BG67540B1 - Power switch with vacuum arc-damping chambers for step voltage regulator - Google Patents

Abstract

The power switch according to the present invention is a three-phase one, wherein the three phases (A, B, C) are isolated from each other and each phase occupies one sector of 120 degrees. There are two main vacuum arc-damping chambers (5, 6) connected in parallel and one auxiliary vacuum arc-damping chamber (8) interposed between them. The two main vacuum chambers (5, 6) are connected by an internal contact arc (33) with contact lamellas (35) which slide over it and connect it alternately to a left contact arc (30) and to a right contact arc (31). The contact lamellas (35) are established on a carrying element (38) mounted on a drive shaft (10). The movable contact (12) of each vacuum arc-damping chamber (5, 6) is connected to an L-shaped lever (13) which has a bearing (15). The two bearings (15) are actuated simultaneously by a symmetrical double-arm lever (20) mounted on a lever (18) with a bearing (19). During the switching cycle a cam (19) gripped to the shaft (10) acts on said bearing and the two main vacuum chambers (5, 6) open and close simultaneously. The auxiliary vacuum arc-damping chamber (8) is connected to a contact system composed of an inner contact arc (44), two outer arcs (41, 42) fixed on a sector (3) consisting of an insulating cylinder and contact lamellas (45) established on a carrying element (37) mounted on a tubular shaft (11). Under the auxiliary vacuum chamber (8) there is an opening and closing system same as the opening and closing system of each of the main vacuum chambers (5, 6). In the particular embodiment the shaft (10) turns to 120 degrees in one switching cycle and by means of a clutch idler turns the tubular shaft (11) to 40 degrees at the end of the switching cycle.

Description

(54) POWER SWITCH WITH VACUUM ARC EXTINGUISHING CHAMBERS FOR STEP VOLTAGE REGULATOR

Field of technique

The invention relates to a step-down regulator power switch that is incorporated into power transformers with on-load voltage regulation. The power switch is the most important node of the step regulator because it switches the operating currents without interrupting the power supply to the consumers. Current type circuit breakers have vacuum arc extinguishing chambers. Their parameters also regulate the parameters of the step regulator. Suitable vacuum arc extinguishing chambers are difficult to find for step regulators with large current ratings. This necessitates looking for more special constructive solutions.

Prior art

A step voltage regulator power switch [1] is known, containing three phases occupying a sector of 120° each and isolated from each other by radially arranged oil gaps. Each phase has one main vacuum arc extinguishing chamber connected to a main contact system and one, auxiliary vacuum arc extinguishing chamber connected to an auxiliary contact system and a resistor. The two vacuum arc extinguishing chambers and associated contact systems are actuated by a vertical shaft coupled to a spring energy accumulator. A cam is mounted on this shaft, which sequentially interacts with mechanisms to open and close the two vacuum arc extinguishing chambers.

A disadvantage of this power switch is that the main vacuum arc chamber is significantly more electrically stressed during switching than the auxiliary vacuum arc chamber. This limits the allowable current rating of the power switch. Another disadvantage is that the synchronization between the times of successive operation of the two vacuum arc extinguishing chambers is difficult, which requires a more special design of the spring energy accumulator.

Another step regulator power switch [2] is known, which also contains a main vacuum arc extinguishing chamber connected to a main contact system and an auxiliary vacuum arc extinguishing chamber connected to an auxiliary contact system and a resistor. In this case, a second tubular shaft is mounted coaxially to the drive shaft. The first shaft actuates the main contact system and the tubular shaft actuates the auxiliary contact system. The two shafts have separate cams that alternately drive the opening and closing mechanisms of the two vacuum arc quench chambers.

A disadvantage of this power switch is that, despite being more complex, it cannot provide a large rated current, which is regulated by the parameters of the main vacuum arc extinguishing chamber.

Technical essence of the invention

The task of the invention is to create a power switch with vacuum arc extinguishing chambers for a step voltage regulator, which provides twice the rated current and switching capacity compared to those of the used vacuum arc extinguishing chambers.

The task was solved by a power switch with vacuum arc extinguishing chambers, containing three phases located at 120° with isolation distances between them. Each phase is located in a metal sector cage as a bottom, cut from an insulating cylinder segment and an insulating sector and has main and auxiliary vacuum arc extinguishing chambers connected to the main and auxiliary contact systems. The two contact systems are actuated by a drive shaft and a tube shaft coaxially mounted thereon. A control cam is mounted on these two shafts, which turn the vacuum arc extinguishing chambers on and off.

