DE2705808A1 - Switchgear for automatic disconnection of short circuited branch lines - has timing element with pneumatic compression chamber providing switching delay - Google Patents

Abstract

The electric switchgear will automatically cut out branch lines in medium voltage networks, which are subject to a short circuit. There is a relay and a separate circuit breaker on opposite sides of an insulated tube, and fuse holders with contact caps on the inside. There is a timing system which will delay the return of the cut-out element to the original setting. The timing element has a pneumatic compression chamber which can be compressed to exhaust the air, when the soft iron armature in the field of force of the magnetic coil presses against it. The return to the original position is delayed by throttling the air inlet to the chamber. The chamber has a filling section, and both are interlinked by a non-return valve.

Description

Switching device for the automatic disconnection of through

Short-circuit faulty branch lines in medium-voltage networks (addendum for patent application P 25 38 163.9) switching device for automatic disconnection of through Short-circuit faulty branch lines in medium-voltage networks, with a relay and a disconnector formed separately therefrom, the relay with its Magnetic coil and its inside the same movable soft iron armature on one End and the circuit breaker at the other end inside one with contact caps Insulating tube of a fuse carrier are housed and with one in the direction its contact isolating tel development spring-loaded switch pin of the isolating switch in the Means of the insulating tube, guided by a central tube, extends into the relay area; furthermore with one that acts directly on the switch pin, the switch pin in the disconnector in contact position holding lock, one of itself after de-energizing the solenoid from their force field moving back soft iron armature actuated trigger element for Loosen this lock in a dead or not short-circuit leading Time after repeated activation of the relay by the circuit breaker as with a timing element to delay the return movement of the trigger element in the Starting position.

The switching device according to the main patent can be in a housing of in the form of a fuse holder. Do this with the latch as well the trigger mechanism for the switch pin designed such that the switching device can be used in any situation. Around the switch pin for contact separation in the disconnector to unlock is as a timing element between the soft iron armature and the switch pin leading central tube an annular piston with seals provided to a hydraulically to create a tight annular cylinder space between this annular piston and the soft iron anchor establishes a hydraulic connection. Namely, the soft iron armature returns in the event of a power failure from the force field of the magnet coil excited by the circuit breaker to its starting position back, then the ring piston is pulled with it and thereby serves as a triggering device Piston guide tube approached the unlocked position. Does it come after or repeated excitation fails to unlock, the ring piston is activated by spring force pushed back into its original position. However, this return movement is delayed by an adjustable valve nozzle in the annular piston, so for a short time following excitation of the relay the piston guide tube its starting position has not yet reached and a subsequent unlocking movement as a result of another Excitation emanates from an already advanced position. This locking and unlocking mechanism works reliably and trouble-free. The annular piston is with its valve nozzle adjustable to exact delay times, it forms a useful timing element. The application of a hydraulic Pressure medium for actuation and Control of the switching processes, however, requires multiple seals both to the outside as well as inside the fuse holder.

It is therefore the object of the invention, the switching device according to the main patent, in particular by avoiding hydraulically operating devices, to simplify.

To solve this problem, a switching device of the type mentioned at the beginning Kind according to the invention characterized in that a pneumatic timing element Pressure chamber is provided which is drawn into the force field of the solenoid Soft iron anchor is compressible while blowing air, which is slowed down for a Expansion after the soft iron armature moves back out of the force field of the magnet coil is equipped with a throttled air inlet and on its movable boundary wall an actuator for releasing a coupling holding the falling soft iron armature and the trigger element for executing a movement in the same direction with one another connects, attacks.

The solution according to the invention simplifies the switching device by avoiding it the hydraulics with the many seals and the movable annular piston. At a simple embodiment, the air required by the pressure chamber from the environment or can be taken from the interior of the switchgear.

It is useful, however, to assign a filling space to the pressure space and thereby creating a closed, pump-like acting compressed air system. In addition a bellows is particularly suitable as a boundary wall.

