BG112775A - CONTACT SYSTEM OF THREE-PHASE POWER SWITCH WITH VACUUM EXTINGUISHING CHAMBER FOR STEP VOLTAGE REGULATORS - Google Patents

Abstract

The supporting structure of the three-phase power switch consists of an upper insulating disk (2) and a lower metal disk (3) connected by three studs (4) and reinforced with three insulating segments (5) of an insulating cylinder. Each phase occupies a sector of 120 degrees and has a main vacuum arc quenching chamber (V1) and an auxiliary vacuum arc quenching chamber (V2), each with an on / off device (16, 17, 18, 19, 20). In the middle there is a common switching shaft (7) with an insulating disk (9) and cams (10). A hollow shaft (8) with an insulating disk (11) and cams (12) is mounted on the switching shaft (7). A contact system consisting of an insulating disk (34), three supports (35) and main contact lamellas (36) is mounted on the top of the switching shaft (7). An auxiliary contact system consisting of an insulating disk (38), three supports (39) and auxiliary contact lamellas (40) is mounted on the upper end of the hollow shaft (8). The slats (36 and 40) are in contact with internal contact arcs (45 and 46) and an external arcuate body with a U-shaped cross section attached to the segment (5). On each stud (4) are mounted a left lever (13) and a right lever (14) with bearings at the end interacting with the cams (10 and 12). The levers (13, 14) have holes in the middle (16) into which the pins (20) enter. A lever (26) with two gears (27, 28) of different radius is mounted on one of the studs. These gears are engaged with a gear from the hollow shaft (8) and a gear freely mounted on it. The latter is actuated at the end of the switch by two pins (30) on a fork (29) connected to a shaft (7).

Description

FIELD OF THE INVENTION

The invention relates to a contact system for a three-phase power switch of a step voltage regulator with two vacuum phase arc quenching chambers. The power switches are built into the oil tank of the step regulator. They switch under load and regulate the voltage of the power transformers without interrupting the power supply.

BACKGROUND OF THE INVENTION

A contact system (1) of a three-phase power switch with vacuum arc quenching chambers (VDK) for step voltage regulators is known. The three phases occupy sectors of 120 ° in horizontal space. Each phase has one main VDK and one auxiliary VDK mounted next to each other on the insulation sector. On this sector and on the metal sector located below it, a switching shaft is mounted, connected to the main contact system for the main VDK and to the auxiliary contact system for the auxiliary VDK. These contact systems are located in the space of the insulation sector. The three phases of this power switch are isolated from each other by radially spaced oil gaps.

The disadvantage of this contact system is that the power switch has increased dimensions and weight. Another drawback is that you have to

1/9 switches the sum of rated and circulating current, which reduces its switching parameters.

Another contact system (2) of a power switch with a similar purpose is also known. It is also composed of three single-phase power switches with isolated phases. There is one main VDK and one auxiliary VDK, but here they switch separately between the rated current and the circulating current. This is achieved by coaxially mounting a hollow shaft on the switching shaft. The first shaft connects the main VDK to the main contact system, and the second shaft the auxiliary VDK to the auxiliary contact system. The synchronization of the action of the two shafts is done through an overload clutch and a freewheel clutch.

The disadvantage of this contact system is that it is also for a three-phase power switch with isolated phases, due to which the dimensions / dimensions and weight are increased. Another disadvantage is that it has a complicated construction and the special connectors have to be made and installed very precisely, because otherwise an accident could occur during operation.

Other three-phase power switches are known, consisting of single-phase contact systems arranged one below the other in a column. They work on similar principles, but are not suitable for the considered type of step regulators.

The problem is that the considered contact systems are for three-phase power switches with isolated phases and are not applicable for the realization of a compact power switch for regulation in a star center built on such a constructive concept.

Also known is (3) a three-phase power switch for regulation in a star center built on the basis of another design concept. It also has one main VDK and one auxiliary VDK in phase, which switch between the rated and circulating current separately. To achieve this, a special spring-energy battery and a duplicate system of command humps are used. There are also special switching units and parallel contact elements.