According to the invention, each phase has two main vacuum arc extinguishing chambers connected in parallel, operating with a common main contact system and an auxiliary vacuum arc extinguishing chamber located between them. The supports of the two main vacuum arc extinguishing chambers have brackets on which a common contact arc is fixed, connected alternately to a left contact arc and a right contact arc by contact lamellas established on a support clamped to a drive shaft. Below the vacuum arc extinguishing chambers is mounted on a support an L-shaped lever connected on one arm to the moving contact of the vacuum arc extinguishing chamber, and on its other arm there is a bearing, the two bearings of the main vacuum arc extinguishing chambers are actuated simultaneously by thumbs of a symmetrical double-arm a lever that is supported on the neck of a lever, also supported on a supporting bottom. This lever has a bearing on its top, contacting periodically during shifting with a cam mounted on the drive shaft. The auxiliary vacuum arc extinguishing chamber is connected to a contact system composed of an internal contact arc, contact lamellae and left and right contact arcs. On a tubular shaft bearing coaxially on the drive shaft are fixed a carrier of the contact plates and a cam, which work with the auxiliary vacuum arc extinguishing chamber. The common drive lever of the two main vacuum chambers is supported by a spring so that the two thumbs are continuously in contact with the two bearings. The same effect is achieved by tension springs connected between the bearing necks and the thumbs. The transmission of the rotation of the drive shaft to the rotation of the tubular shaft is effected by a pin which moves in a circular groove made on the tubular shaft, so that when the driven shaft is rotated approximately 120°, the tubular shaft is rotated approximately 40° at the end of switching. The same thing happens when switching back.

The essential advantage of the invention is that when using available vacuum arc extinguishing chambers, a two-fold increase in the rated current and the switching capacity of the power switch is achieved while maintaining electrical wear resistance. Another advantage is that the construction is compact and does not increase the dimensions compared to the normal implementation.

Explanation of the attached figures

An exemplary embodiment of the power switch with vacuum arc extinguishing chambers for a stepped voltage regulator according to the invention is shown in the attached figures, of which:

Figure 1 is a circuit diagram and switching sequence of the power switch.

Figure 2 - cross-sections at three levels for the three isolated phases labeled in Figure 3 as A-A, B-B and C-C.

Figure 3 - longitudinal section through the middle of one of the phases (D-D).

Figure 4 - longitudinal section through one of the main vacuum arc extinguishing chambers (E-E).

Figure 5 - details of the mechanism for simultaneous actuation of the two main vacuum arc extinguishing chambers.

Examples of implementation of the invention

A single-phase electrical circuit, according to which the power switch with isolated phases is implemented, is shown in fig. 1. Characteristically, there are two main vacuum arc extinguishing chambers V1 and V2 connected in parallel with one auxiliary vacuum arc extinguishing chamber Vc with series connected resistor R. The vacuum chambers have a common terminal 0. The other terminal of V1 and V2 is connected to main a contact system composed of a movable contact Ki and two arcs a and b with an insulating gap x between them. The terminal after the resistance R is connected to an auxiliary contact system composed of a movable contact K2 and two arcs c and d with an insulating gap y between them. Arcs b and d ca connected to deflection I of the step Uc from the regulation winding of the transformer, and arcs a and c - to deflection II. The switching sequence according to Figure 1 is:

pos. (a) Initial position at which deviation I operates.

pos. b) After some rotation of the contact Ki, the chambers V1 and V2 are opened and the operating current is interrupted.

pos. c) The contact K1 is transferred without current from the arc b to the arc a and the chambers V1 and V2 are closed, during which a circulating current appears.

pos. d) The chamber Vc is turned off and the operating current is transferred to bias II.

Pos. e) Contact K2 is transferred without current from arc d to arc c and closes chamber Vc, with which the switching is completed.

The power switch provides large current ratings and switching capability because the two main vacuum arc extinguishing chambers operate in parallel and open simultaneously. The auxiliary camera is very

The power switch is composed of three mutually isolated phases A, B and C. Each of them occupies a sector of 120°. They are located in a known insulating cylinder 1 of an oil pan. The supporting body of each phase is composed of a metal bottom 2, a segment of an insulating cylinder 3 and a flat insulating sector 4. The two main vacuum arc extinguishing chambers 5 and 6 are attached to the sector 4 by metal supports 7. The auxiliary vacuum arc extinguishing chamber 8 is located between the two main chambers and is held by a carrier 9. A drive shaft 10 is mounted on the bottom 2, and a tubular shaft 11 is mounted coaxially on it. A known opening and closing mechanism consisting of an L-shaped lever 13 is connected to the movable contact 12 of the vacuum chambers. , attached to a carrier 14, a bearing 15, a guide 16 and a contact spring 17. The mechanism for simultaneous opening and closing of the two main vacuum arc extinguishing chambers 5 and 6 is new. It consists of a lever 18 bearing on the bottom 2 with a bearing 19 mounted on its upper end (Fig. 3 and Fig. 5). On the neck of the lever 18, a two-armed lever 20 with two thumbs 21 is mounted, connected to the bearings 15 of the two main chambers 5 and 6 by means of a compression spring 22. The lever 18 is fixed to the bottom 2 by a carrier 23. A cam 24 is mounted on the shaft 10, which interacts with the bearing 19 of the lever 18. On the tubular shaft 11 there is a cam 25, which interacts with the bearing 15 of the auxiliary vacuum chamber 8. The transmission of rotation from the shaft 10 to the tubular shaft 11 through a pin 26 which slides in a tangential groove. The current is transmitted from the terminals 12 to the bottom 2 through flexible connections 27, and from the bottom to the output contact 28 - through a plug contact 29.

