NO861465L - SWITCH SWITCH AND SWITCHING SYSTEM WITH SUCH SWITCH SWITCH - Google Patents

Description

The present invention relates to a switch-disconnector of it

type as specified in the introduction to claim 1 as well as a switch system of the type specified in the introduction to claim 5, and in which such a load disconnect switch is built-in.

Load-disconnectors have the task on the one hand of interrupting the nominal current and on the other hand of thereby providing a separation line in accordance with the regulations. Therefore, an arc is drawn in switch-disconnectors during the disconnection process, which must be extinguished with the help of an extinguishing medium.

For this purpose, the movable contact pieces of the load disconnect switch can be connected to a piston cylinder device, which compresses gas<p>g thereby producing a gas flow towards the arc which in this way blows towards the arc.

In addition, it is necessary for switchgear systems in which such load-disconnectors are used to arrange an earthing device. Thereby, it must be ensured by means of a special locking device that the earthing cannot be carried out when the switch-disconnector is switched on or that a switch-disconnector cannot be switched on in the "grounded" state.

For this purpose, a number of mechanical or electronic locking devices are known. With all these devices, the complexity of the mechanical locking and the electronic locking relatively large.

The task of the invention is thus to provide a switch-disconnector of the type mentioned at the outset as well as a switch system with a switch-disconnector where further locking elements are avoided and where the extinguishing of the arc can be influenced in a favorable way.

According to the invention, this task is solved by a disconnect switch of the type mentioned at the outset whose characteristic features appear in claim 1 and by means of a plant of the type mentioned at the outset whose characteristic features appear in claim 5.

Due to the design of the load separator or the load disconnect switch according to the invention, the individual switches have a total of two or respectively three functions: it can be used to disconnect a load, to provide a separation line and thirdly to provide an earthing. The switch disconnector is disengaged, whereby it becomes freely rotatable and by turning the greenhouse together with the switch disconnector, this is prepared for earthing and by influencing the drive in the direction of connection, the earthing is produced. A locking device, which in a special way should prevent "earth" from being switched on when the switch is switched on, is only avoided by the switch itself being used to provide the earthing.

This can be carried out, can be traced back to the fact that in the disconnected state the switch-disconnector is free from the fixed contact pieces. This also means again that the connection line is not encapsulated. When such a load-disconnector is built into a switchgear housing that is closed gas-tight and filled with an insulating gas, e.g. SF^ gas, which is the case with switchgear according to the present invention with this built-in load disconnect switch, it is possible that the connection section, i.e. the section which draws the arc, is located practically freely within the switchgear housing, as the insulating medium is located inside the housing , e.g. SF^ gas, at the same time, was also used as extinguishing gas for the load disconnect switch.

When the individual poles of a switch-disconnector at this switchgear are arranged in series or in a plane and when a total of two such switch-disconnectors are placed inside the switchgear, then both earthing contacts can conveniently be placed in the middle between both rows, whereby both switch-disconnectors must be arranged mirror-symmetrically in relation to each other. It will then be possible without problem to lead this double grounding contact isolated out of the switchgear housing and also lead the test DC voltage in. Depending on which switch is connected to the earthing contacts, the relevant switch pole rows may be subjected to the test voltage.

Further features of the invention appear from the subclaims.

The invention will now be described in more detail with the help of some embodiment examples of the invention and with reference to the drawings, where: Fig. 1 schematically shows the circuit of a medium voltage substation field.

Fig. 2 shows a load disconnect switch according to the invention seen

in cross-section, where the station field according to fig. 1

is applied.

Fig. 3 shows a substation field with a built-in load disconnect switch and outputs according to a first embodiment. Fig. 4 shows a similar field to that shown in fig. 2 with

different arrangements of earthing contacts.

A medium-voltage station field is connected in a so-called cable ring, which is connected via a fuse 11 and a load disconnect switch 12 to a transformer 10, cf. fig. 1. The fuse 11 is located in an isolation room 13, which is enclosed by a solid insulation 14. The switch disconnector 12 is located together with two further switch disconnectors

15 and 16 in a gas-tight closed housing 17, in which inner space 18 is located e.g. SF gas. The cable strings A, B and C are part of the cable ring, which is connected to the transformer via the cable string D, as the entry point in the cable ring is placed between both fixed contact pieces 19 and 20

to the load disconnectors 15 and 16. In the area of the load disconnectors 15 and 16 are contact pieces 21 and 22 which are respectively connected to earth 23. The load disconnector 12 also has two fixed contact pieces, of which the contact piece 24

in the connected state, the nominal current and contact

piece 25 corresponds to contact pieces 21 and 22 and is again connected to ground 23.

