, other, non-coordinated drive levers or rotary levers cannot influence or change their position. Conversely, the blocking zones can act only on the agreed drive lever, respectively, the pivot arm, while the inconsistent drive lever, respectively, the pivot arm remain unaffected. Thrust surfaces may also extend beyond the corresponding blocking zone. In this case, the blocking zone is located in the abutment surface, which extends beyond the length of the blocking zone itself. That is, the blocking zone lies in the abutment surface, and the abutment surface is larger than the obstruction zone. However, it may also be provided that the length of the abutment surface corresponds to the length of the blocking zone.

In another preferred embodiment, it may be provided that both abutment surfaces meet each other and define one edge of the body of the locking element.

The angular arrangement of the thrust surfaces, in particular the angular position of the thrust surfaces, with the inclusion of one common edge of the body, provides a simple processing of the locking element during the manufacturing process. By suitable casting, milling or the like, it is possible to shape the blocking element. Based on the location of the abutment surfaces at an angle with respect to each other and the limitation of the edge of the body between the abutment surfaces, complex shapes of the locking element are excluded. Thus, for the locking element, a simple structure can be used and a stable basic shape of the locking element can be provided. In this case, the thrust surfaces may extend beyond the blocking zones, so that the blocking zones are only part of the thrust surfaces.

According to another preferred embodiment, it can be provided that the locking element is a profiled gate valve.

The profiled gate valve has a substantially rectangular parallelepiped shape, and the gate valve is mounted so that it can be shifted parallel to one of its edges. Accordingly, the gate valve is guided and driven by a suitable actuating element. Due to the profiling of the valve, it is possible to carry out the contact surfaces provided for influencing the mobility of the drive lever, respectively, of the rotary lever and to provide for an appropriate blocking of the movement of the drive lever, respectively, of the rotary lever using blocking zones, while in the release zones it is possible to immerse accordingly , respectively, the rotation of the drive lever, respectively, of the rotary lever on the locking element e. With an appropriate arrangement at an angle of the thrust surfaces of the blocking zones, the valve may have corresponding profiling in various directions. Thus, in particular, valve sections that are reduced in cross section to form release zones can be provided. For profiling in a rectangular parallelepiped-shaped gate valve, corresponding cutouts, grooves, etc. can be made, while corresponding ledges can be located in the transition zone between different cross sections.

In another preferred embodiment, it may be provided that the locking element is actuated like a crank mechanism by means of a rotary control lever.

The locking element is driven depending on the external conditions. So, for example, it can be provided that it is necessary to reliably prevent movement of the drive lever of the power switch in the power switch. In accordance with this, the locking element with its first blocking zone must be moved to the rotation zone of the drive arm. It may be provided that the corresponding manual initiation of the movement of the blocking element is carried out. However, it can also be provided that, depending on the state of another structural element, control of the control lever takes place. For example, the circuit breaker can be combined with a disconnector, which, with the appropriate separation position of the separator, initiates the movement of the locking element, so that the first locking zone is included in the rotation zone of the drive lever. However, it can also be provided that the isolating position of the circuit breaker is set using the blocking element. The circuit breaker is in its off position and has an open breaker position. By blocking the turning movement of the rotary drive lever using the first blocking zone, it is possible to exclude the movement of the drive lever of the power switch, so that the separation function of the power switch is also provided, since even if the switch is inadvertently actuated or malfunctions, the switching movement is mechanically prevented by the blocked drive lever.

When the locking element is driven by the crank type by means of a rotary control lever, it is possible to convert the rotary movement, such as, for example, the movement created by the rotary actuators, into a linear motion of the locking element.

In addition, the swing arm can also be used to deviate linear motion, for example, by 90 °. In this case, it can be provided that the rotary control lever is directly engaged with the locking element or that a crank mechanism with an intermediate connecting rod converts the rotary movement of the control lever into linear movement of the locking element.

Furthermore, it may be advantageously provided that the locking element has a step that separates the locking element into first and second sections, the first section having a larger cross section than the second section, and the first blocking zone is in the first section and the second blocking zone - in the second section.