Further features and details of the invention are as follows Description of an embodiment that is shown in the drawing, refer to. Show it: Fig. 1 is a section through a single pole Load switch in the switched-on and rest position, FIG. 2 shows a section of the relay part 1, but in the excited state, FIG. 3 shows a section like FIG. 2, after completion of the first excited state, FIG. 4 shows a section like FIG. 2 after repeated Excitation, FIG. 5 shows a section through the load switch according to FIG. 1, in the switched-off position, 6 shows a section through the foot part of FIG. 1 with a device for a Triggered after three excitations, FIG. 7 shows a section like FIG. 6 with the device for triggering after a single excitation as well as a device for a manual one respectively.

tripping excited by other poles; Defect point, without switching devices for separating branch lines, Fig. 9 the same Network diagram with switching devices for the branches, Fig. 10 the same network diagram with switching devices and their ramifications, Fig. 11, 12, 13, 14, 15 and 16 current-time diagrams at different Short circuits and switching operations.

The current flow leads in the switching device shown from one lower contact cap 5 to a cylindrical copper tube 70, in the upper part a solenoid 7 is incised, the end of which connects to a tubular cylinder 8. From this, the current is transferred via roller contacts 9 to etin switch pin 10, the upper end of which is inserted into a tulip contact 11, which is expedient is clamped into an upper contact cap 12 by means of a spring ring 71. A Insulating tube 13 forms a housing jacket of the switching device. It is with the contact caps 5 and 12 connected pressure-tight in a suitable manner. At the bottom Section it is drilled larger. Here it centers the solenoid 7 and one Flange of the tubular cylinder 8. Between this flange and the tubular jacket shoulder a disc spring 6 is introduced with preload, which in the event of temperature fluctuations and dynamic stress in the event of short circuits ensure an even contact pressure guaranteed.

The lower contact cap 5 has a shoulder on the inside. A flange of a central tube 16 strikes against this with a snug fit. A round wire spring washer 72 holds the flange in place. At the upper end of the central pipe is the stationary one Part of a ball cage 17 attached. The central tube hole is used to guide the Switching pin 10. An O-ring is pre-tensioned in a groove in the switching pin 73, which presses against the central pipe bore and in the stationary as in the moving state the switching pin ensures a seal against moisture and dust. in the outer edge of the flange of the central tube 16 holes are attached in which the stop pins 74 are guided. Parallel to the central hole in the central tube 16 a further bore is formed or a longitudinal groove cut into it, which is also through the lower part of the stationary ball cage 17 extends. In it becomes a steel wire needle 69 is guided. This is connected to a release pin 20.

A manual or another can be used via an insulating rod Tripping triggered by the switch poles.

At the upper end of the cylinder tube 8 is made of insulating material Pen holder 21 attached. Its central bore guides the switching pin 10. A threaded tulip of the spring holder has a cylindrical bore 22 and one located in the bottom Nozzle bore 23. II trap a trip of the switch can a tension spring 24 relax and a tension anchor 25 with its lower piston part Pull into the cylindrical bore 22. The surge of kinetic energy is here captured by the displacement of the air from the cylinder 22 via the nozzle bore 23 (Fig. 6). In the switching pin 10 a groove is cut into which a spring washer 26 is engaged. The tensile force of the spring 24 is thus transferred from the tension anchor 25 Transfer the spring ring support to the switch pin 1o. However, this cannot evade when he is at the top of his incised longitudinal groove 27 of steel balls 28, which lie symmetrically in the bores of the ball cage 17 and on the switching pin be pressed, is supported (Fig. 1). A cylindrical trigger slide 29 with an inner nose flange 75 as a sliding guide and spring pad as well as a conical ball tumbler prevents the steel balls 28 from dodging. A ring 30 is plugged onto the stationary part of the ball cage 17 and is secured by a round wire spring washer held. It serves for the upper guidance of the release slide 29 and for support a locking spring 31. The release slide 29 has a groove at the upper end, in which a spring ring is locked as a release stop 32.