2/9

The disadvantage of this power switch is that it is very complex in construction and has large dimensions and weight.

SUMMARY OF THE INVENTION

The object of the invention is to provide a contact system for a three-phase power switch for regulation in a star center with small overall dimensions and weight. To have one main VDK and one auxiliary VDK per phase, which will switch separately the rated and circulating current. The construction should be simple and easy to install and control.

The problem is solved with a contact system for a three-phase power switch with VDK for step voltage regulator, containing one main BDK and one auxiliary VDK per phase, mounted by supports to an insulating plate. Each VDK has an opening and closing device located below it and mounted on a metal plate. A switching shaft is mounted between the insulation and the metal plates. A hollow shaft is coaxially mounted on it. The two shafts have separate cams for the main VDK and the auxiliary VDK. A main contact unit consisting of an outer contact arc, an inner contact arc and contact lamellas is mounted on the switching shaft. An auxiliary contact unit with a similar device is mounted on the hollow shaft.

According to the invention, the supporting structure of the power switch consists of an upper insulating disk, a lower metal disk connected by three studs and reinforced with three segments of an insulating cylinder. In the center of the two disks is a switching shaft with an insulating disk and three cams. A hollow shaft with an insulating disc and three cams is mounted on the switching shaft. To each stud are mounted a left lever and a right lever with bearings at their free ends and elongated holes in the middle. In these openings are located spherical pins from the devices for switching off and on the VDK. On one of the studs is mounted a lever with two gears, one of which is on a longer shoulder and is engaged with a gear part of the hollow shaft. The second ring is on a shorter shoulder and is engaged with free bearing of the hollow gear shaft. A hub with a fork is mounted on the switching shaft, which has two pins at both ends. These pins alternate

3/9 interact at the end of the shift with the free bearing of the hollow shaft gear.

The two phase VDCs are attached by brackets to the insulating disk and have opening and closing devices at the bottom. Each of these devices is composed of a stud connected to the movable contact of the VDK, which has a circular channel and a contact spring. The circular channel includes two rollers attached to one end of a L-shaped lever with a spherical pin at the other end. The lubricating lever is mounted on a bracket attached to the metal disk.

The switching shaft has a buffer and a flywheel at its lower end, and at its upper end an insulating disk with three supports for the three phases is mounted. Contact lamellas with contact springs are mounted on the supports. The slats connect an inner contact arc caught to the main VDK and an upper outer contact arc, part of an arcuate contact body. In a similar way, an insulating disk with three supports of auxiliary contact lamellas is mounted at the upper end of the hollow wall, which connect an inner contact arc and an outer lower auxiliary arc.

A left arcuate contact body and a right arcuate contact body with an insulating gap between them are mounted to the inner surface of the insulating segments. Each contact body has an upper main contact arc and a lower auxiliary contact arc formed on the U-section of the arcuate contact bodies. Plug contact assemblies are mounted on the outer ends of these bodies.

In order to reduce the resistance moment of the switching shaft caused by the increased angle of rotation of the hollow shaft, the auxiliary contact lamellas are with rollers and the contact solution of the auxiliary VDK is reduced.

An advantage of the contact system for a three-phase power switch of a step voltage regulator is that a simple and compact power switch for regulation in a star center is realized, which has a large switching capacity. Another advantage is that as a result of the use of the two gears the conditions for switching of the main VDK and the auxiliary VDK are standardized, as the transmission of

4/9 driving moments is optimal. Another advantage is that the installation and control of the power switch is easy and clear.

EXPLANATION OF THE ATTACHED FIGURES

An exemplary embodiment of the contact system of a three-phase power switch with vacuum arc quenching chambers for step voltage regulators according to the invention is shown in the attached figures by

Figure 1 is a longitudinal section through the contact system.

Figure 2 - top view with partial sections of the contact system.

Figure 3 - section under the supporting insulating disk of the contact system.

Figure 4 - unfolded longitudinal section for one phase through the mechanism for opening and closing of the vacuum arc quenching chambers.