The locking element is preferably made in the form of a rectangular parallelepiped, while it may have a corresponding profiling, i.e. various cross sections. For profiling, the rectangular parallelepiped can be equipped with a corresponding ledge that divides the blocking element into two sections. In this case, both sections should extend relative to the axis of movement of the blocking element, along this axis of movement. The step preferably extends across the axis of movement. The step can be formed, for example, by reducing the cross section of the blocking element, so that the blocking element in the first section has a substantially rectangular parallelepiped shape, while the cross section of this rectangular parallelepiped is larger than the cross section of a substantially rectangular parallelepiped of the second section. The locking element due to the reduction of the cross section may have an L-shaped contour. The location of the blocking zones in the first and second section allows the choice of various sizes of the drive lever, respectively, of the rotary lever. Due to this, it is possible to block also relatively far removed from each other the pivot axes of the drive arm, respectively, of the pivot arm using a locking element located between these two axes. The ledge forms an abrupt decrease in the cross section between the first and second sections of the blocking element. Due to the step, the first release zone of the drive lever is limited. When the drive lever is rotated to the first unlocking zone with a step, the movement of the locking element in one direction is limited. This prevents the second blocking zone from being transferred to the rotation zone of the corresponding pivot arm, and the second blocking zone is reliably located in the pivot zone of the pivot arm and excludes the movement of the pivot arm. Thus, on the one hand, the movement of the drive lever can be prevented by the first locking zone of the locking member, and on the other hand, when the drive lever is rotated to the first unlocking zone, the movement of the locking member can be prevented. In addition, on the one hand, the rotation of the pivoting arm can be prevented by the second locking zone of the locking element, on the other hand, when the pivoting lever is rotated into the second unlocking zone, the movement of the locking element can be prevented, and therefore, the first blocking zone remains in the rotation plane of the drive lever and blocks the movement of turning on the drive lever of the power switch.

In this case, it can be preferably provided that the second release zone is in the second section and has a cross section reduced relative to the cross section of the second section.

By further reducing the cross section of the second section, the first and second release zones can be located inside the second section. The second release zone may, for example, profile the locking element in the form of a groove. In this case, the groove can be made in the locking element, in particular in the second section, essentially across the direction of movement of the locking element. Due to this, when the rotary lever is rotated to the second unlocking zone of the locking element, the locking element is prevented from moving by the inserted rotary lever and the lateral walls of the groove located on both sides of the rotary lever in the direction of the axis of movement of the locking element.

Thus, on the one hand, the movement of the pivot arm, respectively, of the drive lever with a locking member can be limited, on the other hand, with the help of the pivot arm, respectively, of the drive arm, the movement of the lock member can also be limited. This makes it possible to interlock the pivot arm and the drive arm. That is, only one of both levers can move freely, while the other lever is locked.

In another preferred embodiment, it may be provided that the first release zone is in the second section.

The location of the first release zone and the second blocking zone in the same second section makes it possible, on the one hand, to block the second blocking zone and the first unlocking zone with respect to each other. Since these two zones are located on the same second section, their relative position is fixed on the blocking element. The first release zone and the second blocking zone may, for example, have the same cross section.

In another preferred embodiment, it may be provided that the drive arm rests on a shaft that extends through the fluid tight seal wall of the circuit breaker circuit breaker unit.

The circuit breakers usually have at least one, usually several, chopper units. The chopper block is a structural unit that serves to create, respectively, interrupt the current path. For example, the interrupter unit may have contact parts movable relative to each other, which in the on state are in galvanic contact with each other and in the off state are electrically isolated from each other. In order to protect the contact parts, it is preferable to provide the breaker unit with a fluid tight enclosure, which surrounds the structural elements inside the fluid tight.

To transmit movement to the sealed housing, it is preferable to ensure a tight passage of the shaft through the wall of the housing and the location of the drive lever directly on this shaft. Thus, on the one hand, it is possible to easily seal the rotary shaft relative to the wall of the sealed housing, on the other hand, the location of the drive lever in close proximity to the chopper block provides the possibility of reliable prevention of shaft movement. Using the drive lever, the movement is transmitted to the shaft and is introduced into the sealed housing using the shaft. Thus, even if there is a malfunction in the drive circuit, it is possible to reliably block the movement of the shaft and thereby the mechanisms for driving contact parts inside the sealed housing of the shaft.

In another preferred embodiment, it may be provided that the pivot arm is in the form of a sector of a circular cylinder.

The execution of the rotary lever in the form of a sector of a circular cylinder provides a locking action of the rotary lever on the locking element in a large area of rotation of the rotary lever. Thus, for example, it can be provided that the pivot arm represents, for example, a segment of at least 90 ° of the circular cylinder, so that when the pivot arm pivots 90 °, a corresponding locking action is provided by the pivot arm in the entire rotation angle. So, for example, it is possible already with the beginning of the movement of the pivot arm to cause a corresponding blocking of the movement of the locking element and save it during all further movement of the pivot arm.

In addition, it may be provided that a status indicator is located on the blocking element.

With the help of a locking element, you can simply display the status of the circuit breaker. Blocking the movement of the drive lever using the first blocking zone can be signaled outward. Since the blocking action is created based on the displacement of the blocking element, the position of the blocking element itself is an indicator of the status of the circuit breaker. When the locking element is locked in the first blocking zone, the power switch must be in the off position, and only in this case is it possible to move the first blocking zone of the locking element in the rotation zone of the drive lever. Accordingly, it is possible, for example, to indicate the status of the circuit breaker using color coding. Using the color marking mask, it can be made visible or closed depending on the position of the blocking element.