Fig. 2 shows a detailed construction of a switch-disconnector or the switch-disconnector 15. The switch-disconnector 15 has a housing 30 made of insulating material, which has a continuous opening 31, in which the movable contact piece 32 of the switch-disconnector 15 is led. At the contact piece 32 there is a piston element 33, which fits exactly into the opening 31. The movable the contact piece is connected with the crank 35 to a drive device, of which only the drive shaft 36 is shown, and then via a piston rod 34. The drive device is located in a drive storage. 37 (house 37) which is fixed

connected to the insulating housing 30 via a traverse 38. Via the connection flange 39 and the sliding contact 40, the current is led to the movable contact 32. The significance for the invention is not the further internal parts, but only the fixed and rigid connection of the insulating housing 30 with the housing 37 for operation and correspondingly assigned guidance of the movable contact piece 32 within the housing 30. The free end of the crankshaft 35 has a transverse pin 41, which is movable in an elongated hole 42 at the piston rod 34. The elongated hole 42 then equalizes the circular movement of the pin 41 by in- or the disengagement. When the drive device is affected, the drive shaft 36 becomes

and thus the crank 3 5 in accordance with the double arrow direction P, depending on the direction of rotation the load disconnect switch is switched on or disengaged.

The movable contact piece 32 cooperates with a fastening contact piece 43, which fastening contact piece in fig. 1 is denoted by the reference number 19. The fastening contact piece 43 is attached to a busbar 44, which corresponds to the wire or the wire string B in fig. 1.

When the switch-disconnector is disconnected from the connected state, i.e. the movable contact piece 32 is in connection with the fixed contact piece 43, the gas is compressed via a supply line not shown in detail by means of the piston 33 in cooperation with a cylinder base 45 to the arc 4 6 which burns between both contact pieces.

As can be seen from fig. 3, the separation point is free in the inner space 18 of the housing 17, so that the gas, e.g. SF^ gas,

which is located in the inner space 18 does not serve only to insulate the busbar or the parts that are in high voltage or in medium voltage, but also for blowing the arc 46 and thus extinguishing it.

At an angle from approx. 30° in relation to the connection line L-L between the fixed and movable contact piece, i.e. the center line of the piston rod 34, there is an earthing contact piece 47. The earth is denoted by the reference number 23. When the switch disconnector 15 is now to be turned into the earthing position, the greenhouse 37 and the insulating housing connected to the greenhouse 37 via the traverse 38 pivoted with the part 40 and the movable contact piece 32, and then so far that the center axis L£-L£ of the earthing contact piece 47 aligns with the center axis L-L of the load disconnect switch, and it has been reached in fig. 2 dotted line registered position 15„. Now the movable contact piece 32 can be brought into connection with the earthing contact piece 47. The dashed position 15„ is the position "earthing prepared" and by simple connection, i.e. influence of the drive device, the load disconnector can be brought into the earthing position. It thus appears here that the load switch carries out the grounding itself, so that special grounding switches and thus locking devices to prevent an impermissible grounding are thus avoided. In order to be able to connect the load disconnect switch again, the housing 37 is simply turned back into the position shown by the solid line and the movable contact piece 32 can be brought back into the connection position by turning the drive shaft 36.

In fig. 3 shows a substation field partially in section, which corresponds to fig. 1 is built into the switch according to fig. 2.

The room 13 in the house 14 is shown with the HH fuses 51, 52 and 53 connected in front of the transformer. Via the bushings 54, 55 and

