BG112088A - 3-PHASE POWERED SWITCH WITH VACUUM RAILWAY CAMERAS - Google Patents

Abstract

The power switch has a round shield (1), an isolation cylinder (2) and isolation round carrier (3), to which via metal heads (8) are attached one odd-numbered main vacuum arching chamber (VAC 9), one even-numbered main VAC (10) and between them- one supplementary VAC (11). In the middle of the round shield (1) is mounded a drive shaft (4) with a buffer (5) and a command back (29). On the top end of the shaft (4) is located central pin wheel (30), clasped to satellite pin wheel (31), which has a leaver (32) with a roll (33). It counteracts in shifts with wheels (27) and contact plates (24), which connect to the immovable contact elements (23). On the drive shaft (4) is mounted movement element (36) with tooth (37), which in the end of the switching turns at a small angle the hinged above it head with drive shoulder (38), which carriers contact plates (39). They are connected with G-shaped plates (4), attached to the metal heads (8) of both of the main VAC (9 and 10). The movable contact element (12) of each of the VAC is activated on a specified program by the back (29) via a given leaver system. There is also an analog variant of the three-phase power switch with isolated phases.

Description

FIELD OF THE INVENTION

The invention relates to a three-phase power switch for a step voltage regulator, designed for regulation under load of power transformers. It uses vacuum arc quenching chambers that extinguish electric arcs without contaminating the transformer oil.

BACKGROUND OF THE INVENTION

A three-phase power switch for a step voltage regulator (1) is known, comprising a supporting structure of a round metal shield, an insulating cylinder and an insulating round support. The three phases occupy one sector of 120 °, and to the insulating support for each phase are mounted one:::.:: *:: ..

odd main vacuum arc quenching chamber (VDK), one even main VDK and between them - one auxiliary VDK. These three VDKs are attached to the insulating support by metal heads, and below them their movable contact is connected to a drive lever system in contact with a control cam, which is located on a drive shaft mounted in the middle of the metal shield. Next to each main VDK there is one fixed contact element attached to the insulating cylinder. The connection between the contact elements and the metal heads of the main VDK is made by disconnectors actuated by a disk mounted at the upper end of the drive shaft.

The two main VDCs are connected alternately by means of a switching contact system with a contact element located above the auxiliary VDC. The contact system is activated by a vertical insulating tube, commanded by elements located in a spring-energy accumulator mounted under the round metal shield. There are resistors above the contact system.

A disadvantage of the known three-phase power switch is that it has a complex construction, especially relating to the device of the switching contact system. It also complicates the spring-energy battery, which is not unified with the batteries used in other power switches.

Another disadvantage is that the disconnectors of the three phases are controlled by common elements. This makes it impossible to create a three-phase power switch with isolated phases, which has a similar design to that for regulation in a star center.

SUMMARY OF THE INVENTION

The object of the invention is to provide a power switch with VDK, comprising two main VDKs and one auxiliary VDK per phase, mounted to an insulating support attached to an insulating cylinder, which is located on a metal round shield. There are also disconnectors that alternately connect fixed terminal contact elements to the main VDCs via a command disk mounted to the upper end of the drive shaft mounted in the middle of the metal disk. A contact system alternately connects the main VDK with a contact element located above the auxiliary VDK.

According to the invention, the upper end of the drive shaft has a central gear engaged with a satellite gear having a roller lever. The roller is in alternate contact with forks bearing contact plates. The forks are mounted on supports mounted on the metal heads of the two main VDK.

The switching contact system consists of a drive element with a tooth mounted to the drive shaft. Above the drive element on the drive shaft is a hub mounted with a drive arm that carries contact plates. They are connected alternately with L-shaped plates attached to the metal heads of the two main VDCs.