In addition, it may be advantageously provided that the locking element with a status indicator moves through the wall.

When moving the blocking element with the status indicator through the wall, along with color marking and position signaling, it is possible to determine the corresponding spatial change after passing through the wall. The protrusion of the locking element from the wall indicates the blocking of the circuit breaker. In this case, the blocking element may be stationary for a long time in the recess of the wall. When the locking element moves through the wall, the portion of the locking element protrudes outward. This protruding portion, which was previously covered by a wall, may have a status indicator. To this end, the protruding portion may be provided with an appropriate color and / or alphanumeric marking as a status indicator. Marking can also be a symbol, for example, in the form of a closed lock.

In another preferred embodiment, it may be provided that the other switching device is an earthing switch.

Power switches are used to turn on, respectively, turn off the path of passage of electric current. In the off state, it can preferably be provided that individual sections of the current path have a ground potential. Using the appropriate earthing switch, you can ground. Another switching device can only be switched in the isolating position of the circuit breaker. Using the interlocking element, it is possible in a simple manner to prevent incorrect switching of another switching device and to perform grounding with the other switching device exclusively in the off state of the circuit breaker. In this case, the grounding separator can be made in the form of a grounding separator of an outdoor installation, i.e. The electrically conductive connection between the ground point and the connection point of the circuit breaker is made in the surrounding atmosphere. So, for example, the grounding separator can have, for example, a rotary axis around which the grounding rod is rotated, while the rotary arm rotates together with the grounding rod.

In addition, it can be provided that the power switch has several switched poles, each with at least one drive lever, which are connected to each other, and a locking element is matched to only one of the drive levers of the switched poles.

The use of several switched poles provides the ability to switch using a single power switch, for example, multiphase transmission systems of electrical energy. This requires interruption, for example, of several, in particular three, electric current paths that belong to a common multiphase electric power transmission system. In this case, it is necessary to ensure at least approximately simultaneous, in particular, simultaneous opening, respectively, the closure of the individual paths of the passage of electric current. In this case, the individual switched poles of the circuit breaker have essentially the same design. At least with each power switch, a separate drive lever is matched, which introduces the corresponding movement into the corresponding sealed housing of the interrupter unit of the corresponding switched pole using a rotatable shaft. The individual drive levers can be connected to each other, so that there is a synchronous movement of the drive levers with each other. At the same time, the connection of the drive levers can be so rigid (for example, using connecting rods) that when one of the drive levers is blocked, the movements of the other drive levers connected to this drive lever are blocked. Thus, it is also possible in the circuit breaker with several switched poles to prevent at all switched poles the undesirable movement of the switching contacts through the use of a single interlocking element. In the same way, the movable parts of several switching poles of another switching device can be connected to each other, if the other switching device is also made multi-pole.

In addition, it can be provided that the circuit breaker has a yoke with a substantially U-shaped cross-section, with the locking element mounted inside a circuit limited by a U-shaped cross-section.

The traverse can serve as the chassis of a circuit breaker, on which all essential structural units are based. Thus, the individual structural units can be positioned and fixed relative to each other. Through the use of a U-shaped cross-section of the crosshead, a sufficiently rigid along the angle of the crosshead is provided with a reduced amount of material. If the blocking element is installed inside a contour bounded by a U-shaped cross-section, then the blocking element with its support is located inside the mechanically protected space, so that external influences on it are at least substantially eliminated.

In addition, it may be provided that the switched poles of the circuit breaker are mounted on a traverse.

With the arrangement of the switched poles of the circuit breaker on the traverse, it is possible to easily align and orient the position and movements of the locking element relative to the position of the switched poles of the circuit breaker. In addition, another switchgear can also be installed on the traverse. So, for example, the rotary shaft of another switching device, oriented parallel to the direction of movement of the locking element, can lean on the traverse, while at one end of the rotary shaft a ground rod is located radially relative to the rotary axis, and the ground rod together with the rotary lever can be rotated around the rotary axis of the shaft.

The following is a more detailed description of the invention based on an exemplary embodiment with reference to the accompanying drawings, in which is schematically depicted:

FIG. 1 - power switch with another switching device, in isometric view;

FIG. 2 is a section along line II-II in FIG. one;

FIG. 3 is a section along line III-III in FIG. one;

FIG. 4 - the drive lever of the power switch located in the first zone of blocking the blocking element, the rotary lever of another switching device, located in the second zone of blocking of the blocking element, in isometric view in section along line III-III;

FIG. 5 is the same view as in FIG. 4, while the locking element is freely movable;

FIG. 6 is the same view as in FIG. 4, wherein the rotary drive lever is in the first blocking zone, and the rotary lever is in the second unlocking zone of the blocking element; and

FIG. 7 - a pivoting lever rotated into the second release zone of the locking element.