DETAILED DESCRIPTION OF THE INVENTION, ® ^{as if Χ} · ^Υ · ^{Ζ of} power switch occupies a sector of 120 and has one main vacuum arc-extinguishing chamber Vi (ADC Vi) and one auxiliary vacuum arc-extinguishing chamber V ₂ (LAS v _2). Through brackets 1 they are attached to an insulating disk 2, which together with a lower metal disk 3 and three studs 4, is the supporting structure of the power switch. It is additionally reinforced with three segments 5 of an insulating cylinder. Through these segments, the contact system can, in a known manner, be mounted to an undisplayed spring-loaded energy storage carrier located in the support head of the step controller. The use of three segments is preferable instead of a whole insulating cylinder, as installation is facilitated and the contact system can be monitored.

Attached to the bottom 3 is a hub 6, inside which is mounted a switching shaft 7. Coaxially on this shaft is mounted a hollow shaft 8. To the shaft 7 is mounted an insulating disk 9 with three control cams 10 located at 0 from each other. A second insulating disk 11 with three is mounted on the hollow shaft 8

5/9 control cams 12. A left lever 13 and a right lever 14 are mounted to each stud 4. Each lever has a bearing 15 (or roller) at its end, which interacts with the respective control cam and has an elongated hole 16 in the middle.

Below each VDK there is a mechanism for switching off and on their contact elements, consisting of a stud 17 connected to the movable contact element of the VDK and an L-shaped lever 18 with two rollers 19 entering the channel of the stud 17 and a spherical pin 20 at the upper end, which enters the elongated hole 16 of the respective lever 13 or 14. The L-shaped lever 18 is mounted on a bracket 21 mounted on the metal flange 3. The stud 17 is supported by a contact spring 22. At the lower end of the shaft 7 is mounted a buffer 23 to which if necessary, a flywheel 24 can be attached. There are also three studs 25 attached to the metal disc 3. They serve as feet for checking the contact system and fix it to holes in the bottom of an unknown oil vessel not shown. On one of the studs 4, above the lever 13 is mounted a lever 26 barely toothed gums 27 and 28 at the end. The ring 27 is on a longer arm and is engaged with a ring gear on part of the hollow shaft 8. The ring 28 is on a shorter arm and is engaged with a ring gear free bearing of the hollow shaft 8. On the shift shaft 7 is the caught hub with a fork 29 with two pins 30 at both ends. The movable terminal 17 of the main VDK Vi has a cooler 31 and a flexible connection 32. The auxiliary VDK V2 also has a flexible connection 33.

An insulating disk 34 is mounted in the upper part of the switching shaft 7, to which a carrier 35 of the main contact lamellae 36 with contact springs 37 is attached. 40, which can be rolled to facilitate movement. On the inner surface of each of the insulating segments 5 are attached a left arcuate contact body 41 and a right arcuate contact body 42 formed in a U-shape. Each contact body has an upper main contact arc 43 and a lower auxiliary contact arc 44. An internal contact arc 45 is connected to the main VDK Vi. an arc 44 and an internal contact arc 46 attached to the insulating disk 2. Between it and the support 1 of the auxiliary VDK V2 is connected a known unsisted resistor. There are 43 between the contact arcs

6/9 insulating gap 47, and between the contact arches 44 - insulating gap 48. To the outer ends of the two contact bodies 41 and 42 are mounted plug contact units 49, which carry out the current connection with known not shown fixed contact elements from the oil vessel of the step regulator . A nozzle 50 is formed at the upper end of the switching shaft 7, to which the lower end of a known insulating shaft is coupled, the upper end of which is connected to a spring-energy accumulator.

The operation of the contact system is as follows: For one switch, shaft 7 rotates abruptly counterclockwise by 90 °. At about 25 °, the cam 10 opens the VDK Vi and closes it at about 65 °. Thus, the contact lamellae 36 pass current-free through the insulating gap 47. In the remaining 20 ° ъ 25 ° the VDK V ₂ must be switched in a similar way. The problem is that not enough time can be provided for normal switching in this range. Therefore, gear pairs 27 and 28 are provided. Depending on their gear ratios, rotation of the auxiliary contact lamellas 40 of the order of 40 ° can also be ensured, thus equalizing _{the operating conditions of VDK Vi and VDK V 2.} The slats 40 are set at 20 ° to the middle position, and at such an angle is the cam 12.