The satellite gears for the three phases are located at 120 ° and are mounted on a supporting star attached to the insulating support of columns. The hub mounted on the drive shaft has three drive arms located at 120 ° each. A current-carrying pin with a wire is attached to the metal head of the auxiliary VDK, which is connected to one end of a resistor. There is a flexible connection or contact plate between the contact plates and a through pin attached to the insulating cylinder. A wire comes out of the bushing pin, which is connected to the other end of the resistor.

In the case of insulated phases, the functional elements are the same, but each phase has a supporting structure of a tubular insulating sector, an insulating sector and a supporting sector. A drive shaft is connected to both sectors, connected by an insulator to a satellite gear, engaged with a central gear. These gears are mounted on a common bearing metal shield.

The advantage of the three-phase power switch is that the construction is simple, especially with the switching contact system. Another advantage is that due to the use of a gear, all the elements of one phase are located in its sector and so a variant with three isolated phases can be realized. Another advantage is that both types of power switches are installed in oil tanks with the same diameter.

EXPLANATION OF THE ATTACHED FIGURES

An exemplary embodiment of the power switch with VDK according to the invention is shown in the attached figures, of which:

Figure 1 is a longitudinal section through the three-phase power switch with VDK.

Figure 2 - top view with partial cross-sections of the power switch.

Figure 3 - longitudinal section through the three-phase power switch with VDK with isolated phases.

Figure 4 - top view with partial cross-sections of the power switch of fig. 3.

EXAMPLES OF EMBODIMENT OF THE INVENTION

The supporting structure of the three-phase power switch with VDK consists of a metal round shield 1, an insulating cylinder 2 and an insulating carrier 3 (Fig. 1, Fig. 2). In the middle of the round shield 1 is mounted a drive shaft 4 with buffer 5. It is connected to a known undisplayed spring-energy accumulator by a lever 6 with a roller 7. To the carrier 3 by methane heads 8 are attached one main odd VDK 9, one main even VDK 10 and between them - one auxiliary VDK

C * 11. The movable contact element 12 of each VDK is connected to a drive mechanism consisting of a guide 13, an L-shaped lever 14 with a roller 15 and a contact spring 16. The contact element 12 is connected to the shield 1 by a flexible copper braid 17. D the lever-shaped lever 14 is mounted on a support 18 attached to the shield 1. On the outer diameter of the insulating cylinder 2, at the main VDK 9 and 10, an odd current-carrying contact element 19 and an even current-carrying contact element 20 are attached, provided with connecting terminals 21. elements 19 and 20 have additional L-shaped bodies 22 with a contact tip 23. They are alternately contacted by odd contact plates 24 with contact

C * springs 25 and even contact plates 26. The contact plates 24 and 26 are supported by forks 27 mounted on supports 28 which are mounted on the respective metal heads 8 of the two main VDCs 9 and 10.

On the lower part of the drive shaft 4 there is a cam 29, which is in contact with the rollers 15, and on the upper part - a central gear 30. It is engaged with one for a phase satellite gear 31 connected to a lever 32. At the end of the lever 32 has a roller 33 which interacts with the fork 27. The three satellite gears 31 are mounted on a support star 34 attached to the insulating support 3 by columns 35.

b. The switching contact system consists of a drive element 36 mounted on the drive shaft 4. It has a tooth 37 which interacts with a hub with a drive arm 3 on which contact plates 39 are arranged. They contact alternately with L-shaped plates 40 connected to Chapters 8 of the Main VDC 9 and 10.

An insulating disk 41 is mounted on the upper end of the insulating cylinder 2, on which certain resistors 42 are mounted. A conductor 44 leading to one end of f * is mounted to the head 8 of the auxiliary VDK 11; resistor 42. A flexible connection 45 protrudes from the contact plates 39, connected to the pass wire 46, attached to the insulating cylinder 2. A wire 47 is connected to the pin 46, which goes to the other end of the resistor 42. The star center is realized by the contact element 48, connected to the metal plate 1.