In FIG. 1 is a perspective view of a circuit breaker. The circuit breaker has a switched pole A, a switched pole B, and a switched pole C. Each of the three switched poles A, B, C is used to interrupt, respectively, create a current path. In this case, the three switched poles A, B, C are made identically and serve to switch the multiphase current path inside the multiphase electric power transmission system. Since the three switched poles A, B, C are identical, the design of the switched pole of the circuit breaker based on the switched pole A is given below as an example.

The switched pole A has a base 1. The base 1 is, for example, a cast metal body that serves to position the entire switched pole A. In this case, the base 1 is provided with a shoulder 1a, which extends the circumference of the base 1 in the radial direction. The base 1 is connected to the traverse 2. For this, the traverse 2 has a recess on its upper closing surface 3, through which the base 1 passes, while the shoulder 1a limits the depth of penetration of the base 1 into the recess of the traverse 2. With the help of the shoulder 1a located on the upper closing surface 3 it is possible to fix the cap 1 on the traverse 2.

The cap 1 passes through the upper closing surface 3 of the beam 2 and has on its end lying under the upper closing surface 3 the gear housing 4. Gear housing 4 is shown in FIG. The yoke 2 has a substantially U-shaped cross section, with the upper covering surface 3 being located on a section that connects to each other both side walls of the U-shaped contour. The housing 4 of the gearbox is dimensioned so that it is located inside the bounded by the U-shaped cross-section of the contour of the beam 2. Due to this, this part of the cap 1 is maximally protected from mechanical stress.

An insulating body 5 is located on the base 1. The insulating body 5 in this case is rotationally symmetrical and is provided on its outer side with extension ribs for the passage of current of the sliding discharge. The insulating body 5 is made in the form of a hollow body, while the inner space of the insulating body is filled with an electrically insulating gas, preferably sulfur hexafluoride. The insulating body 5 is fluid tightly connected to the cap 1, so that the space inside the cap 1 is also filled with an electrically insulating gas. So, for example, made as a housing 4 of the gear section of the cap 1 is also filled with an electrically insulating gas. The cap 1 and the insulating body 5 are connected to each other impervious to the fluid and form a fluid-tight sealed enclosure. The sealed housing of the switched pole A is part of a chopper unit. The chopper block has the structural elements of the switched pole A, which directly serve to create, respectively, interrupt the current path.

By means of the insulating body 5, the first attachment point 6, as well as the second attachment point 7, are electrically isolated and impervious to the fluid. Both connection points 6, 7 serve to connect the electrical lead wires to the switched pole A of the power switch. As electrical wires, for example, overhead line wires or the like can be used. Through both points of attachment 6, 7, a current path is formed into the inner space of the insulating body 5. With the first and second connection points 6, 7, contact parts 8, 9 are movable relative to each other. In this case, the first contact part 8 is stationary inside the insulating body 5 and is electrically connected to the first attachment point 6. The second contact part 9 is mounted movably. The first contact part 8, at its end facing the second contact part 9, is provided with a sleeve-shaped area for introducing a movable second contact part 9, which is made in the form of a finger. Thus, a switching place is formed between the two contact parts 8, 9, which can be brought into the open state, as well as in the closed state, by relative movement between the two contact parts 8, 9. The second contact part 9, through a sliding contact system, is electrically conductive in contact with the second connection point 7, so that both contact parts 8, 9 through both connection points 6, 7 can enter the current path. In order to create movement of the second contact part 9, not shown in FIG. 1 drive unit. The drive device is located outside the insulating body 5, as well as outside the base 1, and rests, for example, on the yoke 2. In FIG. 1, the double arrow 10 shows the possibility of introducing a drive-initiated movement on the end face of the yoke 2. As shown in FIG. 1, discontinuous lines of the path, the movement is introduced through the corresponding housing 4 of the gearbox inside the switched poles A, B, C. In addition, it is possible to introduce drive movement in other places of the traverse 2. In particular, you can enter the movement to any switched pole A, B, C and from there distribute to other switched poles A, B, C. The locking element 14 should preferably be located at the switched pole A, B, C, into which the drive movement is introduced.

In addition, another switchgear is located on traverse 2. Another switching device in this case is made in the form of the so-called grounding disconnector of the outdoor installation. In accordance with the number of switched poles A, B, C, the earthing switch is also made three-pole, i.e. Each of the switched poles A, B, C can be grounded using another switching device. Another switching device has several switched poles A1, B1, C1, which, in turn, are made the same. Therefore, the description of the design of the switched pole A1 of another switching apparatus is given below as an example. The switched pole A1 has a rotary shaft 11. The rotary shaft 11 is mounted to rotate on the upper closing surface 3 of the beam 2, while the rotary axis of the rotary shaft 11 is crossed with the axis of movement of the second contact part 9. In the projection in the direction of the longitudinal axis of the beam 2, t. e. in the direction of the double arrow 10, respectively, perpendicular to the cross section of the essentially U-shaped profile of the crosshead 2, the rotary axis of the rotary shaft 11 intersects the axis of motion of the second contact part 9 at right angles.

