BG112741A - Single-phase power switch with vacuumarc-suppression chambers for on-load tap-changer column - Google Patents

Abstract

The single-phase power switch has two main vacuum arc-suppression chambers (V1 and V2) and one supplementary vacuumarc-suppression chamber (VC) attached to the half of an insulatingdisk (2). Below it, there is a metal disc (1) connected to theinsulation disc via insulating studs (3). In the middle there is acommutator shaft (7), which is supported via bearings on both disks.Below this shaft is mounted a cam (8) , which controls the systemfor synchronous opening and closing of the three vacuum arc-suppression chambers (VAC). A switch lever (27) with a roller (26)is mounted at the upper end of the commutator shaft (7), whichswitches main contact systems mounted on carriers (6) of the mainVAC. Through them, an even fixed contact element (35) and an oddcontact element (37) are switched on and off. The single-phasepower switches for the three phases are secured by two segments (4and 5) of insulation pipe, thus creating a stable fixed column.Around the column, at each single-phase power switch there is aneven current-carrying ring (31) connected to the contact (35), an oddcurrent-carrying ring (32) connected to the contact (37), and anoutput contact ring connected to the metal disk (1) A resistor (40) is located in the space opposite the VAC. On the commutator shaft (7)there is a sleeve via bearing (45) with an arm (48) which switches asupplementary contact system to ensure the connection of the VACto the resistor.

Description

FIELD OF THE INVENTION

The invention relates to a single-phase power switch with vacuum arc quenching chambers. Three such power switches for the three phases are installed on the floor in step voltage regulators of column type. They can be used both when connected in a star center and when connected in a triangle with isolated phases.

BACKGROUND OF THE INVENTION

A step voltage regulator (1) of the so-called column type is known. It contains a support head, an insulating cylinder and a bottom shaped like an oil container. Inside are placed on three floors for the three phases switching under load single-phase contact systems, each of which has two vacuum arc quenching chambers - one main and one auxiliary. On both sides of the vacuum arc quenching chambers (VDK) are mounted a contact bridge connecting in series VDK with fixed contact elements located in a circle on the inner surface of the insulating cylinder, and a terminal contact bridge on the other side of VDK, which connects them with a metal ring also located on the inner surface of the insulating cylinder. There are also mechanical systems for opening and closing the VDK in a certain order and for stable guidance of the movable elements. They are mounted on a centrally located insulating tube, hopping

1/11 activated by a spring-energy accumulator. Current-limiting resistors are also attached to this pipe.

The disadvantage of this power switch, which works as a selector under load, is that it is complex in construction and has large dimensions. The disadvantage is that the main and auxiliary VDC do not switch separately at all switches and this limits the switching capacity. Another disadvantage is that the activation of the contact systems is done by shocks, which increases the mechanical wear and requires a stronger spring-energy battery.

Another constructive concept for making column-type step regulators is also known. These step controllers have simple and compact single-phase power switches (2). In this case, however, these power switches are of the conventional type with oil arc quenching. A power switch with VDK for this type of step controller is shown in (3). It comprises a main VDK and an auxiliary VDK connected by contact elements and placed between a metal flange and an insulating flange, which are mounted in an insulating cylinder. A drive shaft is mounted in the middle of the cylinder, which rotates the VDK and the contact systems 180 ° when switching. The contact systems are located above the insulating flange. Resistors are mounted on the side of the insulating cylinder.

The disadvantage of this single-phase power switch is that it has a complex design and has increased dimensions due to the side mounting of the resistors. Another disadvantage is that the two VDCs do not switch separately, due to which large values of rated currents and step voltages cannot be achieved.

Split switching is performed in the power switch shown in (4). It has two drive shafts mounted coaxially, one first switching the main VDK and the hollow shaft switching the auxiliary VDK. As a result, the construction is significantly complicated. The resistors are also mounted outside the insulating cylinder.

The single-phase power switches mentioned so far work with one main VDK and one auxiliary VDK. A single-phase power plant is also known

2/11 switch (5), which has two main VDK and one auxiliary VDK. Its contact system occupies half the space of a larger insulating cylinder, and the resistors are located in the other half. The power switches with three VDCs have a higher switching capacity in a simplified design.

The disadvantage of this single-phase power switch is that it has large dimensions. This will lead to a significant increase in the overall dimensions and weight of the column-type step regulator.

SUMMARY OF THE INVENTION

The object of the invention is to provide a single-phase power switch with three VDCs for a column-type step voltage regulator. The power switch should fit in a small cylindrical volume in which the resistor is located.

