BG113455A - Three-phase power switch with vacuum arc-damping chambers - Google Patents

Abstract

The three-phase power switch has three phases, each occupying a sector of 120 degrees in a supporting structure composed of a round metal base (1) and an insulating disk (2), interconnected by three profiled insulating rails (3) located between the phases . Each phase has its own insulating segment (4), on which even and odd fixed contact elements (5 and 6) are mounted. The phase has two main vacuum arc extinguishing chambers (V1 and V2) and one auxiliary vacuum arc extinguishing chamber (Vc), mounted by means of metal supports (8) on the insulating disc (2). On a console (14) to each main vacuum arc extinguishing chamber (V1 and V2) is located a quick-acting disconnector containing a plug (10) with contact fingers (11). A three-spoke star (20) with rollers (21) on its ends, which interact with the forks (10), is mounted on the upper end of the drive shaft (15). The three-spoke star (20) is rotated against the direction of rotation of the shaft (15) by a lever-pulley mechanism containing an arm (26) bearing on a ring (24) secured by three columns (23) secured to the insulating disk (2) ). At the end of the arm (26) there is a roller (21) that enters a longitudinal channel (28) of one beam. The arm (26) has a perpendicular arm (29) which is connected by a rod (31) to a drive arm (32) mounted on the shaft (15). Under each vacuum arc extinguishing chamber there is a known mechanism to open and close it during switching. At the extended ends of the rails (3) an insulating disk (33) is caught, on which resistors (R) are mounted. A spring energy accumulator is attached to the metal bottom (1).

Description

THREE-PHASE POWER SWITCH WITH VACUUM ARC EXTINGUISHING CHAMBERS

FIELD OF ENGINEERING

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

PRIOR ART

A three-phase step voltage regulator power switch (1) is known, comprising a supporting structure of a circular metal shield, an insulating cylinder and an insulating circular support. The three phases occupy one sector of 120° each, and one odd main vacuum arc extinguishing chamber (VDC), one even main VDC and between them - one auxiliary VDC are mounted to the insulation carrier for each phase. These three VDCs are attached to the isolation carrier by metal heads, and below their movable contact is connected to a drive lever system contacting a command cam, which is located on a drive shaft bearing in the middle of the metal shield. Next to each main VDC there is one fixed contact element attached to the insulating cylinder. The connection between the contact elements and the metal heads of the main VDC is made by disconnectors actuated by a disc mounted on the upper end of a drive shaft. The two main VDCs are alternately connected through a switching contact system with a contact element located above the auxiliary VDC. The contact system is actuated by a vertical insulating tube, controlled by elements located in a spring energy accumulator mounted under the circular metal shield. There are resistors above the contact system.

A disadvantage of the known three-phase power switch is that it is of complex construction, especially concerning the device of

1/6 switching contact system. It also complicates the spring-energy accumulator, which is not unified with the accumulators 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 that has an analogous construction to that of a star center regulation.

Another three-phase power switch (2) with a simpler design is also known. With it, the three phases also occupy a sector of 120° each. The supporting structure consists of a round metal shield and an insulating round support connected by an insulating cylinder. One odd VDC and one even VDC per phase are attached to the insulation carrier by means of metal heads, and an auxiliary VDC is located between them. An actuator connected to the movable contact element of the VDC is mounted under each VDC to the metal shield. It is actuated by a cam mounted on a centrally located drive shaft. An odd fixed contact element is clamped to the insulating cylinder next to each of the odd main VDCs. Accordingly, next to each even VDC there is an even fixed contact element. A quick-acting disconnector is mounted to the metal carrier of each main VDC, which is successively switched on and off to the corresponding stationary contact element by means of a roller attached to the end of a drive lever. On the inner end of this lever is a satellite gear bearing on a support structure and meshing with a center gear mounted on the upper end of the drive shaft. This design provides reverse rotation of the disconnector actuating lever relative to the rotation of the drive shaft. Thus, all contact and drive systems of each phase are located in its sector.

A disadvantage of this power switch is that, due to the presence of an entire supporting insulating cylinder, the installation and adjustments of the contact systems are difficult. It is also difficult to dismantle in case of revision and repair.

Another disadvantage is that very precise fabrication and adjustment of the gears is required in order to achieve synchronized opening and closing of the snap-action disconnectors. It will be necessary to use special steels to provide some mechanical wear on the gears, as increasing the clearances can upset the action of the quick-acting disconnectors.

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TECHNICAL ESSENCE OF THE INVENTION

The task of the invention is to create a three-phase power switch with vacuum arc extinguishing chambers, which provides easier installation, adjustments and dismantling. Another task is to create a new mechanism for reversing the movement of the lever actuating the quick-acting disconnectors, which provides more reliable action and increased driving torque at the beginning and at the end of the movement.