A grounding rod 12 is connected to the rotary shaft 11 without rotation. The grounding rod 12 extends substantially radially relative to the rotary axis of the rotary shaft 11. In addition, the rotary lever 13, which is also rigidly angled to the rotary shaft, is rotatably connected to the rotary shaft 11. 11. When the rotary shaft 11 moves, the ground rod 12 and the rotary lever 13 move synchronously. The ground rod has an earth potential at its end facing the rotary shaft. For this, it can be provided that the grounding rod 12 is contacted with the ground potential through a separate grounding wire. Such a grounding wire may be, for example, a flexible copper tape.

On the opposite end of the rotary shaft, the free end of the ground rod 12 is a contact zone, which, depending on the length of the ground rod 12, can enter into electrical contact with either the first connection point 6 or the second connection point 7. For this purpose, at each point of attachment 6, 7 there is a corresponding opposite contact, for example, a spring contact slot or the like. When the contact zone of the grounding rod 12 enters the opposite contact in the first, respectively, second connection point 6, 7, an earth connection is created with the ground potential through the grounding rod 12 with the first connection point 6 or the second connection point 7. Accordingly, the connecting wires located on the first, respectively, second connection point 6, 7 receive the earth potential.

The rotation of the rotary shaft 11 can be initiated in various ways. For example, the drive element can act on the end of the pivot shaft 11, on which there is no ground rod 12. However, it can also be provided that the pivot arm 13 is used to input movement into the pivot shaft and, therefore, also into the ground rod 12. The movement of the shafts of the switched poles A1, B1, C1 of another switching device can be synchronized using mechanical coupling. So, it is possible to set in motion only one of the shafts and transmit the drive movement via communication also to other shafts of other switched poles B1, C1.

A power switch with its switched poles A, B, C is used to create, respectively, an open path for the passage of current inside the electric power transmission network. In this case, the connecting wires provided for the transmission of electricity in the case of normal operation must be located and held electrically isolated from the earth's potential. Unwanted connection of connecting wires to ground potential, in particular when they are under rated voltage and pass rated current, can lead to irreparable damage. Therefore, it is desirable to operate the earthing switch only when there is a certain switching position (preferably an open, respectively, off position) of the circuit breaker. Conversely, when grounding the connection points 6, 7 through the grounding rod 12 of another switching device, it is not desirable that the circuit breaker unexpectedly carry out a switching movement, leading to a short circuit to ground.

    In order to prevent such incorrect switching in the circuit breaker, it is provided that the drive system is provided with an interlocking element 14. In FIG. 1 part of the locking element 14 protrudes through the side wall of the beam 2. The following is a description of the principle of operation and function of the locking element with reference to the following figures.

In FIG. 2 shows a cross section of the crosshead 2 in the direction II-II. You can see a substantially U-shaped cross section of the crosshead 2, while on the upper closing surface 3 there is a rotary shaft 11 of another switching device. In addition, a pivot arm 13 is shown which is connected to the shaft 11. In FIG. 2 shows, by way of example, the possibility of connecting the grounding rod 12 to the rotary shaft 11. Thus, in this case, it is provided that with the help of one or more axially lying brackets 15, the grounding rod 12 is pressed against the receiving element which is connected to the rotary shaft 11. With the help of screwed staples 15, it is possible to easily replace the grounding rod 12. So, when the grounding rod 12 is worn or when the opposite contact changes from the first point 6 of the connection to the second point 7 when Connections or vice versa can be used is shorter, correspondingly longer ground rod 12. In addition, FIG. 2 shows a section of the base 1 of the switched pole A made in the form of a gearbox 4. Inside the gearbox 4 there is a part of the gearbox that serves to transmit movement to the second contact part 9. In front of it, the shaft 16 passes through the wall of the sealed housing of the circuit breaker of the switching pole A. Suitable sealing rings are provided for this, so that also when the shaft 16 is rotated, a fluid tight connection between the wall of the sealed housing is provided the shaft 16. At the end of the shaft 16 protruding from the gear unit 4, the drive lever 17 is mounted. The drive lever 17 is connected without turning to the shaft 16. The drive lever 17 has a socket 18 in the form of a plug into which the drive rod 19 and the connecting rod 20 are inserted With the drive rod 19, it is possible to transmit movement in the direction of the double arrow 10 in FIG. 1 to a drive lever 17 of an adjacent chopper block, in this case, a switched pole B, and in the same way from a switched pole B also to a switched pole C. Thus, the individual drive levers 17, which are aligned with the corresponding switched poles A, B, C, connected to each other through the corresponding connecting rods, so that the movement of the drive lever 17 of the switched pole A can be transmitted through the connecting rod 20 also to other drive levers of other switched poles B, C power off yuchatelya.