The main contact system contains a left contact arc 30 and a right contact arc 31 attached to the pipe segment 3. Between the two arcs there is an insulating gap 32. At a smaller radius there is a contact arc 33, which is held by means of brackets 34 to the supports 7 of both main vacuum arc extinguishing chambers 5 and 6. The contact arc 33 is alternately connected to the contact arcs 30 and 31 through contact slats 35 with contact springs 36. The slats 35 are mounted to a carrier 37, fastened by an insulating carrier 38 to the shaft 10. To the respective contact arcs 30 and 31 the plug contacts 39 are caught which contact through contacts 40 on the insulating cylinder 1. The auxiliary contact system is composed of a left auxiliary contact arc 41 and a right auxiliary contact arc 42 attached to the pipe insulation segment 3 with an insulation gap 43 between them There is also a short internal contact arc 44 connected alternately to the arcs 41 and 42 by means of auxiliary contact lamellae 45, which are mounted on a carrier 46 secured by an insulating element 47 to the tubular shaft 11. The contact arc 44 is clamped to a column 48 mounted on the insulating sector 4.

Above the main contact system, an insulating sector 49 is mounted to the pipe segment 3, on which known resistors, not shown, are established. The three phases A, B, C are attached via the pipe segments 3 to a known flange, not shown, on which a spring energy accumulator is mounted. For more stable reinforcement, additional insulating sheets 50. Shaft 10 is driven by the spring-energy accumulator through an insulating shaft 51 connected to it with a half-cardan coupling 52. A buffer lever 53 is mounted to the lower end of shaft 10, which interacts with not shown stops located on bottom 2.

The switching sequence shown in figure 1 can also be illustrated by the construction given in the other figures. The spring-energy accumulator closes the shaft 10 by 120°. After about 40°, the cam 19 opens the two main vacuum arc extinguishing chambers 5 and 6. Thus, the contact lamellae 35 pass without current from the left contact arc 30 to the right 31. After a rotation of about 80°, the vacuum chambers 5 and 6 close and the pin 26 starts to rotate the tubular shaft 11, and the cam 25 opens the auxiliary vacuum arc extinguishing chamber 8 and the contact lamellae 45 pass without current from the arc 41 to the arc 42. At the end of the movement, the vacuum chamber 8 closes and the switching is completed. Reverse switching is done in the same way.

Claims (1)

A power switch with vacuum arc extinguishing chambers for a step voltage regulator containing three phases spaced at 120° with insulating distances between them, each phase housed in a metal sector cage on a bottom cut from an insulating cylinder segment and an insulating sector on which main and auxiliary vacuum arc extinguishing chambers are attached, connected to main and auxiliary contact systems actuated by a drive shaft and coaxially mounted tubular shaft with separate cams located thereon and commanding the opening and closing of the vacuum arc extinguishing chambers, characterized in that that there are two vacuum arc-extinguishing chambers (5 and 6) connected in parallel and one auxiliary vacuum arc-extinguishing chamber (8) located between them, and on the supports (7) of the symmetrically located two main vacuum arc-extinguishing chambers (5, 6) there are consoles ( 34), on which a common contact arc (33) is fixed, connected alternately with a left contact arc (30) and a right contact arc (31) by means of contact lamellae (35) established on a carrier (37) clamped to a drive shaft (10), and under the vacuum arc extinguishing chambers (5, 6, 8) is mounted on a carrier (14) an L-shaped lever (13) connected on one arm to the movable contact (12) of the vacuum arc extinguishing chamber, and on the other arm there is a bearing ( 15), the bearings (15) of the two main vacuum arc extinguishing chambers (5, 6) being actuated simultaneously by fingers (21) of a symmetrical two-armed lever (20) bearing on the neck of a lever (18) bearing to the bottom (2) and having on its upper part a bearing (19) contacting periodically during switching with a cam (24) mounted on a shaft (10) and similarly the auxiliary vacuum arc extinguishing chamber (8) is connected to a contact system composed of an internal contact arc (44) attached to an insulating sector (4) by means of a column (48), contact lamellas (45) carried by a carrier (46) caught on a tubular shaft (11) and contacting alternately with a left contact arc (41) and a right contact arc (42), and the bearing (25) connected to the auxiliary vacuum arc extinguishing chamber (8) contacts periodically during the switching with a cam (25) mounted on the tubular shaft (11)