The task was solved with a three-phase power switch with vacuum arc extinguishing chambers, containing three phases occupying sectors of 120° and located in an insulating cylinder with a round metal bottom and an insulating round carrier. Each phase has two main vacuum arc extinguishing chambers (VDC) and one auxiliary VDC located between them. The three VDCs are attached to metal supports clamped to the insulation support. Fast-acting disconnectors are mounted on the metal supports of the main VDC, and next to each of them there is a fixed contact element attached to the insulating cylinder. A vertical drive shaft is located in the middle of the power switch, to the upper end of which is mounted a mechanism for actuating the quick-acting disconnectors.

According to the invention, the supporting structure is composed of a round metal bottom and an insulating disc connected by three profile-shaped insulating rails located between the phases. Each phase has a separate insulation segment that carries the odd and even fixed contact elements.

The mechanism for reversing the direction of rotation is composed of a three-spoke star bearing on the upper end of the drive shaft, on one of the spokes of which a longitudinal channel is made. It includes a roller located at one end of an arm bearing at the other end of a horizontal ring attached to the insulating disk by means of three columns. The arm has a second perpendicular arm connected by a rod to an arm fixedly mounted to the drive shaft.

At the end of each beam of the three-pointed star, a bearing is mounted, which interacts with the forks carrying the contact fingers of the quick-acting disconnectors. The forks are mounted on brackets connected to the metal supports of the vacuum arc extinguishing chambers.

The profiled insulating rails have an elongated upper end to which an insulating disc carrying the resistors is attached.

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All pivots of the mechanism for reversing the rotation are built on the basis of rolling bearings.

A flywheel can be installed on the drive shaft above the cam if necessary.

An advantage of the three-phase power switch according to the invention is that the installation and adjustments of the mechanisms of one phase can be done with the insulating segment removed. This provides great accessibility and visual control. After that, the segment is installed and sequentially proceed to the installation of the remaining phases. The same advantage is available for disassembly and repair. Another advantage is that the rotation reversal mechanism is reliable and long-lasting. It is easy to adjust and provides the necessary precision of action without requiring special manufacturing accuracy. It also has the advantage of providing greater driving torques at the beginning and end of switching when there are resisting torques from the fast-acting disconnectors.

EXPLANATIONS OF THE ATTACHED FIGURES

An exemplary implementation of the three-phase power switch with vacuum arc extinguishing chambers (VDC), according to the invention, is shown in the attached figures, of which:

Figure 1 is a longitudinal section through the power switch.

Figure 2 - longitudinal section through the actuation mechanism of the quick-acting disconnectors on an enlarged scale.

Figure 3 — top view of one of the phases with resistors removed, the other phases not shown being the same.

Figure 4 - the one shown in fig. 3 but switched to the other end position.

Figure 5 - dependence of the driving torque acting on the quick-acting disconnectors on the angle of rotation of the drive shaft.

EXAMPLES OF IMPLEMENTATION OF THE INVENTION

The supporting structure of the power switch is composed of a circular metal base 1 and a circular insulating disc 2 connected together

4/6 with three profile-shaped insulating rails 3 located between the three FDS occupying one sector of 120° each. Each phase has an insulating sector 4 clamped to the metal bottom 1 and an insulating disk 2 between the insulating rails 3. At the ends of the insulating sector 4, an odd fixed contact element 5 and an even fixed contact element 6 are mounted. An odd metal carrier is clamped on the insulating disk 2 from above 7 with odd VDC Vi, even metal carrier 8 with even main VDC V2 and between them - carrier 9 with auxiliary VDC V _c . A quick-acting disconnector consisting of a fork 10 carrying contact fingers 11 with contact springs 12 is mounted on a carrier 8. The fork 10 is mounted on an axis 13 attached to a carrier 14 clamped to a carrier 8.

In the middle of the metal bottom 1 is mounted a vertical drive shaft 15 with a command cam 16, a buffer 17 and a blocking double arm lever 18 with a bearing 19, which is driven by a known spring energy accumulator, not shown.

On the upper end of the shaft 15 is mounted a three-spoke star 20 with a roller or bearing 21 at the end of each spoke. The rollers 21 functionally interact with the channels of the forks 10, whereby the contact fingers 11 are connected to contact bodies 22 connected to the upper end of the fixed contact elements 5 and 6.

The three-spoke star 20 is rotated by the drive shaft 15 by a lever-and-slide mechanism with the following device (shown in Fig. 2 in the middle position). A horizontal ring 24 is mounted on three columns 23 attached to the insulating disk 2, to which a shaft 25 with an arm 26 is mounted in the middle of one of the phases. At the end of the arm 26 there is an axis 27 with rollers that enter a radial channel 28 on one star beam 20. The arm 26 has a perpendicular arm 29, at the end of which a rod 31 is mounted on an axis 30. This rod 31 is connected at its other end to an arm 32 immovably mounted on a shaft 15.