Thus, it is possible to apply a common drive unit that creates movement, and this movement can be transmitted to all switched poles A, B, C of the circuit breaker.

A transverse coupler 21 is fixed at the free ends of the side walls of the U-shaped traverse 20. A recess is made in the transverse coupler 21, into which the spacer bolts 22 are inserted. The support bracket 23 is supported by the spacer bolts on the transverse coupler 21. The support bracket 23 is movably mounted the locking element 14. The spacer bolts 22 can be aligned using the thread on the transverse coupler 21. Thereby, it is possible to establish a reliable locking action of the locking element. In particular, it is possible to set the position of the thrust surfaces. In this case, the shift direction of the locking element 14 is parallel to the rotary axis of the rotary shaft 11, and also parallel to the rotary axis of the shaft 16 of the drive lever 17. In addition, a control lever 24 is located on the support bracket 23, through which movement can be transmitted to the locking element 14.

In FIG. 3 shows a section along line III-III in FIG. 1. In FIG. 3 shows the internal space of the gear housing 4 and the driven lever 25, which is mounted inside the gear housing 4 on the shaft 16 and transmits the movement of the drive lever 17. Through the driven lever 25, motion is transmitted to the second contact part 9.

In FIG. 3 shows a top view of a support bracket 23, which has a recess for allowing the locking element 14 to be parallel to the rotary axis of the shaft 16, and also parallel to the rotary axis of the rotary shaft 11, which is not shown in FIG. 3. It can be seen that the blocking element 14 has a substantially rectangular parallelepiped shape, with the rectangular parallelepiped having different cross sections, i.e. during the blocking element 14, a step 26 is located that extends substantially transverse to the axis of movement of the blocking element 14. The step 26 divides the blocking element 14 into a first section 14.1, as well as a second section 14.2. Due to the step 26, an abrupt decrease in the cross section from the first section 14.1 to the second section 14.2 is set. Both the first section 14.1 and the second section 14.2 have a substantially rectangular cross section with a rectangular parallelepiped structure, with the cross section of the first section 14.1 being larger than the cross section of the second section 14.2. Due to the structure of the first and second sections 14.1, 14.2, the locking element 14 has an L-shaped contour, while one of the sides of the L-shaped contour serves as an abutment surface to the support arm 23.

The control lever 24 is supported on the support bracket 23 with a possibility of rotation, while the control lever 24 is made in the form of a two-arm lever and is connected to a drive device for the locking element 14. With the other shoulder, the control lever 24 is guided with a finger in the wings of the locking element 14, so that the control the element 24 and the locking element 14 interact with each other in the form of a crank mechanism. The rotary movement of the control lever 2 4 is converted into linear motion of the locking element 14. The link is made in the form of an elongated hole extending across the direction of movement of the locking element 14. By connecting the control lever 24 and the locking element 14, the stroke of the locking element 14 is limited so that the locking element 14 cannot slip out of the support bracket 23.

In the first section 14.1 of the blocking element 14, a first blocking zone 27 is located. The first blocking zone 27 lies in the abutment surface, which lies in the L-shaped side of the blocking element 14, while the first blocking zone 27 with its abutting surface is located on the side that lies opposite the abutment surface of the blocking element 14 in the support bracket 23. The drive lever 17 is provided with a stop 17.1, which, as shown in FIG. 3 position stands for the first zone 27 of the blocking and adjacent to it, so that the free rotation of the drive lever 17 is blocked by the first zone 27 of the blocking. This position of the actuating arm 17 may preferably exist when the contact parts 8, 9 are separated from each other. The power switch is in the open position, respectively, off position.

In the area of the second section 14.2 is the first release zone 28. Based on the reduction of the cross section in the area of the first unlocking zone 28, it is possible to pass down the stop 17.1 of the drive lever 17 in front of the locking element 14, so that the circuit breaker is turned on. To do this, the locking element must first be moved in the direction of arrow 29.

In addition, in the area of the second section 14.2, a second release zone 30 is located. The second release zone 30 is formed by a groove locking element 14 formed on the abutment surface in the L-shaped structure. While the groove is made in the side surface, which lies opposite the L-shaped side of the L-shaped locking element, which serves to slide the locking element 14 in the support bracket 23. Moreover, the groove is made so wide that the width of the pivoting arm 13 is only slightly less.

