NO881062L - LIGHT SWITCH DEVICE FOR LOAD SWITCHES. - Google Patents

Description

The invention relates to an arc extinguishing device according to the preamble of patent claim 1.

An arc extinguishing device of the aforementioned type is described in DE-AS 11 32 622. The compressed air breaker described there consists of a pair of main separating knives and a double-legged auxiliary separating knife, both of which are stored in a common pivot point. The auxiliary cutting knife carries an extinguishing chamber and is connected to a folding bellows in such a way that in the last compressed air during the disconnection movement it flows into the extinguishing chamber and there produces the interruption of the arc current. In this connection, the folding bellows is attached with a control part provided with an internal bore which can be displaced in the longitudinal direction and which has its first contact in a point arranged eccentrically to the pivot point of the separating knife and its second contact in a pivot joint belonging to the extinguishing chamber. In the case of a disconnection movement, the main separating knife first breaks and in the further course includes the auxiliary separating knife with the extinguishing chamber, so that the two separating knives rotate at the same angular speed. Thereby, the air compressed by the compression of the bellows flows into the extinguishing chamber for blowing the auxiliary connection point.

With the known compressed air switch, air is used as extinguishing agent. Compared to a high quality insulating gas, e.g.

SF6 requires this for a successful interruption of the current in medium voltage networks a large flow rate of the air and which must be produced via a corresponding compression during the disconnection movement. In the known switch, the compression is produced by compression of a folding bellows. The size of the compression pressure is thus determined by the speed with which the folding bellows are pressed together. As both pairs of separating knives must also be moved during the compression phase, a proportionately large drive energy is required for successful disconnections.

The purpose of the invention is to improve the arc extinguishing device according to the preamble of claim 1 so that the switchgear filled with insulating gas with relatively low mechanical drive energy can be used in a simplified version in load switches. The stated purpose is achieved by an arc extinguishing

direction of the aforementioned nature and with the following features:

a) The auxiliary coupling part 3 is blocked during the first part of the opening sequence and follows the main coupling part 1 with a large

speed when the blocking is lifted by means of a spring 14 arranged between the coupling parts 1,3 which can be tensioned during the first part of the opening sequence.

b) The auxiliary coupling part 3 is equipped with a reservoir 7 with an opening 61 for the insulating gas arranged on one side in the direction of

the opening movement and which is in flow connection with the nozzle 6 and

c) the main connecting part 1 is connected to a part which occasionally cooperates with the reservoir 7 and with which gas by means of

volume change gas is displaced through the nozzle 6 into the arc 34.

The extinguishing device according to the invention must work

with the high-quality insulating gas found in the completely encapsulated switchgear, e.g. SF6. Since, due to the electronegative properties of the gas, the ionization properties in the zero crossing of the arc to be broken are also several times better than with air, a relatively low flow rate in the nozzle is needed. For this reason, the invention provides for the reservoir pressure which is formed in an open reservoir moved by the auxiliary coupling part to produce the gas flow during the arc's burning period at least during its first part. In the case of arcs with longer burning periods, e.g. in the phase that is to be extinguished last in a three-phase system, a further compression does indeed come into play. The production of the reservoir and compression pressure takes place in an energy-saving manner by the following sequence in the course of movement during an opening: - powerless opening of the main coupling part at arbitrarily low speed, simultaneous charging of a between the two coupling parts

arranged spring bearings,

- cancellation of the blocking of the auxiliary coupling part, formation of an arc^- subsequent rapid movement of the auxiliary coupling part under the action of the spring bearing acting between the two coupling parts, application of the gas flow towards the arc by means of

reservoir pressure,

- amplification of the gas flow by compression in the other

part of the subsequent movement, intensive blowing with longer arcs.

The specified course of movement enables the use of an advantageous drive device with relatively low energy, as the movement of the main coupling part, which is more or less mass-loaded depending on the current strength, and the charging of the spring bearing mainly have no effect on the course of the arc interruption and consequently do not need to be narrowly limited in time. As the auxiliary switch part only has to carry the operating current for a few milliseconds, it can be made with little mass and can consequently be quickly brought to a high speed.

Appropriate embodiments and further developments of the subject matter of the invention are specified in the subclaims.

In order to facilitate the understanding of the invention, it is explained in more detail in the following in connection with the drawing. Fig. 1 shows an elevation of a load switch pole with a pivotable connecting part with the arc extinguishing device according to the invention in the ON (I) position.