The problem is solved with a single-phase power switch for step voltage regulator column type, containing two main vacuum arc quenching chambers and one auxiliary vacuum arc quenching chamber (VDK), attached to an insulating plate, and mechanisms for switching off and on the VDK. There is also a contact system connected to two high-speed disconnectors and a contact system connected to the auxiliary VDK and resistor.

According to the invention, two main VDCs and one auxiliary VDC are attached to one half of the insulating disk. In the other half of the disk there is a main contact system, consisting of a current-carrying sleeve with a tail, mounted on a support on a carrier of each of the two main VDK. There are two current-carrying contact lamellas with contact springs on the tail. The inserts in a certain sequence are connected to an even fixed contact element and an odd fixed contact element, which are attached to the insulating disk. This is obtained by rotating the current sleeve by means of a connected fork and a roller mounted on a switch, mounted on a central drive shaft.

3/11

Above the three VDK is an auxiliary contact system, performing in a certain sequence the connection between the three VDK and the resistor.

The auxiliary contact system consists of an insulating bracket attached to the support of the auxiliary VDK, a contact arc is mounted on top of the console, and below it there are two contact arcs with an insulating gap between them. The arches are mounted on current-carrying brackets on the girders of the two main VDCs. A rotating sleeve with a arm is mounted on the drive shaft, on which an upper contact plate is established, in contact with the arcs connected to the main VDK. This rotation occurs at the end of the shift, as there is an idle clutch between the rotating sleeve and the drive lever. As a result, the necessary connections are realized between the three VDK and the resistor, which is located under the main contact system in the space under the plate.

The current connection between the current sleeve and the bracket of the carrier of each of the two main VDCs is made by a flexible connection. Alternatively, this could also be done by plug contact elements.

The upper insulation disc and the lower metal disc are connected by vertical insulation studs. Alternatively, vertical insulation rails can be used.

The discs are additionally reinforced by two segments of insulating pipe. As an option, a vertical cage made of insulating rails can also be used. The segments connect the three single-phase power switches for the three phases of the three-phase step controller in one stable column. Coaxially and in pairs at each single-phase power switch are arranged an even contact ring connected to the even fixed contact element, an odd contact ring connected to the odd fixed contact element, and an output contact ring connected to the metal disk. On the drive shaft is mounted a cam, which interacts with a mechanical system that turns on and off the three VDK. The system contains a stud wound in the terminal of the movable element of the respective VDK and a bracket mounted on it. The carrier has two rollers and can make some movement along the stud in order to adjust the exact contact solution of the VDK. The two rollers contact the L-shaped lever with a roller or bearing on top, which

4/11 interacts with the hump. The L-shaped lever is mounted on a bracket that is mounted on a metal disk.

The resistor is made of zigzag punched strip of stainless or electrical steel sheet with a relatively large specific electrical resistance. The tape is folded in a zigzag pattern, and between the individual turns there is a distance from the insulating tape. There may be a variant of a resistor made of a resistive wire with a round or rectangular cross section.

An advantage of the single-phase power switch according to the invention is that the construction has three VDCs, which provides higher technical parameters compared to the switches with two VDCs. Another advantage is that the resistor is inside the power switch and smaller dimensions and a simpler design are achieved.

Another advantage is that the column with the three single-phase power switches is stationary, which results in advantages for the entire column-type step controller.

EXPLANATION OF THE ATTACHED FIGURES

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

Figure 1 is a longitudinal section through the power switch (E-E).

Figure 2-part section through the main contact system (D-D).

Figure 3 - top view of the contact systems located above the upper insulation disk (B-B).

Figure 4 is a cross-sectional view above the lower metal disk (CC).

Figure 5 - part of the resistance strip from which the resistor is made.

