BG66470B1 - Single-phase power switch for step voltage regulator - Google Patents

Abstract

The power switch is operating with one main (1) and one auxiliary vacuum arc-extinguishing chamber (2), and a resistor (4) is connected in series to it. It comprises three phases (x, y, z), taking a sector of 120° each. The phases are insulated from each other. Each phase has two vertical insulation strips (13, 20) and among them, one above the other, following elements are fixed: a metal sector (24) bearing the mechanism (25) for operating the vacuum arc-extinguishing chambers (VAEC), insulation sector (23), where bearers (28) of VAEC (1, 2) are mounted, and a contact system. The contact system comprises two external arcs – a main arc (10, 11), with interruption (12), and an auxiliary arc (13, 14), with interruption (15), displaces along the angle. One short (10) and one long (13) arc have a common bearer (43) fixed to one of the strips (19). In the same way the other two arcs (11, 14) are fixed to the other strip (20). The contact system has also two internal arcs (6, 7), one connected to the main VAEC (1), and the other to the auxiliary VAEC (2) via a resistor (4). The internal and external arcs are interconnected via movable contact bridges (16, 17) rotated by a driving shaft (5).

Description

Field of technology

The invention relates to a three-phase power switch for a step regulator, designed to regulate under load the voltage of power transformers with windings connected in a star and in a triangle. It uses vacuum arc quenching chambers in order not to contaminate the insulating environment in which it is immersed.

BACKGROUND OF THE INVENTION

A three-phase power switch for step voltage regulator / 1 / is known, containing three single-phase contact systems, located in one plane and occupying sectors of 120 ° each, with an insulating space provided between them. Current-limiting resistors are mounted above the contact systems. Under the three contact systems is a common spring energy accumulator, which drives them through insulating shafts. The contact system is of the classic type with arc quenching in oil, which is contaminated by the products separated from the electric arcs.

The disadvantage of this three-phase power switch is that the current-limiting resistors are located above the contact systems, which increases the size of the power switch and the step controller when connected in a star, provided that it is unified with the triangle connection. Another disadvantage is that the arc quenching in oil contaminates it in the oil tank of the step regulator.

Technical essence of the invention

The object of the invention is to provide a three-phase power switch for a step voltage regulator, which is largely unified for connection in a triangle and a star, and in a star design has a significantly reduced height. The construction should have one main and one auxiliary vacuum damping chamber. To provide an insulating gap between the even and odd fixed contact element, as in the stationary position the vacuum arc-quenching chambers are closed and have a potential of the terminal.

The problem is solved with a three-phase power switch for step voltage regulator, containing three single-phase contact systems, located in one plane and occupying sectors of 120 °, with an insulating space between them. Current-limiting resistors are mounted above the contact systems, and a common spring energy accumulator is located below them. According to the invention, each of the three phases is fixed between two vertical insulating rails, to which a metal sector is mounted with a mechanism for actuating the movable contact elements of a main vacuum arc quenching chamber and an auxiliary vacuum arc quenching chamber. The two chambers are attached by supports to the insulation sector, located above the metal sector. Above the insulation sector there are two fixed external arches - main and auxiliary, which have interruptions offset at an angle. Two movable contact bridges connect the external arcs to the internal arcs, one of which is connected to the main vacuum arc quenching chamber and the other to a resistor of the auxiliary vacuum arc quenching chamber. The movable contact bridges are connected to an insulating bracket mounted on a drive shaft, to which a cam is attached to actuate the mechanism controlling the vacuum arc-quenching chambers. The insulating rails are attached to a common support base, to which are mounted a central gear connected to a spring energy accumulator and three satellite wheels connected to the respective drive shafts.

The main external arcs and the auxiliary external arcs have common supports attached to the two phase insulation rails. On the insulating cylinder of the oil tank of the step regulator there are terminal contact elements to which the common brackets are connected in the operating position of the power switch.