The cams 10 and 12 act in a certain sequence on the bearings 15 and the levers 13 and 14, respectively, and through the pins 20 located in the elongate openings 16 open and close the VDK. In the last 20 ° of the rotation of the shaft 7, the corresponding pin 30 of the fork 29 acts on the gear pair 28 and through the gear pair 27 the hollow shaft 8 is rotated 40 °.

Claims (5)

PATENT CLAIMS 1. Contact system of a three-phase power switch with vacuum arc quenching chambers for step voltage regulators, comprising a main vacuum arc quenching chamber (VDC) and an auxiliary vacuum arc quenching chamber (VDC) mounted by supports to an insulating plate with vacuum chambers attached to a metal plate, having a switching shaft with a cam acting on the devices and a hollow shaft mounted on the switching shaft, which also has a cam acting on the devices, and on the switching shaft is mounted a main contact unit consisting of an external contact arc, arc and contact lamellas, and on the hollow shaft is mounted an auxiliary contact unit with a similar device, characterized in that the supporting structure consists of an upper insulating disk (2) and a lower metal disk (3) connected by three studs (4) and reinforced with three segments (5) of an insulating cylinder, in the center there is a switching shaft (7) with an insulating disk (9) and cams (10), a hollow shaft (8) with an insulating disc (11) and cams (12) is mounted on it, to each stud (4) are mounted a left lever (13) and a right lever 14) with bearings (or rollers) (15) at the ends and elongated holes (16) in the middle in which a spherical pin (20) of the device for switching off and switching on the vacuum arc quenching chambers (Vi and V2) is located, on one of the studs (4) are a bearing lever (26) with two gears (27, 28), the ring (27) is on a longer arm and is engaged with a gear (27) of the hollow shaft (8), and the ring ( 28) is engaged with free bearing of the hollow shaft (8) gear (28), with this gear in the last stage of switching alternately interact two pins (30) of the fork (29) with a hub attached to the switch shaft (7) . Contact system according to claim 1, characterized in that the two VDCs (Vi, V2) are fastened by supports (1) to the insulating disk (2) and have an opening and closing device at the bottom, consisting of a stud (17) connected with the movable contact of the VDK, which has a circular groove and a contact spring (22), as in the circular groove enter two rollers (19) caught at one end of an L-shaped lever (18) with a spherical pin 8/9 (20) at the other end, and the L-shaped lever (18) is mounted to a bracket (21) attached to the metal disk (3). Contact system according to claims 1 and 2, characterized in that the switching shaft (7) has a buffer (23) at its lower end, with the possibility of adding a flywheel (24), and at its upper end is mounted insulating disc (34) with three supports (35) for the three phases (X, Y, Z), which carry main contact lamellas (36) with contact springs (37), the lamellas connecting an inner contact arc (45) and an upper outer contact an arc (43), part of an arcuate contact body (41), and in an analogous manner at the upper end of the hollow shaft (8) is mounted an insulating disk (38) with three supports (39) of auxiliary contact lamellas (40) which connect inner contact arc (46) and outer lower auxiliary contact arc (44). Contact system according to claims 1, 2 and 3, characterized in that it has a left arcuate contact body (41) and a right arcuate contact body (42) with a U-shaped cross section, which has an upper main contact arc (43) and a lower auxiliary contact arc (44), the two contact bodies (41, 42) being mounted on an insulating segment (5) with an insulating gap (47, 48) between them, and plug contact assemblies (49) being attached to their outer ends. . Contact system according to claims 1, 2, 3 and 4, characterized in that in order to reduce the resistance moment of the switching shaft (7) caused by the increased angle of rotation of the hollow shaft (8), the auxiliary contact lamellas (40) ) are rolled and the contact solution of the auxiliary VDK (V2) is reduced.