56, these HH fuses 51 to 53 are introduced into the interior 18 of the housing 17, as the most common commercial cable feed-through or cable end termination can be used here. Lace conductors 57, 58 and 59, which are connected to a connecting angle 60, join the bushings 54 to 56. In fig. 3, only one connection angle 60 is indicated. Both rear switches belonging to the lines 58 and 59, which belong to a three-phase system, are not shown. The switch-disconnector 12 corresponds to the switch-disconnector 15, whose effectiveness is explained with reference to fig. 2. The cable ring is then formed by means of the three-phase supply line A, which is led via the cable entries 61, 62 and 63 into the interior of the housing 17 and connected to the load separator 16 via slip lines 64, 65 and 66. It is only indicated one of the three switch-disconnector poles, both of the others being arranged in the rear plane. Above the busbar 44, which corresponds to the line or the line B and the one which with the line B to the switch 12 forms a unit and a single busbar, the switch 16 is connected via contact pieces 19 to the switch 15, whose individual switch poles are connected via the strips 67, 68 and 69 to the cable glands 70, 71 and 72, which is again led through to the wiring C. The grounding contacts 21 and 22 as well as 25 are arranged to the left of the switch poles and then like the grounding contact 46 in fig. 2, so that reference must be made to this in this context. All three on-load switch poles have respective uniform and for all three common housings,

which corresponds to the greenhouse 37. By turning this greenhouse, all three switch poles can be brought into operation or grounding positions.

In fig. 4 shows a variant. The switches 15 and 16, which are located next to each other within the cable ring, are arranged in a mirror-image manner in relation to each other, so that the cranks are not arranged in parallel in relation to each other, as shown in fig. 3, but mirror-symmetrical so that they form in the one in fig. 4, the position showed an acute angle between them. The greenhouse and the switch are quasi-mirror-symmetrically rotated by 180°. This means that an earthing connection 80 can be inserted in the space between the switches 15 and 16, to which earth connection contacts 81 and 82 are connected via a holder 83. The holder 83 for each individual switch pole can be isolated and led out from the housing 17 via the wire 84, 85 respectively. 86 and the feed-throughs 87, 88 and 89. One then has two possibilities: via a connecting grounding rail 90, all three conductors 84, 85 and 86 and thus the grounding contacts 81 and 82 can be grounded for the three switch poles respectively. the possibility consists in removing the connection rail 90 and passing a test voltage separated into the interior of the housing via the individual bushings 87, 88 and 89 for respective poles and for each switch 15 respectively. 16. With this construction, the switch 12 is arranged in the same direction within the housing 17 as the switch 16, so that both cranks of both switches 12 and 16 are directed parallel and only the crank 35 of the middle switch is in the other direction. In this case, the earthing device,

as in the embodiment according to fig. 3 is placed between the switches 12 and 15, be connected to the housing 17. This earthing circuit has the reference number 91.

Claims (8)

Switch-disconnector with a fixed contact piece and a movable contact piece actuated by a drive device and surrounded by a housing of insulating material, and with an earthing contact, which is arranged offset in relation to the fixed contact piece, characterized in that the insulation housing (30), which serves to guide the movable contact piece (32), which is designed as a shock contact piece, is permanently connected to the housing (37) for receiving the drive device which operates the switch disconnector, and that to provide the earth position, the greenhouse with the drive device and the insulation housing is rotatable together. 2. Switch-disconnector according to claim 1, characterized in that the insulating housing is tubular and has two transverse walls (45, 39) for guiding the movable contact piece (32). 3. Switch-disconnector according to claim 1 or 2, characterized in that the drive device is a mechanical spring-drive device, whose spring energy after the release of the locking suddenly brings the contact piece to the starting position. 4. Load disconnect switch according to claim 3, characterized by. that round contact pieces are arranged as switch contacts, which are provided with an arc-resistant contact material. 5 . Switch system with at least one three-pole load disconnect switch device formed by three load disconnectors according to one of the preceding claims, characterized in that the housing (17) of the switch system is designed to be gas-tight and filled with an insulating gas, preferably SF^ gas. 6. Switch system according to claim 5, characterized in that to form the three-pole switch-disconnector, the individual switch-disconnectors (12, 15, 16) are arranged in a row for each pole and that in the case of two adjacent rows, the earthing contact is located between them for both rows and becomes there held by a holder (83) of electrically conductive material which connects the rows to each other. 7 . Switch system according to claim 6, characterized in that connecting cables (84, 85, 86) are connected to the holder, which are led via bushings from the housing (17) isolated from the housing (17) and over which it can be supplied to the individual switch poles a test DC voltage. 8. Switch system according to claims 5-7, characterized in that the switch section of the load disconnect switch (12, 15, 16) is arranged freely in the housing (17) of the switch system and is not surrounded by the housing by the insulating material, so that the insulating gas enclosed in the housing (17) of the switch system simultaneously serves as an extinguishing gas for an arc that occurs when the load disconnect switch (12, 15, 16) is switched on under load.