Fig. 2 shows a section of fig. 1 during the arc interruption.

Fig. 3 shows the same as in fig. 2, albeit with a variant of the auxiliary coupling part. Fig. 4 shows the section A-B according to fig. 2, through the nozzle body and reservoir. Fig. 5a,b,c shows a schematic diagram of a load switch pole with connecting elements that can be displaced in the longitudinal direction and in the positions "connected" (5a) during the disconnection (5b) and "disconnected"

easy" (5c) .

Fig. 6 shows a section of fig. 1 with the bellows during the arc interruption. Fig. 7 shows the section A-B according to fig. 6 through the nozzle body and the bellows. Fig. 8 shows a view of a pole of a three-way switch with the arc extinguishing device according to the invention.

Fig. 9 schematically shows a load switch with double interruption.

In fig. 1 shows a load switch pole built into a closed housing 31 filled with insulating gas. The current flows in position I from the busbar 32 over the connection 12 to the main contact 11, over the main connection part 1 to the pivot point 8 on the stationary contact 4 and to the connection 13 which is mounted on the high-voltage plug 33. The on-load switch is operated by the shaft 2 tightly guided through the housing 31 and the insulating connecting rod 4 8.

The main connecting part 1 consists of two parallel blades which carry the nominal current and in the event of a fault also take up the short-circuit load (fig. 4). In position I, the two knives contact the main contact 11 in the usual way. In the example shown, according to fig. 2 the shutter device according to the invention with the auxiliary coupling part 3, the nozzle body 16 and the reservoir 7 arranged between the blades of the main coupling part 1 and likewise rotatable about the pivot point 8. A piston 62 cooperating with the opening 61 in the second part of the turning movement of the auxiliary coupling part 3 and attached to the main coupling part 1 complements this embodiment of the arc extinguishing device according to the invention. Spring 14

is connected to both coupling parts 1,3 and it accelerates during the interruption the subsequent auxiliary coupling part 3 and pulls it to the stop 5. In this position the piston 62 is fully inserted into the reservoir 7.

In fig. 2, the main coupling part 1 has almost reached position 0 during a disconnection. Shortly before this, the auxiliary coupling part 3 was released by means of the carrier 9 from the barrier operating in position I between the nozzle body 16 and the auxiliary contact 17 attached to the stationary contact and now runs under the action of the spring 14 with the speed following the main coupling part 1 which moved with the clearly lower speed. The arrow indicates the direction of the gas flow.

Fig. 4 shows in section two different phases of the blowing of the arc. On the left side, the reservoir pressure P^ produced by the movement of the auxiliary switch part 3 acts, and the arrow shows in this connection how the gas flows into the reservoir 7, accumulates there and, by the resulting pressure difference Pj_~Pq, is led through the nozzle 6 at high speed to the arc 34.

On the right side, the main connecting part has reached the opening stUling 0, the piston 62 is already in the opening 61 and now compresses the gas present in the reservoir 7 to the pressure and enhances the gas flow through the nozzle 6, daP2>P]_-

The auxiliary coupling part 3 is arranged between the blades of the main switch part 1. As a low-mass component, it can best be manufactured from a light metal. The carrier 9 is rotatably arranged between the two knives on the main coupling part 1 in such a way that in the resting position it does not significantly protrude beyond the profile of the two coupling parts 1,3. The stroke 5 limits the movement of the auxiliary coupling part 3 in the rest position and ensures its entrainment during engagement movements (fig. 1 and 2).

In another embodiment of the invention, the subsequent auxiliary coupling part is itself designed as an elastic component in the form of a bending spring 15 (Fig. 3). In this connection, the bending spring 15 is fixed or clamped in the vicinity of the pivot point 8, e.g.

to a traverse 35 which connects the two knives on the main coupling part 1 and it can suitably be made stacked of several layers of a spring band steel. The short-term current load during the interruption process can be taken up by the spring cross-section or by one or more layers of a band with high conductivity (e.g.

Cu) which can be arranged in addition to the bending spring 15. The total energy required to produce the speed V2 is stored in the bending spring 15 upon disconnection and until the entrainment of the subsequent auxiliary coupling part 3.

In fig. 3 also shows a variant of the driver which consists of a lifting joint 36. In the extended position of the joint, the auxiliary coupling part 3 is thereby entrained at the beginning of the extinguishing process, while at the end of the disconnection movement (dotted line) the joint is folded between the two knives on the main coupling part 1 and not reduces the insulation distances to other live or earthed parts at protruding parts.

