DE19963256C1 - HV load switch has drive for second movable contact supplied with release signal when first driven contact reaches given position - Google Patents

Abstract

The HV load switch has a contact system provided with 2 driven contacts (2,8), operated by respective drives (7,10), which are interlinked so that the release signal for the second drive is provided after the contact operated by the first drive has reached a given position. The position of the latter contact can be provided via an electromagnetic sensor (14), a variable resistance device, or a pair of auxiliary contacts.

Description

The invention relates to high voltage power switch, the contact system forming the switching path with a first contact movable by a drive and with a second drivable contact is provided.

Such a high-voltage circuit breaker is an example as known from DE 196 22 460 C2. With the well-known The contact system has two high-voltage circuit breakers by a common drive in the opposite direction drivable contacts. The drive movement is by means of a first drive element on the first contact and with means of a second drive element and a transmission transfer the second contact. One hotter for guidance Isolating nozzles serving switching gases arranged at the first contact se serves as a coupling element.

The insulating nozzle and the gearbox must be designed in this way be that they the forces occurring during switching operations transferred reliably. It is particularly important when switching off who desires that the contacts with a high Ge separate speed to master high breaking capacity . To increase the separation speed of the contacts the contacts are driven in the opposite direction ben. In addition to the high thermal load, the insulating nozzle se in the known high-voltage circuit breaker also one exposed to strong mechanical stress.

The present invention has for its object a High-voltage circuit breakers of the type mentioned above  train that the mechanical load on the insulating nozzle is reduced.

The object is achieved according to the invention with a high voltage Circuit breaker of the type mentioned by a additional to assigned to the second drivable contact driven by one in a predetermined position of the he Most movable contact trigger actuation signal generated cash is resolved.

With the additional, the second drivable contact ordered drive is the usual until now over the Isolierdü se running coupling of the two contacts for transmission canceled by driving forces. This will make the mechanical Load on the insulating nozzle significantly reduced. The second The drive acts on the second independently of the first drive Contact. The required dependence of the movement processes of the two contacts from one another is now thereby realized that depending on the position of the first Contact an actuation signal for the second drive he is fathered. By this forced control of the second type the safe switching behavior of the high-voltage Circuit breaker guaranteed.

That generated depending on the first moving contact Actuation signal can be generated in different ways become.

A first advantageous embodiment of the invention for this provides that the actuation signal by means of a Stel development of the first contact-sensing arrangement with change resistance is triggered.  

By using variable resistances, which the To map the position of the first contact is constructive easy and inexpensive way given the second Forced drive control.

An alternative embodiment of the invention provides that the actuation signal by means of the position of the first Contact detecting arrangement triggered with auxiliary contacts is.

Such a design takes into account that at a high voltage circuit breaker for detection and reporting ver various parameters, various auxiliary contacts are provided are that can be designed so that certain Have positions of the first contact recorded. Existing Technical facilities can therefore be inexpensively modified adorned and used for the control of the second drive become.

It can also be advantageous that the actuation signal with means of a position detecting the first contact order is triggered with light barriers.

By using light barriers, there is no contact se arrangement for detecting the position of the first contact to disposal. This variant is easy on ver Different versions of the high-voltage circuit breaker customizable. Ready-made modules can be used only at a suitable point, for example a shift linkage.

Another variant in the design of the invention provides that the actuation signal by means of a Stel  development of the first contact detecting arrangement with in one Compression and / or heating volume arranged pressure sensors is triggered.

Such an embodiment of the invention takes into account that pressure changes in a compression and / or heating volume are also dependent on the position of the first contact. No ben this assignment, it is possible to the pressure sensors Collecting data, such as historical data of an increase in pressure. From this data you can then for example, signs of wear can be detected.

An advantageous embodiment of the invention is also then given when the actuation signal by means of a Stel development of the first contact detecting arrangement on the first Movable contact arranged force sensors is triggered.

This configuration takes into account that the drive in its Force course is subject to changes from one another the switch contacts and the pressure build-up in the compressor volume is dependent. Certain positions of a switch contact can be assigned to characteristic force profiles become. For example, the interlocking of Switch contacts connected with an increased driving force. The position of the first contact piece is therefore with means of a force-displacement diagram can be clearly recorded. A sol The force-displacement diagram also enables statements to be made about the state of the contact system, for example, Ver signs of wear on the contacts due to changed Frictions can be identified in good time.

An advantageous embodiment of the invention can also be found therein exist that the actuation signal by means of a Stel  development of the first contact detecting arrangement with electro magnetic sensors is triggered.

Electromagnetic sensors have a small construction volume and also enable direct electronic ver data processing. They can therefore be well within an egg ner switching chamber, which only has a limited space for additional che devices, arrange.

Regardless of the options described above Triggering the actuation signal is advantageously a redundant generation of the actuation signal provided.