An insulating disc 33 is connected to the extended upper end of the insulating rails 3, which carries known resistors R. A known free-wheel disconnector 34 is mounted on the shaft 15, which activates a known contact system mounted above the carrier 9 of the auxiliary VDC Vc. It is not shown in the figures in order not to complicate them.

A known system is installed under each VDC that opens or closes a specific VDC during switching. It is composed of a carrier 35 attached to the metal bottom 1, on which an L-shaped lever 36 is mounted. A bearing 37 is located at the vertical end of the lever 36, which

5/6 interacts with the command cam 16. The horizontal arm of the lever 36 is connected to the movable contact 38 of the corresponding VDC. The contact pressure is provided by a contact spring 39. If necessary, a flywheel 40 can be installed on the drive shaft 15 above the cam 16.

The operation of the power switch according to the invention is as follows. The known spring-energy accumulator, by means of a lever 18 and a bearing 19, rotates the drive shaft 15 in one direction by a certain angle during one shift and in the opposite direction during the next shift. In this particular case, the rotation angle is 90°. The command cam 16 acts on the bearings 37 and implements a certain sequence of opening and closing of specific VDCs.

When the shaft 15 is rotated, the arm 29 is rotated by means of the arm 32 and the rod 31, with which the arm 26 is also rotated. The roller axis 27 mounted on its end acts on the channel 28 of one beam of the three-pointed star 20, and the one mounted on the end of the beam roller 21 closes via fork 10 the contact system 11 -22 already at the beginning of switching (fig. 3 and fig. 4). At the end of the switching, the contact system 11-22 connected to the other VDKU opens

During reverse switching, the contact system connected to VDC Vi is closed and the contact system connected to VDC Va is opened. The action of the contact systems of the other two phases, not shown in the figures, is analogous, since their construction is the same.

From the indicated sequence, it can be seen that the moments of resistance from the action of the quick-acting disconnectors are only at the beginning and at the end of the switching.

In fig. 5 shows the power characteristic showing the dependence of the driving moment Md on the angle of rotation a of the shaft 15. It is characteristic of the sliding mechanisms and provides suitable moments for the specific case.

From fig. 2, it can be seen that all the hinged connections of the rocker arm mechanism are based on rolling bearings. This ensures reliable and long-lasting operation. The supporting structure of the power switch allows, after removing one of the insulating segments connected to one of the phases, its stability does not change. In this way, the assembly, setting and disassembly of this phase is greatly facilitated.

Claims (5)

1. A three-phase power switch with vacuum arc extinguishing chambers, containing three identical phases each occupying a sector of 120° in a supporting structure consisting of a circular metal base, a circular insulating disc and an insulating cylinder, each phase having one odd main vacuum arc extinguishing chamber, one even main vacuum arc-extinguishing chamber and auxiliary vacuum arc-extinguishing chamber fastened by metal supports to the insulating disk, on the metal supports of the main vacuum arc-extinguishing chambers, quick-acting disconnectors are established interacting with fixed contact elements mounted on the insulating cylinder, in the middle of the metal bottom is a vertical actuator bearing shaft, which in its upper part is connected to a mechanism reversing the direction of rotation of the elements controlling the quick-acting disconnectors, characterized by the fact that the supporting structure is composed of a round metal bottom (1) and an insulating disk (2) connected by three profiled insulating rails (3) located between the phases and each phase has a separate insulating segment (4) which carries an odd fixed contact element (5) and an even fixed contact element (6), and the mechanism for reversing the direction of rotation is composed of a bearing on the upper end on the drive shaft (15) a three-beam star (20), on one beam a longitudinal channel (28) is made, into which a roller (27) located at one end of an arm (26) bearing at the other end (25) of a horizontal ring enters (24) clamped to the insulating disk (2) by three columns (23), and the arm (26) has a second perpendicular arm (29) connected by a rod (31) to an arm (32) fixedly mounted to the drive shaft (15). 2. Three-phase power switch according to claim 1, characterized in that at the end of each beam of the three-ray star (20) there is a mounted bearing (21) which interacts with the forks (10) carrying the contact fingers (11) of the quick-acting disconnectors, and the forks (10) are mounted (13) on brackets (14) connected to the metal supports (7, 8) of the main vacuum arc extinguishing chambers (Vi and V2). 3. A three-phase power switch according to claims 1 and 2, characterized in that the profiled insulating rails (3) have an elongated upper end to which the insulating disc (33) carrying the resistors (R) is attached. 1/2 4. A three-phase power switch according to claims 1, 2 and 3, characterized in that all the pivot connections of the mechanism for reversing the rotation are built on the basis of rolling bearings. 5. A three-phase power switch according to claims 1, 2, 3 and 4, characterized in that a flywheel (40) may be mounted on the drive shaft (15), above the cam (16).