In fig. 5a, 5b and c show schematically how the arc extinguishing device according to the invention can also be used with slide switches. In this connection, both coupling parts 41, 42 can advantageously be designed as cylindrical or tubular parts. The stationary contact comprises a bell contact 51

which in the connected state transfers the current to the main connection part 41 from where it is diverted via the stationary contact to the lower switch connection. The auxiliary contact 17 is, as in the already mentioned embodiments, locked to the nozzle body 16. The nozzle body 16 is attached to the low-mass tubular auxiliary coupling part 42 which at the same time forms the reservoir for the gas and can be displaced parallel to the main coupling part 1. Between the coupling parts 41 and 42 a current transfer is arranged, f .ex. as a simple tow contact (not shown). A piston 62 is connected to the main coupling part 41 and cooperates with the auxiliary coupling part 42 which acts as a cylinder in its interior.

Fig. 5a shows the entire arc extinguishing device in the engaged position, with the piston 62 then standing in the auxiliary coupling part 42. After opening the main coupling part 41 (fig. 5b) and after the position corresponding to the smallest extinguishing distance has been reached, it strikes the main coupling part 41 attached catch 43 against the flange 44 on the auxiliary coupling part 42 and cancels the blocking between the nozzle body 16 and the auxiliary contact 17 (left side of fig. 5b). By the relative movement between the two coupling parts, the spring 45 has been pre-tensioned. It now pulls the nozzle body 16 and the auxiliary coupling part 42 at high speed in the disconnection direction, so that the gas occurring in the reservoir is blown through the nozzle 6 towards the arc 34. On the right side of fig. 5b, it can be seen how the spring 45 has already pulled the auxiliary coupling part 42 so far after the piston 62 again dips into the auxiliary coupling part 42 and with the help of the now formed compression pressure leads further gas into the arc 34.

In the disconnected position (fig. 5c), the auxiliary coupling part 42 lies against the ring 46 which is connected to the main coupling part 1 above the carrier 43. The piston 62 then remains as in fig. 5 completely in the interior of the auxiliary coupling part 42.

In fig. 6 and 7, the arc extinguishing device according to the invention is shown using a bellows 63 to displace the insulating gas. On the left side of fig. 7, in this connection, the auxiliary coupling part with the reservoir 7 is shown shortly after lifting the blocking between the auxiliary contact 17 and the nozzle body 16. A gas flow already acts on the arc 34 and is formed in the same way as in fig. 4, left side, at the pressure difference P^~Pq. On the right side of fig. 7, the reservoir 7 touches the bellows 63 along an edge or surface that is almost completely sealed. During the further course of movement, a displacement of gas occurs when the bellows 63 is compressed, which, due to the greater pressure p2, results in an increased blowing effect in the nozzle. In fig. 7, the end position of the main coupling part 1 with the bellows 63 is also drawn in, as this occurs both in the engaged as well as in the disengaged position of the extinguishing device.

The bellows 63 becomes due to intrinsic stability resp. by built-in springs held in the position where it comes into contact with the reservoir during the opening movement.

The arc extinguishing device according to the invention can advantageously also be used to improve the load switching function of three-way switches, as shown in fig. 8. Parts with the same function are thereby, with reference to fig. 1 denoted by the same reference number. In the third position of the connecting part 1, the mains part connected to the high-voltage plug 33 is grounded via the grounding contact 19.

The invention can also be used with advantage for load switches with double interruption, particularly when they are to be used at high voltages and/or at large load currents. In fig. 9 schematically shows a possible device in principle where again parts with the same function are indicated with the same reference number. The main switching part 101 is here made with two arms and is maneuvered by one for all three phases of a coupling's common insulation shaft 49. Both ends of the main switching part 101 are each provided with an auxiliary coupling part 103 with the nozzle body 16, reservoir 7 and spring 14. In the position I connects thereby the connecting parts 101, 103 each the busbar 3 2 with the high-voltage plug 33. Fig. 7 shows the extinguishing position for the two-armed load switch.