By redundant generation of the actuation signal ensures that if a system fails to generate of the actuation signal another system the actuation signal generated. This is the second control Drive ensured and an incorrect switching of the Contact system is avoided.

The invention is based on a drawing cal shown mathematically and described in more detail below.

The shows

Fig. 1 shows a pole of a high voltage circuit breaker with a Steuerungsanodnung,

Fig. 2 shows a variant of Fig. 1,

Fig. 3 shows a detail of a variant embodiment with a ver änderlichem resistance,

Fig. 4 shows a detail of a variant embodiment with a force sensor,

Fig. 5 shows a detail of an embodiment variant with a pressure sensor and

Fig. 6 shows a detail of an embodiment variant with an auxiliary contact.

The high-voltage circuit breaker according to FIG. 1 has an encapsulation 1 which surrounds a contact system. The contact system has a first arcing contact 2 and a first nominal current contact 3 . The first rated current contact 3 and the first arcing contact 2 are connected to one another in an angle-stiff manner. At the first rated current contact 3 Iso lierdüse 4 is arranged. A compression volume 5 and a heating volume 6 are arranged coaxially with the first arcing contact 2 . The first arcing contact 2 and the first nominal current contact 3 can be driven by a first drive 7 .

Furthermore, the contact system has a second arcing contact 8 and a second nominal current contact 9 . The second rated current contact 9 is mounted in a stationary manner. The second arcing contact 8 can be driven by a second drive 10 .

A sensor 14 for detecting the axial position of the first rated current contact 3 is arranged on the encapsulation 1 . The first drive 7 is designed in a known manner as Federspeicheran drive; the second drive 10 is also in a known manner as an electromagnetic drive.

A control module 11 is provided to control the first drive 7 . The second drive 10 is controlled by a dependence acting in depen of the position of the first arcing contact 2 and the first rated current contact 3 Zwangssteuerungsmo dul 12th Furthermore, a redundant forced control module 13 is provided, which takes over the control of the second drive 10 in the event of failure of the forced control module 12 or the sensor 14 .

The mode of operation of the arrangement shown in the switch-off position in FIG. 1 during a switch-off process is described below.

In the associated switch-on position, the first arcing contact 2 and the second arcing contact 8 as well as the first nominal current contact 3 and the second nominal current contact 9 are in electrically conductive connection with one another. The control module 11 generates a switch-off pulse, which acts on the first drive 7 . This switch-off pulse also acts on the redundant positive control module 13 . The first drive 7 moves the first arcing contact 2 and the first rated current contact 3 in the switch-off direction. The sensor 14 detects the position of the first rated current contact 3 . The sensor 14 is an electromagnetic sensor, which detects the magnetic field emanating from an arranged on the first nominal current contact 3 as the acting permanent magnet 15 . When a certain position of the first nominal current contact 3 is reached, a switch-off signal for the second drive 10 is triggered by the positive control module 12 . The second drive 10 moves the second arc contact 8 in the switch-off direction. In the event of a fault in the forced control module 12 or the sensor 14 , the second drive 10 is controlled by the redundant positive control module 13 . In Fig. 1, this redundant Zwangssteue module 13 is time-controlled. The redundant forced control module 13 causes a time delay in the switch-off pulse generated by the control module 11 . After a time interval has elapsed, this switch-off pulse is transmitted to the second drive 10 in the event of a fault in the positive control module 12 or the sensor 14 .

The following functional sequence results when switching on. The first arcing contact 2 , the first rated current contact 3 and the second arcing contact 8 are in their switch-off positions. The contact system is open. The control module 11 generates a switch-on pulse. This switch-on pulse acts on the first drive 7 and on the redundant positive control module 13 . The first drive moves the first arcing contact 2 and the first rated current contact 3 in the switch-on direction. The position of the first nominal current contact 3 is detected by the sensor 14 and transmitted to the positive control module 12 . When a certain position of the first rated current contact 3 is reached, the positive control module 12 outputs a switch-on pulse for the second drive 10 . The second drive 10 moves the second arcing contact 8 in the switch-on direction. In the event of a fault in the positive control module 12 or the sensor 14 , the redundant positive control module 13 forwards the switch-on pulse of the control module 11 to the second drive 10 after a time interval. This ensures that when the first arcing contact 2 and the first rated current contact 3 move, the second arcing contact 8 is also moved.

The high-voltage circuit breaker according to FIG. 2 differs from the exemplary embodiment according to FIG. 1 solely in the implementation of the redundant control of the second drive 10 . The first drive 7 is controlled by the control module 11 . The second drive 10 is controlled by a forced control module 12 . A sensor 14 detects the position of the first nominal current contact 3 and forwards it to the positive control module 12 . The sequence of switching on and off of the contact system and the control of the two drives 7 , 10 takes place in a known manner.