     After the rotary shaft 11 moves and the rotary lever 13 is rotated into the second blocking zone 19, the blocking element 14 is prevented from moving. When the shaft 11 rotates, the rotary lever 13 moves to the second unlocking zone 30, the power switch is preferably in its open position, while switching on is not possible based on the position of the first blocking zone 27 in the turning zone of the stop 17.1 of the drive lever 17. Thus, it is ensured that only when the power is off lyuchatelya inclusion of another switching device may occur. The pivot arm 13 for providing locking along its entire pivoting trajectory is made in the form of a sector of a circular cylinder, with the side surface of the sector of the circular cylinder lying opposite the bottom of the groove, and the side walls of the groove of the second unlocking zone 30 lie opposite to the corresponding closing surfaces of the sector of the circular cylinder.

In addition, in the second portion 14.2 of the blocking element 14, a second blocking zone 31 is located, wherein the first blocking zone 27, the first unlocking zone 28, the second unlocking zone 30 and the second blocking zone 31 are arranged one after the other in the direction of movement of the blocking element 14. The first the blocking zone 27 is in the first section 14.1, and the first unlocking zone 28, the second unlocking zone 30, as well as the second blocking zone 31 are sequentially one after another in the second blocking section 14.2 element. The first release zone 28 and the second blocking zone 31 have the same shape, in particular the same cross section, with the first unlocking zone 28 and the second blocking zone 31 being separated from each other by the second unlocking zone 30.

As shown in FIG. 3 state, it is possible to rotate the drive lever 13 into the second unlocking zone 30 of the locking element 14, i.e. in this state, the power switch is in the open position, and the grounding separator is still in the off position, while turning the shaft 11 and the grounding rod 12 and the pivoting arm 13 of the other switching apparatus attached to it, it can be transferred to its on position. Shown in a plan view in FIG. 3, the switching position is shown as an example in FIG. 6 isometric view.

The following describes the switching sequence with reference to FIG. 4, 5, 6 and 7, in which the power switch is first transferred from its on position to its off, respectively, open state, and then another switching device is turned on, i.e. grounding splitter.

FIG. 4, 5 and 6 are partially shown with a gap to provide a view of the locking element 14. For clarity, in FIG. 4, 5 and 6, the drive rod 19 is not shown.

In FIG. 4 shows the position of the drive lever 17 in which it is in the on state of the circuit breaker. The stop 17.1 is immersed in the first unlocking zone 28 of the locking element 14, i.e. shown in FIG. In the 4-position of the locking element 14, the actuating lever 17 can move from its shown on position clockwise to its off position (see FIG. 5, the off position). The movement of the pivot arm 13 due to the position of the second blocking zone 31 in its rotation path is not possible, i.e. Unwanted switching of another switching device (in this case, an earthing switch) is prevented. Due to the position of the ledge 26 in the on position of the drive lever 17, the locking element 14 can be driven by the control lever 24 only to a limited extent, since the ledge 26 abuts against the stop 17.1 of the drive lever 17 and thereby prevents the second release zone 30 from being transferred to the swivel plane lever 13. In the figure, the space located between the step 26 and the stop 17.1 of the drive lever 17 in the direction of movement is exaggeratedly large to explain the principle of operation.

To enable the switching process of another switching device, it is necessary to move the drive lever 17 from the position of the power switch to the open position of the power switch. To do this, the drive lever 17 is rotated clockwise. The stop 17.1 of the drive lever 17 releases the trajectory of the stop 26 of the locking element 14, so that due to the movement of the control lever 24, the first blocking zone 27 is translated into the rotation zone of the stop 17.1 of the drive lever 17 (see Fig. 5). In addition, while the locking element 14 is moving, the second locking zone 31 of the locking element 14 relative to the pivoting arm 13 is active, so that while the locking element 14 is also moving, the protection of the other switching device is ensured.

In FIG. 6 shows the completion of what started in FIG. 5 of the movement of the locking element 14. The stop 17.1 is located in the area of the first locking zone 27 of the locking element 14, i.e. the movement of the drive lever 17 with its focus 17.1 is prohibited using the locking element 14 with its first blocking zone 27. The second release zone 30 is located in the pivot zone of the pivot arm 13, i.e. the pivoting movement of the pivot shaft 11 with the pivot arm 13 is possible when the pivot arm 13 is immersed in the second release zone 30. The second blocking zone 31 protrudes beyond the wall of the yoke 2 and can, using the corresponding color marking or inscription, signal the blocking position of the power switch (see FIG. 2). In FIG. 2 shows the state of FIG. 6 in a different projection.

Based on the blocking of the movement of the drive lever 17, the possibility of turning on the circuit breaker in the opening position is excluded even when the kinetic circuit of the circuit breaker is set in motion.

