SE417880B - AUTOPNEUMATIC PRESSURE GAS POWER SWITCH - Google Patents

Description

7 10 45 * 20 25 'm 3 7-801417-2 = 2 _ In the case of a switch of the type described, a reverse blowing must take place into the hollow, movable coupling pin, it may be advantageous to avoid gas losses during the compression phase initially shut off the flow path through an additional valve mechanism nism (see German Pat 2,529,501). An advantage of this construction is that the gas flow distance until the nozzle is very short.

Another embodiment of autopneumatic compressed gas switches, which ket, for example, is known from the German publication 24 08 871 and M 53 68, has an insulating material nozzle which is stationary relative to active counter-contact and compression piston, ie not included in it movements of the contact. This is where the variable circuit breaker first stroke the nozzle and pull for refraction into the stationary nozzle.

Only in a fully withdrawn state is the baby released, This construction has the advantage that the arc first burns outside and then inside the nozzle but at low gas pressure and with little effect. This results in significantly less disintegration. sharing products. Since the compression chamber, where it is primed extinguishing gas is located, initially shut off through the switch pin, this existing fresh gas can not -j is mixed with ionized gas. In addition, pre-compression occurs without each_gas loss. i_The lower nozzle area most important for extinguishing is exposed to dast for a very short time for the arc. Only when it requires extinguished distance between the power contacts, it freezes moving switch pin compression chamber and blowing begins; An inconvenience at breaker of the above-described second embodiment. however, the compression devices are necessarily 'shows relatively long gas paths between the compression chamber and the clay material nozzle. Through the long flow path resp the high the flow resistance causes an undesirable pressure drop. Its- except the flow paths form dead spaces, which in some bridges even larger during the compression phase (German publishing scripture 21 08 874). Because the gas in this room can not be squeezed away through.compression piston, can very high compression pressures not achieved. A further inconvenience can be seen in the fact that after the release of the blow the compression stroke of the known switches as a rule is completed, so that the gas pressure drops relatively quickly during the extinguishing fasen.i 10 '15 20 50 E 40 ? 801 # 1? -2 The object of the present invention is to combine them the advantages of both known embodiments and in particular to propose one pneumatic compressed gas switch, which is characterized by simple construction and allows very high compression and short gas flow paths.

Furthermore, as little extinguishing gas as possible shall be lost, before the extinguishing distance is reached, ooh the energy conversion in the switch distance shall be small. At the same time, the arc burn time should be short and finally, even after the release of the blast, an additional compression be possible.

This task is solved according to the characteristics specified in the main requirement. the signs.

To further illustrate the invention, it is described therein the following four embodiments of an autopneumatic compressed gas breaker according to the invention, which are shown in the accompanying drawing. Where- at shows in longitudinal section Fig. 1 shows a first embodiment of the switch in switch-on position, Fig. 2 shows the switch according to Fig. 1 immediately before the contact disconnection ningen, Fig. 5 shows the switch according to Fig. ü during the extinguishing phase, Fig. 4 shows a second embodiment of the switch immediately before contact separation,. Fig. 5 shows a third embodiment of the switch in switch-on position and _ Fig. 6 shows a fourth embodiment of the switch in switch-on position.

I fig. 1-6 have all parts not belonging to the invention, such as drive device, support insulators, housings, parallel capacitances, etc. for for the sake of simplicity omitted. Equal construction parts have in all fi- gures are denoted by the same reference numerals.

The switch shown in Figs. 1-5 has current connections 55, 56. The stationary contact device 1 consists of a rated current contact 2 and a fixed power contact 5. A slidable in a control movable power contact 6 stored is pressed downwards by means of a pressure spring 14. In the engaged position (fig. 4) the power contact 6 is through a locking device 8 connected to the stationary power contact 5.