5/11

EXAMPLES OF EMBODIMENT OF THE INVENTION

The supporting structure of the power switch consists of a lower metal disk 1, an upper insulating disk 2 and insulating studs 3. After mounting all the elements, two segments 4 and 5 of a cut insulating cylinder are mounted between the two disks and above the upper disk. These segments reinforce the three floor-mounted single-phase power switches for the three phases in one column. Alternatively, the two segments may be replaced by a cage of vertical insulating elements. To the upper insulating disk 2, by means of supports 6, two main vacuum arc-quenching chambers VI and V2 and one auxiliary vacuum arc-quenching chamber (VDK) VC located between them are attached. In the middle of the switch to the two disks 1 and 2 is mounted a drive shaft 7, on which is mounted by an insulating sleeve 8 a cam 9. The cam interacts in a certain sequence with the mechanical systems for opening and closing the three VDK. Each of the three identical systems is composed of an L-shaped lever 10 with a bearing (or roller) 11 that interacts with the cam 9. The L-shaped lever 10 is mounted on a carrier 12 mounted on the disk 1 and is in contact with two rollers 13, fastened to a carrier 14, which is connected to a stud 15 wound in the terminal of the movable contact element of the VDK. The adjustment of the VDK solution is done by moving the carrier 14 on the stud 15, after which it is fixed with screws (Fig. 1 and 3). The system also has a contact spring 16 and a flexible connection 17 for discharging the current from 15 to 1. At the lower end 18 of shaft 7 is mounted a arm with buffer 19. Towards the end 18 and the similar end on the upper side are mounted intermediate unshown shafts the three-phase power switches.

The power switch has a main contact system connected to VDK VI and V2 and an auxiliary contact system connected to VC. The main contact system comprises a current-carrying sleeve 20 with a tail 21, rotating at a certain angle on a stud 22 attached to the carrier 6 of the respective main VDK - VI or V2. On the tail 21 are mounted two conductive lamellae 23, pressed against it by contact springs 24. On the conductive sleeve 20 is mounted a fork 25, which is actuated by a roller 26 caught on the end of a switching lever 27 mounted on the shaft 7. the shaft 7 by an insulating element 28. The carrier 6 of the respective main VDK has a bracket 29 electrically connected to the current-carrying sleeve 20 by a flexible connection 30.

6/11

Coaxially on the outside of the cylinder of segments 4 and 5, an even contact ring 31, an odd contact ring 32 and a terminal contact ring 33 are arranged in floors. They are attached to the insulating cylinder by insulating elements 34. The contact rings contact unshown contact systems which are part of from the step controller, in which the column of the three single-phase power switches is built in.

An even fixed contact element 35 is mounted on the insulating disk 2, which is connected to the even contact ring 31 by a cylindrical protrusion 36. An analogous odd fixed contact element 37, but with an extended downward end, is connected to the odd contact ring 32. The terminal contact ring 33 is connected to the metal disk 1 by an intermediate current-carrying element 38. The current-carrying lamellae 23 are switched on and off in a certain sequence with the fixed contact elements 35 and 37. In this case VDC VI and a fixed contact element 35 connected to the even contact ring 31 are included. facilitating the switching on and off of the current-carrying lamellas 23, bearings or rollers 39 are mounted on their outer end. A current-limiting resistor 40 is located in the space opposite the VDK. In this case it is made of punched zigzag sheet metal (Fig. 5) of stainless steel or electrical. , which have a relatively high specific electrical resistance. The sheet metal tape is folded in a zigzag pattern and insulated between the turns with insulating tape. For example, a prespan, which can be perforated. Other resistor designs are possible. The resistor is connected to the auxiliary contact system. This system comprises an insulating bracket 41 mounted on the support 6 of the auxiliary VDK VC, on which the bracket is mounted a contact arc 42. Below this arc are two symmetrically arranged contact arcs 43 and 44, between which there is an insulating gap. The arches are attached to the brackets 29 of the two main VDK VI and V2. In the upper part of the shaft 7, under the switching lever 27 is rotated a rotating sleeve 45 (Fig. 1 and 3), which rotates at the end of the switching under the influence of tooth 46 of the lever 27, removing the gap 47. The sleeve 45 has insulated relative to it is a arm 48 which carries an upper contact plate 49 and a lower contact plate 50. The plates contact the arm by being pressed against it by contact springs 51. The upper contact plate 49 is connected to the contact arc 42 and the lower

7/11, the contact plate 50 is switched between the contact arcs 43 and 44. One end of the resistor 40 is connected to the contact arc 42, and the other end to the support 6 of the auxiliary VDK VC. The connecting wires to the resistor are insulated and pass under the upper insulating disk 2, but are not shown in the drawings. The single-phase power switch can be set and functionally checked before closing between segments 4 and 5. The two segments are then mounted and the three single-phase power switches are assembled in one stable column. Then the current-carrying rings 31, 32, 33 are installed on each phase.

The operation of the single-phase power switch according to the invention is as follows:

In one shift, in the exemplary embodiment shown, the drive shaft 7 rotates 150 ° in one direction and reverses 150 ° in the other direction for the next shift. The rotation is performed abruptly on the three phases of an unknown spring-energy accumulator not shown.