In FIG. 3 and FIG. 4 shows a power switch with isolated phases. The numbers of the elements with the same purpose are the same as in fig. 1 and FIG. 2, although there are small design differences. In this case, the three phases are spaced radially apart and an insulating distance is provided between them 49.

The three phase VDCs are mounted on an insulating sector 50, which is connected to a sector of an insulating cylinder 51. Below the VDC is another supporting sector 52, which may be made of metal or insulating material. A current-carrying unit 54 is attached to it by a support 53. Here, the drive arm carries contact plates 55, which connect arcs 56 mounted to the metal heads 8 with the terminal 46.

The three tubular sectors 51 are mounted on a common bearing metal shield 57, in the center of which is a bearing shaft 58 with a central gear 59. It is reinforced by a support 60. Gear 59 is engaged with three satellite gears 61 located on 120 °. Each of these gears 61 is connected to a drive shaft 62 by an insulator 63. Above each phase there is an insulating sector 64 to which certain resistors not shown are attached.

The operation of the power switch is as follows:

The drive shaft 4 rotates abruptly 90 ° from the drive lever 6 (Fig. 1, Fig. 2). Gear 30 rotates counterclockwise and rotates gear 31 clockwise. The roller 33 of the lever 32 inverts the fork 27 and the contact plates 26 are connected to the contact body 22. Then the cam 29 sequentially turns on the VDK 11, turns off the VDK 9 and turns on the VDK 10. contacts the arm 38 and switches the contact plates 39 from one arcuate plate 40 to the other. The operation of the power switch from fig. 3 and FIG. 4 is analogous.

Claims (5)

PATENT CLAIMS GO A three-phase power switch with vacuum arc-quenching chambers, comprising a metal shield support structure, an insulating cylinder and an insulating carrier to which two main vacuum arc-quenching chambers (VDCs) and one auxiliary VDC for each phase are attached by metal heads, in the center of each phase. shield is a bearing drive shaft with control rollers interacting with forks with contact plates connected alternately with contact bodies mounted to the insulating cylinder next to the main VDK, and above the auxiliary VDK there is a switching contact system consisting of movable contact plates connected alternately to the contact elements mounted on the metal heads of the main VDK, characterized in that the upper end of the drive shaft (4) has a central gear (30) engaged with a satellite gear (31) having a lever (32) with a roller (33) ), which alternately contacts the forks (27) with contact plates (24) attached to the main VDK (9 and 10) by supports (28), and the switching contact and the system consists of a drive element (36) with a tooth (37) mounted on the drive shaft (4) and a hub mounted above it with a drive arm (38) with contact plates (39) connected alternately with shaped plates (4), attached to the metal heads (8) of the two main VDCs (9 and 10). Three-phase power switch according to Claim 1, characterized in that the satellite gears (31) are arranged at 120 ° for the three phases and are mounted on a support star (34) attached to the insulating support (3) of columns. (35). ² .: 'Σ ς ··: · ^; '”· Three-phase power switch according to Claims 1 and 2, characterized in that the hub mounted on the drive shaft (4) has three drive arms (38) arranged at 120 ° for the three phases. Three-phase power switch according to claims 1, 2 and 3, characterized in that a current-carrying pin (43) with a wire (44) is connected to the metal head (8) of the auxiliary VDK (11), which is connected to one end of a resistor (42), and between the contact plates (39) and a through pin (46) attached to the insulating cylinder (2), there is a flexible connection (45) or one with contact plates (55), as from the through pin (46). ) a wire (47) connected to the other end of the resistor (42) comes out. Three-phase power switch according to claims 1 and 4, characterized in that in a variant with three isolated phases the functional elements are the same, but each phase has a supporting structure of a tubular insulation sector (51), an insulation sector (50) and a carrier sector (52), to both sectors (51, 52) is mounted a drive shaft (62) connected by an insulator (63) to a satellite gear (61) engaged with a central gear (59), such as these gears 59, 61) are mounted on a common supporting metal shield (57).