The insulation rails of one phase are connected to the insulation rails of the adjacent phases by the common supporting base and intermediate insulating elements. When connecting a power switch with isolated phases between actuators50

66470 The blinding gear and the drive shaft have an insulator and the resistors are mounted above an insulating sector located at a level above the contact system. When connected in a star center, the gear is mounted directly to the drive shaft, and the resistors are located in the space between the phases. A plug contact unit is mounted to the metal sector, connected to terminal contact elements passing through the insulating cylinder of the oil vessel.

The advantage of the power switch according to the invention is that it works with vacuum arc quenching chambers, which have a long service life and do not contaminate the oil. Another advantage is that the implementations for connection with isolated phases and connection in a stellar center are largely unified.

Explanation of the attached figures

An exemplary embodiment of the three-phase power switch for a step voltage regulator according to the invention is shown in the attached figures, of which:

Figure 1 is a circuit diagram on which the power switch operates;

Figure 2 is a longitudinal section of the power switch;

Figure 3 is a cross-sectional view of three levels of the power switch of Figure 3; 2.

Examples of the invention

The power switch has one main vacuum arc-quenching chamber (VDK) 1 (Fig. 1) and one auxiliary vacuum arc-quenching chamber 2 with common terminal 3. A current-limiting resistor 4 is connected in series with the auxiliary VDK 2. Concentrically on a common drive shaft 5 arc 6 connected to the main VDK 1 and above it an internal current-carrying arc 7 connected to the resistor 4. Two external interrupted current-carrying arcs are connected to terminals 8 and 9 of the power switch connected in series to a known undisplayed selector. consisting of a short arm 10 and a long arm 11 with an interruption 12. The auxiliary current arc with a long arm 13 and a short arm 14 with an interruption 15 is located above it. The connection between the main inner arc 6 and the outer main arc 10-11 is made by a movable contact bridge 16. In a similar way the connection between the auxiliary arcs 7 and 13-14 is realized by a movable contact bridge 17. 5 Terminals 8 and 9 on are in some way connected to a step winding 18.

The three phases (x, y, z) are located at 120 ° to each other and are isolated from each other (Fig. 2 and Fig. 3). Each phase is mounted between 10 two vertical insulating rails 19 and 20, which are attached below to a common supporting base 21. Under the base is a known spring energy battery 22. Between the two rails 19 and 20 are insulated sector 23, 15 supporting VDK1 and VDK2 and a metal sector 24, on which a mechanism 25 for actuating the movable contact elements 26 of VDK is mounted. Sectors 23 and 24 are attached to the insulating rails 19 and 20 by bolts 27, which ensures the stability of the supporting structure. VDK1 and VDK2 are mounted to the insulating sector 23 by current-carrying metal girders 28, which are pressed from above by an insulating arc 29 (Figs. The mechanism 25 consists of a two-arm angle lever 30 with a rolling bearing 31 mounted on one arm, and connected to the other arm by movable contact elements 26 of VDK1 and VDK2. The contact pressure of VDK is provided by contact springs 32. Under the metal sector 24 is mounted a plug contact shaft 33, which is in contact with a terminal contact element 34. The terminal contact elements 8,9 and 34 for each phase are attached to an insulating cylinder 35 of the oil vessel of the step regulator.

A cam 36 is mounted on the drive shaft 5, which is in series contact with the bearings 31. The discharge from the movable contact elements 26 of the VDK to the metal sector 24 is in a known manner by flexible metal braids 37.

To the common bearing base 21 are mounted a central gear 38 connected to the spring-energy accumulator 22 and satellite gears 39 of the three phases. For example, the rotation of the gear 38 by 90 ° is converted to 120 ° for the gear 39. The gear 39 is connected to the drive shaft 5 by an insulator 40. An insulating carrier 41 is attached to the upper end of the shaft 5, which rotates the contact levers 16. and 17. Contact pressure occurred

66470 Bl consists of contact springs 42. The arcs 10-13 or 11-14 have common supports 43, which are attached to the insulating rails 19 and 20 and when mounting the power switch in the oil tank 35 lie down and are pressed by bolts to the terminals 8 and 9. The inner arc 6 is connected to the bracket 28 of VDK 1. The inner arc 7 is attached in isolation to the rail 20 and is connected to one end of the resistor 4, while its other end is connected to VDK2.