Inside the solenoid 7 is located, separated by a small Gap spacing, a soft iron anchor 33. An inner cone is formed on its upper part. A stop ring 76 is attached to the upper end of the soft iron anchor, which is held by a Compression spring 34, which is slightly pretensioned in the rest state, on a conical ring 53 is pressed. This conical ring 53 sits with a press fit in the tubular cylinder 8, where it is held in place by a spring ring 56. A light spring ring is supported on this spring ring Compression spring 55, which bears on a ball clamping ring 54 and in every position of the switch to evade the in the Conical ring inlaid locking balls 52 prevented.

If the anchor is at the upper stop, the locking balls have 52 a slight play compared to the conical ring 53 and a trigger tube 77. This The trigger tube is turned behind in the upper section to form a ball pocket 78, into which the steel balls 28 can move when a switch is triggered. That Trigger tube 77 is slid easily over the central tube 16 and is by means of a tension spring 79 is held in abutment on an attachment ring 80 in the central tube 16. When the trigger tube 77 is raised, the locking balls lock earlier how the free-wheeling balls 9o release the lock when tightening the soft iron armature 33. The two cones therefore have different inclined surfaces.

The central tube 16 is surrounded by a pneumatic timing element, that sits on its flange. It consists of two tubes pushed into one another. The inner tube 81 is slightly longer than the outer tube 82. An O-ring 83, which through a spring ring 84 is pressed against each other, seals them against each other. On a flange of the inner tube 81 is an upper bellows 85 and on the thicker flange of the outer tube 82 a lower bellows 86 attached. Both bellows are in the middle with each other connected and this rigid connection engages an actuating tube 88, which with a pretensioned compression spring 89 on its flange to the soft iron anchor 33 is pressed. The length of the actuating tube 88 is dimensioned so that in the stop position the freewheel balls 9o, as well as a ball clamping ring 91 and the compression spring 92 opposite the inner cone of the soft iron anchor 33 and the trigger tube 77 are slightly lifted off.

With a conical one carried by the rigid bellows connection Sealing lip 87, which strikes against the outer tube 82, becomes a spatial separation of the pneumatic space of the timing element into a filling space 93 and reaches a pressure chamber 94. Both rooms are via an opening 95 in the shell of the outer tube 82 and the nozzle bores made in the flange of the outer tube 82 96 connected to each other. The communication between the two bellows spaces can be achieved by means of a controllable nozzle needle 97 are reinforced or throttled.

To stimulate the switching mechanism of the switching device according to the invention, the excitation current JA must be a multiple of the highest operating current JB. It it is no longer a matter of briefly occurring load peaks, but of disruptive short-circuit currents JM.

In Fig. 2 is the electropneumatomechanical device of the switching device shown in the excited state.

The current flow in the magnetic coil 7 has at least the value YES reached and thus assumed a magnetic force field around the soft iron anchor 33 to pull into this. The opposing forces of the pretensioned compression spring 34 and the compression spring 89 on the actuating tube 88 must be overcome. When the pressure rises, the air in the pressure chamber 94 passes through the sealing lip 87 into the filling chamber 93 off. The lower bellows 86 is compressed and the upper bellows 85 stretched proportionally to the change in volume.

The stop ring 76 has moved when the soft iron anchor 33 is tightened released from the locking balls 52. This causes them to move down and jam the conical ring 53 with the trigger tube 77. The trigger tube therefore remains in his Position unchanged on the attachment ring 80. The freewheel balls 9o move with the soft iron anchor with. This is not pulled into the center of the force field, because over the actuating tube 88 and the stop pins 74 are limited in travel. At the time the impact of the soft iron anchor 33 on the stop pins 74 is the displacement the air via the sealing lip 87 in front of the pressure chamber 94 to the filling chamber 93.

The steady state of FIG. 2 is maintained until the short-circuit time At 1 has ended and the circuit breaker 1 is at the network node switches to pause time Pt 1.

This case is shown in Fig. 3, the switching device during the break Pt 1 shows shown. Due to the power interruption, the force field is also the Solenoid 7 collapsed and the tensioned compression spring 34 now pushes free soft iron anchor 33 up to the stop on the conical ring 53. The freewheel balls 9o block themselves in this reversal of movement between the inner cone of the soft iron anchor 33 and the trigger tube 77, which is thereby pushed up with the soft iron anchor. The locking balls 52 do not hinder this movement.

With reference to FIGS. 9 and 11, the short-circuit excitation can be Atl (Fig, 2) act around an arc flashover, which occurs in the pause time Pt 1 of the circuit breaker 1 is made to go out. When switched on flows then the normal operating current JB 2. If this continues, the compression spring is 89 bring the actuating tube 88 into its starting position.

Via the rigid connection of the actuating tube 88 to the bellows these are also brought back to the dXe starting position with simultaneous volume equalization between pressure chamber 94 and filling chamber 93. Since the sealing lip 87 blocks in this direction, is a compensation only via the opening 95 and the nozzle bores 96, which through the nozzle needle 97 can be reduced or enlarged in the flow to achieve. After a by setting the nozzle needle a predetermined time the actuating tube 88 will reach the clamped freewheel balls 9o and through their lift release the lock. The trigger tube 77 is thus free and from the Tension spring 79 is withdrawn as far as the attachment ring 80. The initial state according to Fig. 1 is now restored.

However, if a short circuit forwarding is unsuccessful, as shown in FIG and switches the circuit breaker 1 after a pause time Pt 1, which is based on empirical values A fraction of a second is closed again, then the state according to FIG. 3 remains almost unchanged. A repetitive stimulation occurs (FIG. 4). Your process can be compared with the excitation according to FIG. 2. However, there is a difference in that the trigger tube 77 is raised after the completion of the first excitation and its upper end is close to the trigger stop 32. Now becomes the soft iron anchor 33, pulled into the magnetic force field, as already described earlier, loosens the stop ring 76 of the locking balls 52 and these clamp themselves between the conical ring and trigger tube 77, minus that caused by the play of the ratchet balls 52 Yield and hold the trigger tube 77 in the raised position. The freewheel balls 9o solve their lock on the inner cone of the soft iron armature 33, its path over the actuating tube 88 is limited by the stop pins 74. This arrangement lasts as long as until after the graduation time St 1 of the protective device in the network node of the Circuit breaker 1 switches off. The short circuit excitation YES is ended with the Switch S 3 in junction 3 according to FIG. 9 switches to tripping.

The time of tripping is shown in the current-time diagram in FIG. 15 labeled AS 3.

In Fig. 5, the disconnection process is shown on the single-pole switching device. As already described for FIG. 3, the force field of the magnetic coil 7 is after separation of the short circuit interrupted. The pretensioned compression spring 34 can relax and presses the released soft iron anchor 33 up to the stop on the conical ring 53. The free-wheeling balls 9o lock between the inner cone of the soft iron armature 33 and the trigger tube 77, which is carried by the anchor until it is with its end hits the trigger stop 32 and the trigger slide 29 by lifting opens. The tensioning force of the locking spring 31 is far below the counterforce of the compression spring 34, so that no critical hindrance can occur when it is triggered. Also supports the conical ball tumbler on the release slide 29 the opening process, because the Tension spring 24 exercises over the edge of the longitudinal groove 27 in the switching pin lo on the steel balls 28 exert a pressure that pushes them outwards. There is a parallelogram of forces here between the force of the locking spring 31 in connection with the angular inclination of the conical Ball tumbler and the force of the mainspring 24. However, the balance of the forces must here are decisive for the guard locking. The steel balls 28 give way to the ball pocket 78 of the trigger tube 77 and release the switch pin lo, which is about the force the tension spring 24 for contact separation with the tulip contact 11 and thus for disconnection leads. The lower piston part of the tensioning anchor 25 is thereby inserted into the cylindrical bore 22 of the spring holder 21 pressed and its kinetic energy by a brief Air compression is collected, which is relaxed via the nozzle bore 23.

As described in FIG. 15, a disconnection of the switch in In the event of a malfunction, this can only take place in a no-voltage break at time AS 3. The establishment for arc quenching is for the case after Fig. 13, with shutdowns A or switchovers for operational reasons can be carried out manually by a line section carrying operating current JB have to. Certain plastics have the property when exposed to hot plasma come into contact to split off gases which are suitable for switching light arcing Bring extinction. For this purpose there is an extinguishing pipe below the tulip contact 98 attached, which is supported with its flange on the housing jacket 13. in the Extinguishing pipe 98 arc bores 99 are attached. Will a shutdown of a operating current-carrying line initiated, is between the tulip contact 11 and the switching pin 1o drawn an arc. The tension anchor 25 has a flange, which brushes against the housing jacket 13 and in the quick switch-off process, like a piston in a cylinder that compresses the air beneath it. Since the amount of air within the Switch housing is not changed, arises between the disconnecting tension anchor 25 and the extinguishing tube 98 a vacuum, which the hot plasma through the arc holes 99 pulls, causing the arc with the gas splitting off in the plastic pipe is deleted.

The device for manual deactivation is shown in FIG. For this purpose, the trigger pin is operated in a known manner by an isolated trigger rod 20 raised against the compression spring 68. Permanently connected to the release pin stands a steel wire needle which is in a bore and groove of the central tube 16 lies and through a hole in the ball cage 17 to the lowest part of the nose flange 75 of the release slide 29 is sufficient, which causes a disconnection after lifting, as has already been explained in more detail for FIG.

FIG. 1o shows a network diagram in which, as in FIG Switches s 4 according to the invention are installed in the branches 4 of the branches 3 are. A triggering process in the manner described above would bring here however, no advantages, because a short circuit in the branch 4 would be unsuccessful Short-circuit forwarding of circuit breaker 1, switch S 3 and switch S 4, shutdown. To a gradation of the releases and thus a selective one To achieve separation of switches S 4 and S 3, stop pins are on the switching device 74 inserted into bores in the flange of the central tube 16, which refer to a Support spring ring 67, which can optionally be inserted into one of the grooves 66 in the Inside the lower contact cap 5 is engaged. This can be done in a simple way the stroke HW can either be lengthened or shortened. Fig. 6 shows the device with a shortened stroke, while the extended stroke HW is shown in FIG. 7. In Fig. 7, the stroke of the soft iron armature 33 is extended, so that the pneumatomechanical The device is already ready to trip at the first short-circuit excitation and after the start of the pause time Pt 1 it switches off. 14 shows shows this switching process in a current-time diagram. JB 3 is the operating current, which flows on junction 3 and its branch 4, At 1 is the short-circuit excitation time, AS 4 is the switch-off time of switch S 4 at branch 4, PT 1 the pause time of circuit breaker 1 and JB 3 - JB 4 is the operating current at junction 3, minus the separated branches 4. However, selectivity is only given if if the switch S 3 is designed for two-time excitation, as previously shown in Fig. 15 has already been described.

6, on the other hand, shows the device with the stop pin raised 74. This shortens the stroke HW of the soft iron armature 33. The pneumatomechanical Setting up the switch requires three short-circuit excitations in order to be in the Trigger pause time Pt 3.

As shown in the current tent dlagromm of FIG for the circuit breaker 1 requires an automatic downstream switching device NE. The short circuit K 3 is assumed here at junction 3 according to FIG. The trigger of switch S 3 takes place here at time A S 3.

The switch gradation is twice and for switch S 4 for the switch S 3 a three-time excitation with subsequent shutdown.

If the short-circuit point is at branch 4, according to Fig. 16, the switch S 4 is switched off at time A S 4. For the turnoff 3 the supply would continue after the pause time Pt 2 has expired, JB 3 - JB 4.

If, in the event of a short circuit, a switch is triggered on a branch line, the pantographs affected by the shutdown will soon have a Power interruption reported to the responsible operating point.

The point of failure has already been localized. After fixing the Malfunction, the switchgear must be manually switched to the switch-on position. To this For this purpose, the switch pin 1o is pressed into the switch compartment until the longitudinal groove 27 the steel balls 28 and the conical ball tumbler of the release slide 29 presses the steel balls 28 into the longitudinal groove 27 with the force of the locking spring 31.