The position of the first rated current contact 3 is transmitted to a modified redundant positive control module 16 by means of a redundant sensor 17 . For this purpose, the redundant sensor 17 has a light barrier which, by means of a reflector 18 arranged on a transmission rod of the first drive 7, maps the movement of the first nominal current contact 3 and of the first arcing contact 2 . The redundant sensor 17 can also be designed as an electromagnetic sensor. As a variant, the sensor 14 can have a light barrier. If the positive control module 12 or the sensor 14 assigned to it work incorrectly, its function is completely taken over by the modified redundant positive control module 16 and the redundant sensor 17 assigned to it. The on or off pulses for the second drive 10 are then generated by the modified redundant positive control module 16 and transmitted to the two th drive 10 .

Further variants of the sensors 14 , 17 will be described in the following. The Fig. 3 shows a at the first rated current contact 3 disposed electrical resistance element 19. Between a first end 21 of the electrical opposing elements 19 and a fixed to the encapsulation 1 arranged sliding contact 20 , an electrical resistance can be determined. By the relative movement of the electrical Wi derstandselements 19 and the sliding contact 20 to each other, the measurable electrical resistance is variable. The measured electrical resistance is proportional to the sequence of movements of the first arcing contact 2 and the first rated current contact 3 . The positive control module 12 can generate the switching timpuls for the second drive 10 using the measured electrical resistance. This arrangement can be used in the same way for the redundant sensor 17 and the modified redundant positive control module 16 .

Another variant for determining the distance covered by the first rated current contact 3 is shown in FIG. 4 Darge. The sensor used is a force sensor 22 integrated in the transmission rod assigned to the first drive 7 . This force sensor 22 represents the forces occurring on the transmission rod during a switching process. These forces are essentially determined by the interlocking of contacts and by the change in gas pressure in the compression volume 5 . Thereby, the position of the first Lichbogenkontaktes 2 and the first rated current contact is 3 clearly detectable by means of an assignment of the forces occurring course sion bar at the Transmis. Using this information, the compulsory control module 12 is able to control the second drive 10 . This principle of determining the position of the first arcing contact 2 and the first rated current contact 3 can also be combined with the modified redundant forced control module 16 .

In order to determine the position of the first contact 2 and the first nominal current contact 3 , a pressure sensor 23 is arranged in the compression volume 5 in FIG. 5. This pressure sensor 23 generates an image of the pressure in the compression volume 5 . By means of the changes in the pressure in the compression lumen 5 , the position of the first arcing contact 2 and the first nominal current contact 3 can be clearly mapped. The pressure sensor 23 generates an input variable for the forced control module 12 . This principle of detecting the position of the first arcing contact 2 and the first nominal current contact 3 can also be combined with the modified redundant positive control module 16 .

Another way of determining the position of the most arcing contact 2 and the first rated current contact 3 as an input variable for the positive control module 12 or the modified redundant positive control module 16 is shown in FIG. 6. A cam 24 is arranged on the drivable first nominal current contact 3 . An auxiliary contact 25 is arranged in a fixed position on the capsule 1 . During the movement of the first rated current contact 3 , the cams 24, like the auxiliary contact 25, interact with each other when a certain position is reached such that the auxiliary contact 25 is closed. The switching state of the auxiliary contact 25 acts as an input variable on the positive control module 12 or the modified redundant positive control module 16 . If several cams 24 are arranged on the nominal current contact 3 (or other moving parts, such as transmission rods), it is possible to map the movement of the first nominal current contact 3 using a plurality of auxiliary contacts 25 with great accuracy.

Claims (8)

1. High-voltage circuit breaker, the contact system forming the switching path is provided with a first contact ( 2 ) movable by a drive and with a second drivable contact ( 8 ), characterized by an additional drive ( 8 ) assigned to the second drivable contact ( 8 ). 10 ), which can be triggered by an actuation signal generated in a predetermined position of the first movable contact ( 2 ). 2. High-voltage circuit breaker according to claim 1, characterized in that the actuating signal is triggered by means of a position of the most contact ( 2 ) detecting arrangement with variable resistors. 3. High-voltage circuit breaker according to claim 1, characterized in that the actuating signal is triggered by means of a position of the most contact ( 2 ) detecting arrangement with auxiliary contacts. 4. High-voltage circuit breaker according to claim 1, characterized in that the actuating signal is triggered by means of a position of the most contact ( 2 ) detecting arrangement with light barriers. 5. High-voltage circuit breaker according to claim 1, characterized in that the actuation signal is triggered by means of a position of the most contact ( 2 ) detecting arrangement with compression and / or heating volume ( 5 , 6 ) arranged pressure sensors. 6. High-voltage circuit breaker according to claim 1, characterized in that the actuating signal is triggered by means of a position which detects the most contact arrangement with the first movable contact ( 2 ) arranged force sensors. 7. High-voltage circuit breaker according to claim 1, characterized in that the actuating signal is triggered by means of a position of the most contact ( 2 ) detecting arrangement with electromagnetic sensors. 8. High-voltage circuit breaker according to claim 1 or one of the following, marked by redundant generation of the actuation signal.