In FIG. 7 is shown outside the yoke 2, with the locking element 14 protruding its second blocking zone 31 through the yoke wall, and the pivot arm 13 is immersed in the second unlocking zone 30. The grounding rod 12 is inserted in its contact zone into the coordinated opposite contact of the first or second point 6, 7 of the connection of the switched pole A. Based on the circular cylindrical shape of the segment of the rotary lever 13 already at the beginning of movement, during the switching movement and after reaching the switching state of another switching device, in this case, the grounding separator, the blocking element 14 is prevented from moving. Since this movement is prevented, the first blocking zone 27 is also not can be moved from the drive lever abutment 17 17.1 cornering zone, so that a reliable prevention switching the circuit breaker via the locking element 14.

When you turn off another switching device, i.e. upon termination of its grounding function, the execution in the reverse order shown in FIG. 7, 6, 5 and 4 stages. In the on state of one of the devices (power switch, respectively, of another switching device), the corresponding other device (i.e., another switching device or power switch) is blocked for switching movement by means of a locking element 14.

This embodiment of the drive system is suitable, in particular, when using a power switch with a separator function, i.e. The circuit breaker performs shutdown tasks, i.e. it interrupts the rated and operating currents up to short circuit currents and, when switched off, reliably performs the function of separating the contact solution. In the divided state of the contact parts 8, 9 that are movable relative to each other, by opening the control lever 2 4, it is possible to protect the opening position of the power switch and to mechanically prevent the inadvertent opening of the power switch.

     However, it may also be provided that the control lever 24 is moved, for example, depending on the switching state of other devices. These other devices can be, for example, separate dividers or other switching devices, while their switching state is determined by the position of the control lever 24.

Claims (17)

1. The drive system of the circuit breaker, comprising a rotary drive lever (17), as well as a blocking element (14) with a first locking zone (27) and a first unlocking zone (28) for the rotary drive lever that is moved to the turning zone of the drive lever (17) ( 17), characterized in that the locking element (14) has a second unlocking zone (30) and a second locking zone (31) for the pivot arm (13) of the other switching apparatus, while the actuating arm (17) is pivotally mounted around the first pivot axis, and pov The pivot arm (13) is rotatably mounted about a second pivot axis, and both pivot axes are oriented substantially parallel to each other, while the locking element (14) is pivotally mounted substantially parallel to the pivot axes. 2. The drive system according to claim 1, characterized in that the first blocking zone (27) is located in the first abutment surface, and the second blocking zone (31) is in the second abutment surface, while both abutment surfaces are angled, in particular at an angle right angle relative to each other. 3. The drive system according to claim 2, characterized in that both thrust surfaces are joined together and limit one edge of the body of the locking element (14). 4. The drive system according to claim 1, characterized in that the locking element is a profiled gate valve. 5. The drive system according to claim 1, characterized in that the locking element (14) is actuated like a crank mechanism using a rotary control lever (24). 6. The drive system according to claim 1, characterized in that the locking element (14) has a step (26), which divides the locking element (14) into the first and second section (14.1, 14.2), while the first section (14.1) has a larger cross section than the second section (14.2), and the first blocking zone (27) is in the first section (14.1), and the second blocking zone (31) is in the second section (14.2). 7. The drive system according to claim 6, characterized in that the second release zone (30) is in the second section (14.2) and has a cross section reduced relative to the cross section of the second section (14.2). 8. The drive system according to claim 6, characterized in that the first release zone (28) is in the second section (14.2). 9. The drive system according to claim 1, characterized in that the drive lever (17) is supported by a shaft (16), which passes through a fluid-tight sealed wall of the circuit breaker circuit breaker block. 10. The drive system according to claim 1, characterized in that the pivot arm (13) has the shape of a sector of a circular cylinder. 11. The drive system according to claim 1, characterized in that a status indicator is located on the blocking element (14). 12. The drive system according to claim 11, characterized in that the locking element (14) with a status indicator moves through the wall. 13. The drive system according to claim 1, characterized in that the other switching device is an earthing switch. 14. The drive system according to claim 1, characterized in that the power switch has several switched poles (A, B, C), each with at least one drive lever (17), which are connected (20) to each other, and only with one of the drive levers (17) of the switched poles (A, B, C), a locking element (14) is matched. 15. The drive system according to claim 1, characterized in that the circuit breaker has a yoke (2) with a substantially U-shaped cross section, while the blocking element (14) is installed inside a contour bounded by a U-shaped cross section. 16. The drive system according to p. 15, characterized in that the switched poles (A, B, C) of the power switch are installed on the traverse (2). 17. The drive system according to claim 1, characterized in that the locking element (14) has a step (26) that divides the locking element (14) into the first and second sections (14.1, 14.2), while the first section (14.1) has a larger cross section than the second section (14.2), and the first blocking zone (27) is in the first section (14.1), and the second blocking zone (31) is in the second section (14.2), while the second unlocking zone (30) is in the second section (14.2) and has a cross section reduced relative to the cross section of the second section (14.2), while The first release zone (28) is in the second section (14.2).

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