Claims (17)

1. Arc extinguishing device for load switches arranged in encapsulated medium-voltage switching systems filled with an insulating gas, which consists of a main switching part and an auxiliary switching part which, during the opening process of the load switch, follows the main switching part and thus, by means of a nozzle, produces the flow of the insulating gas directed towards the switch arc, characterized by that a) the auxiliary switch part (3) during the first part of the opening sequence is blocked and follows the main coupling part at high speed (v^ ) when the blocking is lifted by means of a spring (14) arranged between the coupling parts (1,3) which can spanned during the first part of the opening sequence, b) that the auxiliary coupling part (3) is equipped with a reservoir (7) with an opening (21) for the insulating gas arranged in the direction of the opening movement on one side and which is in flow connection with the nozzle (6) and that c) the main connecting part (1) is connected to a part which occasionally interacts with the reservoir (7) and with which, due to volume changes, gas is displaced through the nozzle (6) into the arc (34). 2. Arc extinguishing device for load switches according to claim 1, characterized by the following course of the opening movement: a) during the first part, the main coupling part (1) covers the largest part of the road and thereby occasionally releases the opening (61) of the reservoir (7), b) after lifting the blocking, insulating gas flows through the opening (61) into the reservoir (7) and blows the arc (34) through the nozzle (6) using the reservoir pressure effect, c) at the latest from when the minimum extinguishing distance has been reached at the auxiliary connection part (3) the phase for the displacement of the insulating gas begins. 3. Arc extinguishing device for load switch according to claim 1 or 2, characterized in that the connecting parts (1,3) during the opening process can be swung around a pivot point (8) connected on both sides with a stationary contact (4). 4. Arc extinguishing device for load switches according to claim 1 or 2, characterized in that the connecting parts (41,42) during the opening process can be displaced towards a final fixed point on a straight or curved axis connected via electrical connections with the second stationary contact (47). 5. Arc extinguishing device for load switch according to et of requirements 1-4, characterized in that the main connecting part (1) for displacing the insulating gas is connected to a piston (62) which dives into the reservoir (7) through the opening (61) in an almost tightly connected manner. 6. Arc extinguishing device for load switches according to one of claims 1-4, characterized in that a bellows (63) attached to the main connecting part (1) to which the reservoir (7) joins almost tightly lies in such a way that the reservoir (7) and the volume of the bellows (63) form a common volume, which by compression of the bellows (63) causes the displacement of insulating gas. 7. Arc extinguishing device for load switches according to claim 1, characterized in that a coil spring (45,14) or coiled flex spring is arranged at each end attached to each of the connecting parts (1,3,41,42). 8. Arc extinguishing device for load switches according to claim 1, 2 or 3, characterized in that the auxiliary coupling part (3) is designed as a bending spring (15) fixed in contact near the pivot point (8) on the main coupling part (1). 9. Arc extinguishing device for load switches according to claim 8, characterized in that the auxiliary coupling part (3) in the direction of rotation comprises flexible band-shaped layers of highly conductive material. 10. Arc extinguishing device for load switches according to claim 1 or 2, characterized in that the barrier is formed by a nozzle body (16) which surrounds the nozzle and consists of a metallic material and the auxiliary contact (17) belonging to the stationary contact. 11. Arc extinguishing device for load switches according to claim 10, characterized in that the nozzle body (16) has a ball or bulb-like shape and the contact springs of the auxiliary contact (17) a lyre-like shape. 12. Arc extinguishing device for load switches according to one of claims 1 or 2, 10 or 11, characterized in that the blocking is canceled by a carrier (9,36, 43) attached to the main connecting part (1,41,101) shortly before the minimum extinguishing distance for the main connecting part (1 ,41,101) is reached, by means of form-closing entrainment of the auxiliary coupling part (3,42,103). 13. Arc extinguishing device for load switches according to one or more of claims 1, 2, 5 or 6, characterized in that the reservoir (7, 42) is connected to the nozzle (6) over rounded, evenly decreasing cross-sections. 14. Arc extinguishing device for load switches according to one or more of claims 1, 2, 5 or 6, characterized in that the reservoir (7) is limited by thin-walled plate or insulating material walls in such a way that a sufficient cross-section is released in the opening direction ( 61) for the introduction of the insulating gas. 15. Arc extinguishing device for load switches according to one of claims 1-3 and 5-14, characterized in that the main connecting part (1) connects the pivot point (8) in a third position with an earthing contact (19). 16. Arc extinguishing device for load switches according to one of claims 1,2 and 5-11, characterized in that the main coupling part (101) can be pivoted by means of a shaft (49) of insulating material and connected on both sides with stationary contacts (11), both sides each having an auxiliary coupling part (103). 17. Arc extinguishing device for load switches according to one of the preceding requirements, characterized in that SF6 or a gas mixture containing high levels of SF6 is used as insulating gas.