For breaking, one is driven by means of a bolt 58 fixedly linked drawbar 5 downwards, At the same time the guide 7, insulating material ~ nozzle 4 and cylinder 12 downwards. The extinguishing room in room 57 the gas is compressed. The flue gas supply duct and nozzle opening is closed in the initial phase through the fixed power contact 5, A very tight slot in the fixed power contact 5 a 10 45 20 a25 ao ast 40 7801417-Sat 4 prevents gas losses. The variable power contact 6 remains initially locked at the contact 5, whereby the compression spring 14 _tension. Thus, as shown in FIG. 2 shows the supply of the extinguishing gas flow channel and nozzle opening still closed.

The reading is canceled as soon as the annular ledge 15: abuts the upper edge of the guide 8 (fig. 2).

At the same moment, the power contacts 5, 6 are pulled apart and the beat 6 then snaps backwards accelerated through the spring 44 into the nozzle 4. Between the separated power contacts 5, 6 arises an unblown arc. _ 7 Instead of or in addition to the compression spring 44, the contact 6 kcäven is passed downwards through the gas stream. In this case, the ring the space between the guide 7 and the contact 6 through drilled channels 48 in the guide 7 connected to the upper of the compression chamber 57 part (Fig. 6).

Only when the power contact 6 has released the nozzle 4 and the inflow channel, the pre-compression phase ends and the arc the blowing with the pre-compressed extinguishing gas. The time of con- the stroke disconnector and the drive rod 5 and the power contact 6 speeds are so attuned to each other, that in this moment the pressure of the extinguishing gas and the contact distance are sufficient to break the short-circuit current. The blowing then continues through further reduction of the room 57. The extinguishing gas stream exits through the nozzle 4 and partly through the hollow contact 6 together drilled channels 40g (baokblowing). The insulating material sleeve pushed upwards by a compression spring 15 san 16 has the task of protecting the locking device 8 against arc impact. To brake the movable power switch 6 in the end position 'there is a damping plastic ring 17.' Switch feedback and independent power contacts hooking is done by moving the drive rod 5 upwards.

The switch shown in Fig. 4 differs from the one shown above. written by the fact that the hooking device 9 for the movable the power contact 6 is built into the stationary piston 11. This has the advantage that it is not exposed to the arc. The hooking device 9 consists of several over the guide 7 circumferentially distributed, front cut-off bolts 19, which are displaced W bart stored in radial bores 20 in the piston 11. They exhibit to a projection 21 for supporting the movable power contact 6. The bolts 49 are pressed through compression springs 22 inwards against a stop 10 15 20 25 50 55 7801417-2 25. In order for the bolts 19 to be able to grip through the movable guide 7, the latter has several longitudinal slots 24.

Fig. 4 shows the switching position immediately before the contact 6 released. Just before the ledge 15 from below hits the steering 7 upper edge, the bolts are pushed through the inclined surface 52 at the slots 24 upper end outwards and contact 6 is released. As described above, it is clayed by the spring 14. The projection 21 is only in the center of the oblique front surfaces of the bolts 19 and enters a counter- corresponding grooves in the inclined surface 52. This ensures that the bolts 19 is then completely pushed back into the radial channels 20.

For reconnection, the drive rod 5 is moved upwards. A wide effect the sleeve 59 attached to the contact 6 prevents the bolt 19 from penetrating into the spring 14. A ledge 41 at the lower end of the contact 6 makes it possible to insert the projection 21 under the contact 6 and thus its locking.

Another variant of the hooking device 10 for the contact 6 is shown in Fig. 5. This is an already known device, which described in German Pat 1,540,062 under the designation " verriegelung ", ie piston ring locking.

This locking method has compared to a latch the advantage that the acting force is distributed over a relatively large area and that one can thus handle very high forces.

The reading shown here consists of one in a ring groove 26 in a support ring 27 mounted piston ring 25, which in locked condition rests against a ring surface 28 on the piston 11. The support ring 27 is attached to several over the circumferentially distributed bolts 29 of the movable power contact 6, which grips through longitudinal slots in the guide 7. To expand the piston ring 25 in the locked state is used one with a compression spring 50 loaded pin 51.

Based on the switch-on mode shown in the figure, it is entered the drive rod 5 or the guide 7 downwards in order to switch off. So soon the pin 51 through a front end fixed to the guide 7 inclined pin 15 against the force of the spring 50 is pushed outwards, the piston the ring 25 through the inclined ring surface 28 into the groove 26 of the support ring 27 and contact 6 is released in this way. Contact 6 is accelerated again about the spring 14 and is damped in the end position by a gas cushion 18 and a plastic ring 17.