The sequence of operation of the contact systems is as follows:

Under the influence of the roller 26, when turning the switching lever 27, the contact element 37 is first switched on. The cam 9 closes the auxiliary VDK VC, after which the main VDK VI opens. Sufficient time is provided for the electric arc in VDK VI to go out and the other main VDK V2 is closed. Then the auxiliary VDK VC is opened and the electric arc in it is extinguished. During the last 20 ° of rotation, the auxiliary contact system is switched from arc 43 to arc 44, thus preparing the reverse switching. At the end, the contact pair 23 - 35 is opened, which provides the necessary insulation distance.

Claims (6)

PATENT CLAIMS 1. A single-phase power switch with three vacuum arc-quenching chambers for a column-type step voltage regulator, comprising two main vacuum arc-quenching chambers and one auxiliary vacuum arc-quenching chamber attached to an insulating plate, and mechanisms for switching off and on there is also a contact system connected to two quick-acting disconnectors and a contact system connected to the auxiliary vacuum arc quenching chamber and a resistor, characterized in that two main vacuum arc quenching chambers (VI and V2) are attached to one half of the insulating disk (2). ) and between them - an auxiliary vacuum arc quenching chamber (VC), and in the other half of the disk (2) is a main contact system consisting of a current-carrying sleeve (20) with a tail (21) mounted on an axle (25) mounted on carrier (6) of each of the two main vacuum arc quenching chambers (VI and V2), the tail (21) having two currents connecting contact lamellae (23) with contact springs (24), which in a certain sequence are connected to an even fixed contact element (36) and an odd fixed contact element (37), attached to the insulating disk (2), by rotating the current-carrying sleeve 20) by means of a connected fork (25) and a roller (26) mounted on a switch (27) mounted on a central drive shaft (7), and an auxiliary contact system is located above the vacuum arc quenching chambers (VI, V2, VC), performing in a certain sequence the connection between the vacuum arc quenching chambers and a resistor (40). Single-phase power switch according to claim 1, characterized in that the auxiliary contact system consists of an insulating bracket (41) mounted on the support (6) of the auxiliary vacuum arc quenching chamber (VC), a contact arc is mounted on top of the bracket (47). ), and below it there are two contact arcs (43, 44) with an insulating gap between them, mounted on current-carrying brackets (29) on the supports (6) of the two main vacuum 9/11 arc-quenching chambers (VI, V2), on the drive shaft (7) is mounted a rotating sleeve (45) with an arm (48) on which are mounted an upper contact plate (49) in contact with the arc (42), and a lower contact plate (50) rotating in contact with the arcs (43, 44) when rotating at the end of the switching sleeve (45) connected by an idle connector to the switching lever (27), and as a result the necessary connections between the three vacuum arc quenching chambers (VI, V2, VC) and the resistor (40) located below the main contact system. Single-phase power switch according to claims 1 and 2, characterized in that the current connection between the current-carrying sleeve (20) and the bracket (29) of the carrier (6) of the main vacuum arc quenching chamber (VI or V2) is made by a flexible connection ( 30), but could also be done by plug contact elements. f Single-phase power switch according to claims 1, 2 and 3, characterized in that the upper insulating disk (2) and the lower metal disk (1) are connected to vertical insulating studs (3) or insulating rails - as an option, and are additionally reinforced by two segments (4,5) of insulating pipe or cage of insulating elements - as an option, these segments connect the three single-phase power switches for the three phases of the three-phase step controller in one stable column, and coaxially and storey at each single-phase power switch are arranged an even contact ring (31) connected to the fixed contact (35), an odd contact ring (32) connected to the fixed contact element (37), and an output contact ring (33) connected to the metal disk (1). Single-phase power switch according to claims 1, 2, 3 and 4, characterized in that the drive shaft (7) has a cam (9) which interacts with the mechanical system for switching on and off the vacuum arc-quenching chambers (VI, V2) , VC) comprising a stud (15) wound into the outlet of the movable contact element of the respective vacuum arc-quenching chamber with a carrier (14) mounted thereon, which can 10/11 to make small axial movements along the stud, the carrier (14) has two rollers (13) connected to the L-shaped lever (10) with a bearing or roller (11) on top, the L-shaped lever (10) is mounted on a bracket (12) mounted on the metal disk (1). Single-phase power switch according to claims 1, 2, 3, 4 and 5, characterized in that the resistor (40) is made of zigzag punched strip of stainless or electrical steel sheet, the strip being zigzagged and between the individual turns there is a distance from the insulating tape, but as an option the resistor can be made of a round or rectangular resistive wire.