In a power switch with isolated phases, the resistors 4 are mounted on an insulating sector 44, which is fixed between the insulating rails 19 and 20. If the power switch is for a star center, the gear 39 is connected directly to the metal drive shaft and the resistors 4 are located in the space between the rails 19 and 20 of the adjacent phases. In this way the height of the power switch, respectively - of the oil tank is significantly reduced.

The strengthening of the three phases relative to each other is done to the common supporting base 21 and by insulating elements 45. Improving the insulating strength between the phases can be done by installing barriers 46 to the rails 19 and 20.

The connection of the spring-energy accumulator 26 to the undisplayed bottom of the oil vessel 35 is made in a known manner by means of a coupling 47.

The operation of the power switch when switching is performed as follows. The spring-energy accumulator 22 accumulates energy when the plug 47 is rotated 180 °. After release, there is an abrupt rotation of the gear 38 or all three satellite gears 39. The drive shaft 5 actuates the contact bridges 16 and 17. The cam 36 acts on the bearing 31 of the VDK1 and opens it. Thus, the contact bridge 16 passes current-free through the interruption 12. Further, the cam 36 switches off the VDK2 and the contact bridge 17 passes current-free through the interruption 15. Thus, the transfer from the deviation 8 to the deviation 9 takes place in the same way.

Claims (5)

Patent claims 1. Three-phase power switch for step voltage regulator, comprising three single-phase contact systems located in one plane and occupying sectors of 120o with provided insulation distance between them and floor-mounted current-limiting resistors, a contact system and a common spring energy accumulator characterized by that each phase is fixed between two vertical insulating rails (19, 20), having a metal sector (24) with a mechanism (25) located thereon for actuating movable contact elements (26) of a main vacuum arc quenching chamber (1). ) and an auxiliary vacuum arc quenching chamber (2), which are caught by supports (28) to the insulating sector (23), and above the sector (23) there are two fixed external arcs - main (10-11) with interruption (12) and auxiliary (13-14) with interruption (15), also contact bridges main (16) and auxiliary (17) are connected by an internal arc (6) connected to the main vacuum arc quenching chamber (1) and an internal arc (7) connected to the resistor (4) of the auxiliary vacuum arc quenching chamber (2), the movable contact bridges (16, 17) being connected to an insulating support (41) mounted on a drive shaft (5) to which a cam is attached. (36) for actuating the mechanism (25). Three-phase power switch according to Claim 1, characterized in that the insulating rails (19, 20) are attached to a common support base (21) to which a central gear connected to the spring-loaded battery (27) and three auxiliary gears are mounted. gears (39) connected to the respective drive shafts (5). Three-phase power switch according to claims 1 and 2, characterized in that the main external arcs (10, 11) and the auxiliary external arcs (13, 14) have common supports (43) attached to the two insulating rails (19, 20). ), and the insulating cylinder (35) of the oil tank has terminal contact elements (8, 9), to which the brackets (43) are connected in the operating position of the power switch. Three-phase power switch according to Claims 1 to 3, characterized in that the insulating rails (19, 20) of one phase are connected to the insulating rails of the adjacent phases by a common supporting base (21) and intermediate insulating elements (45). . 66470 Bl -. ·>, • _l ^ bia.H <h, ibi.nn ^> ^ _l er> wwaMgiwa ^ n> eawi » S * W Three-phase power switch according to Claims 1 to 4, characterized in that when connected in isolated phases there is an insulator (40) between the gear (39) and the shaft (5) and the resistors (4) are mounted on an insulating sector 5. (44), attached to the insulating rails (19, 20), and when connected in a star center, the gear (39) is mounted directly to the shaft (5) and the resistors (4) are located in the space between the phases.