For reconnection, the piston ring 25 is compressed under the control upward movement of the ring 7 through an oblique ring surface 54 on the piston 11 and returned to the plotted position. o. 7801417-2 10 _20 25 .w i äs 6 Fig. 6 shows a switch which consists of several connected in series ~ shredding sites for each pole. o o The figure shows the lowest connection point of a switch pole in the strike mode. The mechanical connection for driving adjacent The moving parts of the horizontal coupling point are made by means of insulating material. rialstavarf42. 7 7 _ 6 Again, continuous stationary insulating material cylinder 46 is provided the stationary parts of the coupling points, namely the counter-contact '1 with the power contact 5 and the rated current contact 2 and the compression the stationary bottom 47 of the space 57 and a locking device attached thereto. In the fixing process, for example, through unscrewed screws. where, . g f_ The moving parts of the switch include an insulating material nozzle 4; insulating rods 42 attached thereto, a guide 7 with a piston 43 and one with the guide 7.by an insulating rod 5_and a bolt 58 for- . tied, drive device not shown in the figure, Inside the guide 7 a movable power contact 6 is axially displaced apparently stored. It is actuated by a spring 14 and is lockable at the piston 11 by means of the locking device 10.

: The lower power connection 56 of the switch is attached to the from here the current flows via a ring contact 44 to the guide 7 and a second ring contact 45 to the movable one power contact 6. The current path continues via the stationary receiver connector 1, which consists of the power connector 5 and the rated current connector 2. The upper current connection of the terminal of the switching pole is 'closed to the stationary counter contact of the top coupling point 1.

Based on the position shown in the figure, it is drawn in and for 'switch off the rod 5 downwards. Hereby the control 7 moves with the insulating material nozzle 4 and the rated current contact 2 also in the direction 7 down. The power contact 6 initially remains in the on- position, as it is held in its initial position by locking the device 40§ By lowering the guide 7, the spring 14 is tensioned.

At the same time, the extinguishing gas in the compression chamber 37 is compressed through downward movement of the piston 45. Through a very narrow slit of the counter-contact 5 prevents extinguishing gas from flowing out prematurely.

As soon as the upper part of the guide 7 abuts an edge 45 The power contact 6, the same is released by a pin 35.

The locking device 10 corresponds to the piston ring the reading. 10 15 7801417-2 Below is a summary of the benefits of the switch according to the invention. 1. 20 5. 10.

Short arc time until the extinguishing distance is reached thanks to it the rapid spring drive of the variable power contact.

No blowing of the arc before the extinguishing distance is reached.

The arc burns under low gas pressure, until the extinguishing the distance is reached, resulting in a small contact and nozzle distance or a large number of possible short-circuit before an audit is required.

Insulating material nozzle for extinguishing crucial area is affected first in the extinguishing mode of the arc.

Until the extinguishing mode is reached, the compression chamber is separated from the arc, whereby the fresh extinguishing gas does not with ionized gas.

Short gas flow paths from compression chamber to nozzle and thereby low pressure drop.

Very small dead volume in the compression chamber, whereby one can achieve high final pressures.

The arcing of the arc begins only when the required minimum grinding extinguishing distance reached.

When the minimum extinguishing distance is reached, the extinguishing the gas further during the blowing.

No valve device is needed for the movable, hollow the power contact to prevent premature re-blowing.