The switch-on process is now complete and the switch position is complete according to FIG. 1 achieved.

To make it easier to switch on, there is a hole on the switch pin lo 62 for engagement of a simple tool such as a screwdriver.

Damage to the smooth bore of the central tube 16 is thus also avoided.

As described in the remarks, the switching device according to the invention is created for a variety of uses. After accepting the cover 65 can through simple intervention via the nozzle needle 97 a time adjustment made, or by adjusting the spring ring 67 a change of the switching sequence can be achieved.

The so-called timing element is in itself a closed unit. It is normally filled with the ambient gas in the switch housing. The time adjustment The nozzle needle 97 can be increased by a power of ten if the filling takes place with light o1.

Claims (8)

Claims Q switching device for the automatic disconnection of Short-circuit faulty branch lines in medium-voltage networks, with a relay and a disconnector formed separately therefrom, the relay with its Magnetic coil and its inside the same movable soft iron armature on one End and the circuit breaker at the other end inside one with contact caps Insulating tube of a fuse holder are housed and one in the direction its contact disconnected position spring-loaded switch pin of the disconnector in the middle the insulating tube, guided by a central tube, extends into the relay area; furthermore with one that acts directly on the switch pin, the switch pin in the disconnector in contact position holding lock, one of itself after de-energizing the solenoid from their force field moving back soft iron armature actuated trigger element for Release this lock in a dead or not short-circuit leading Time after repeated activation of the relay by the circuit breaker and with a timing element to delay the return movement of the trigger element to the starting position, characterized in that a pneumatic pressure chamber is provided as a timing element is that of the soft iron armature drawn into the force field of the magnetic coil (7) (33) is compressible while blowing out air, allowing for slowed expansion after moving the soft iron armature back out of the force field of the magnetic coil with a throttled air inlet is equipped and on its movable boundary wall an actuator for releasing a coupling holding the falling soft iron armature and the trigger element for executing a movement in the same direction with one another connects, attacks. 2. Switching device according to claim 1, characterized in that the pressure chamber (94) is assigned a filling space (93) and both rooms about one only Check valve opening to the filling chamber and one leading from the filling chamber to the pressure chamber throttled Uberstömkanal are in communication with each other. 3. Switching device according to claim 1 or 2, characterized in that Pressure and filling space (94, 93) in the form of a ring directly adjacent to one another around the central tube (16) with fixed end flanges and a bellows (86, 85) as the outer boundary wall are arranged, with a rigid connecting wall separating the rooms with a Sealing lip (87) provided as a check valve and the overflow channel in the one on the central tube adjacent double wall (81, 82) is formed. 4. Switching device according to one of claims 1 to 3, characterized in that that a valve with an adjustable nozzle needle to throttle the overflow air (97) is built in. 5. Switching device according to one of claims i to 4, characterized in that that an actuating tube (88) is provided as the actuating element for the clutch, one end of which is attached to the rigid connecting wall of the bellows (85, 86) is, while the other end releases the clutch in the starting position and a circumferential shoulder formed thereon the soft iron armature (33) on its the magnet coil (7) engages under facing end face. 6. Switching device according to claim 5, characterized in that the insulating housing Stop pins Q 4) aligned with the actuating tube to limit the movement the actuating tube (88) and the soft iron armature (33) are adjustably supported are. 7. switching device according to one of claims 1 to 6, characterized in that that in the range of motion of the iron anchor (33) a trigger tube (77) surrounds the central tube (16), the soft iron anchor on its inner surface in the direction of the disconnector, the cone widening and in this cone space Freewheel balls (90) inserted to clamp the trigger tube and the soft iron armature are spring-loaded in the direction of the clamping position, but in the starting position are pushed out of the clamping position by the actuating tube. 8. Switching device according to one of claims 1 to 7, characterized in that that the trigger tube (77) is spring-loaded towards the starting position and in the The initial position is held by an attachment ring (80).