Claims (9)

7801417-2 Patent claims Autopneumatic pressurized gas circuit breaker with a movable power connector (6) and a fixed counter-connector (1), with a pump device consisting of a stationary piston (II) and a cylinder (by means of a drive device together with the movable power connector (6) slidable ( 12) and with the insulating material nozzle (4) fixedly connected to the cylinder (12), the insulating material distance (4), is characterized in that the movable power contact piece (6) during interconnection of a compression spring (14) acting in the direction of switching off ) is slidably mounted in a guide (7) fixedly connected to the movable cylinder (12), that a locking device (B, 9, 10) I is arranged, by means of which the movable power contact piece (6) is held in the switch-on during the first phase of the breaking process. position and by means of a release device depending on a given cylinder stroke is releasable and that for shutting off the insulating material nozzle (4) during the first phase of the breaking process the movable the outer diameter of the power connector (6) is equal to the inner diameter§ of the insulating material nozzle (4) Compressed gas switch according to Claim 1, characterized in that the movable power contact piece (6) is hollow and that it can be locked by means of an inner bead to a counter-contact piece (3) having an outer bead and that the power contact piece (6) in its inner contains a displaceable insulating material sleeve which is displaceable by a compression spring (15) in the direction of closing, which can rest against the inner bead (Figs. 1-3). in Compressed gas switch according to Claim 1 or 2, characterized in that the release device consists of a stop (13) arranged at the movable power contact piece (6) and a counter stop arranged at the guide (7). 9 7801417-2 Compressed gas switch according to Claim 1 or 2, characterized in that the movable power contact piece (6) can be locked by the locking device (9, 10) to the stationary piston (11) of the pump device (Figs. 4 and 5). Compressed gas switch according to claim 4, characterized in that the locking device (9) has several bolts each in radial bore (20) in the piston (11) mounted by a pressure spring (22) actuated each in said radial bore (20). (19), which grip through each axially directed slot (24) arranged in the guide (7) and with each side-sided projections (21) engage under a stop on the movable power contact piece (6) in its switching position and that at the counter-contact piece (l) showing the end of each axially directed slot (24), an oblique surface (32) is provided, which at the end of the first phase of the cut-off movement for releasing the power contact piece (6) runs towards a corresponding oblique surface on the associated bolt (19) and then displaces the same radially outwards against the force of the compression spring (22). Compressed gas switch according to Claim 4, characterized in that the locking device (10) has a support ring (27) surrounding the movable power contact piece (6) and the guide (7) and having an outer ring groove (26) which, by means of axial slots (19) gripping slots (24) in the guide (7) are fixedly connected to the movable power contact piece (6), that in the annular groove (26) a radially displaceable pin (standing) under the force of a compression spring (30) is mounted. 31) expandable piston ring (25), which in the locked position of the movable power contact piece (6) in expanded state rests both against the ring groove (26) and against a ring surface (28) on the stationary piston (11) and that at the guide (7 ) a bevelled pin (33) is arranged, which in the first phase of the disengagement movement due to the release of the power contact piece (6) presses the radially displaceable pin (31) against the force of the compression spring (30) radially outwards out of engagement with the piston ring (25). Compressed gas switch according to one or more of the preceding claims, characterized in that the power contact piece (6) is hollow and that a slidable insulating material sleeve (16) arranged by a compression spring (15) is arranged therein to protect the fixing device (8). against the effect of arc. 7901417-2 ((710 Compressed gas circuit breaker according to one or more of the preceding claims, characterized in that one of a plastic disc (17) and / or a compression chamber (18) is provided for end-end damping of the movable power contact piece (6). existing damping device. - Compressed gas switch according to Claim 6, characterized in that an inclined ring surface (34) is arranged at the piston (II) during compression of the piston ring (25) during actuation. Sat. Compressed gas circuit breakers according to claims 1 and 6, characterized in that they have several series-connected switching points for each pole and that all the switching points are arranged in a continuous, stationary insulating material cylinder (46), which forms the stationary counter-contact (2, 3) and the stationary the bottom (47) of the compression chamber (37) for each breaking point and at the same time forms the outer wall of the compression chamber (37) (Fig. 6). Compressed gas switch according to claim 10, characterized in that for the acceleration of the movable power contact (6) through the gas pressure in the pump device (27), the control (7) has several annular bores (48); Compressed gas switch according to Claim 10, characterized in that insulating material rods (42) are arranged inside the insulating material cylinder (46) which are attached to the first breaking count insulating material nozzle (4) and to the lower one. the end of the guide (7) for the adjacent breaking point. PROMISED PUBLICATIONS: