BG66471B1 - Power switch for oltc with two arc arrester chambers per phase - Google Patents

Abstract

The power switch is a main assembly of the OLTC and used for control of the voltage on-load of power transformers. It has one main vacuum arc arrester chamber (AAS1) and one auxiliary vacuum arc arrester chamber (AAS2). The input shaft (31) is placed on metal bottom (27) and is coupled by means of overload gear to the shaft (32) of the main switchboard system (6). This shaft (32) has at its lower end a cam (37), which by means of fork mechanism (22) switches off and on (AAS1). At its upper end, the shaft (32) is coupled through isolated support (44) to the moving contact bridge of the main switchboard (6). It consists of contact arc (5) connected to AAS1 and two sectors - short and long (7, 8), attached to the fixed contact elements (9, 10). Outside of the shaft (32) coaxially a tubular shaft (33) is placed, with cam (45) for actuation of AAS2 and it is also connected to an auxiliary switchboard (17) with design similar to that of the main switchboard (6). There is a simplified execution version, in which there is no overloading gear. The design provides switching off by AAS1 only of the operation current and switch off by AAS2 only of the circulating current.

Description

(54) POWER SWITCH FOR STEP VOLTAGE REGULATOR WITH TWO VACUUM PHASE EXTINGUISHING CHAMBER

Field of technology

The invention relates to a power switch for a step regulator, designed to regulate under load the voltage of power transformers. It has one main vacuum arc quenching chamber (VDK) and one auxiliary vacuum arc quenching chamber (VDK) per phase. With this type of power switches, it is preferable for the main VDK to switch off the operating current in both directions, and the auxiliary VDK to turn off the circulating current.

BACKGROUND OF THE INVENTION

A power switch for step voltage regulator / 1 / is known, containing for phase one main VDK, switching off the operating current and one auxiliary VDK, switching off the circulating current, which is equal to the step voltage divided by the value of the resistor. In order to achieve this separate switching off of the two types of currents, two sets of control humps are used, located one below the other. One set of cams works in one direction of switching, and the second set of cams works in the other direction. The switching of the cam sets is done by a connector, commanded by a profile channel, connected to the spring-energy accumulator of the power switch. The construction is complemented by two switching contact units and parallel contact units, part of the elements of which are located on the inner surface of the oil vessel of the step regulator.

The disadvantage of this power switch is that it has a complex and heavy construction. Another disadvantage is that the power switch can be oscillated and controlled only when installed in the oil tank, which complicates production and operation.

Technical essence of the invention

The object of the invention is to provide a power switch for a step voltage regulator with two VDCs per phase, of which the main VDK to exclude only the operating current, and the auxiliary VDK - only the circulating current. The construction should be simple, compact and light.

There should be no parallel contact units, which would ensure that the power switch removed from the oil tank would be a separate complete unit. So that it can be controlled, tested and revised without problems.

The problem is solved with a power switch for step voltage regulator, containing per phase one main VDK and one auxiliary VDK, two switching contact systems and a drive shaft with command cam 15 mechanisms for actuating VDK.

According to the invention, a shaft of a main switching contact system is mounted in a tubular shaft of an auxiliary switching contact system. At the upper end of the first shaft is mounted an insulated carrier with a main current-carrying bridge of the main switching contact system, and at the lower end of the shaft there is a cam for actuating the main VDK. At the lower end of the tubular shaft there is a cam for actuating the auxiliary VDK, and at 25 the upper end of the tubular shaft is mounted an insulated support with an auxiliary current-carrying bridge of the auxiliary switching contact system.

One variant is when the shaft of the main switching contact system is coupled by an overload clutch with an input shaft mounted on the metal bottom of the power switch. In the case of a general rotation of the input shaft at an alpha angle, the operating range of the main VDK is the first angle alpha / 2, and the operating range 35 of the auxiliary VDK is the second angle alpha / 2. When reversing, the operation sequence is preserved, as there is an idle stroke of the input shaft pins until the tube shaft arm touches.

The main switching contact system consists of a contact arc, a main current-carrying bridge, a short arc and a long arc with an insulating gap between the two arcs. Similarly, the auxiliary switching contact system 45 consists of a contact arc, an auxiliary current bridge, a long arc and a short arc with an insulating gap between them. The short arc of the main switching contact system and the long arc of the auxiliary contact system are connected to a common contact element. Also

B1 figure 3 - top view of the power switch;

Figure 4 is a cross-sectional view of the power switch above the cam mechanisms;

figure 5 - variant of the power switch from fig. 2;

Figure 6 is a cross-sectional view above the cam mechanisms of the variant of Figure 1; 5.

The attached figures show a single-phase power switch with an alpha angle = 120 °. With a three-phase power switch, the three phases are located at 120 ° to each other, and the alpha angle can be 45 °.

Examples of the invention

The power switch has one main VDK1 (Fig. 1) and one auxiliary VDK2 connected in series with resistor 3. A main switching contact system 4 is connected in series with VDK1, consisting of a contact arc 5, a main current bridge 6, a short arc 7 and a long arc. 8. The short arc 7 is connected to a current-carrying contact element 9 and the long arc 8 to a current-carrying contact element 10. These two contact elements are connected to a step winding 11 of the transformer by contact elements 12 and 13 of a known selector. The short 7 and the long 8 contact arcs are separated by an insulating gap 14, which must withstand the test stresses of one step.

Similarly, an auxiliary switching contact system 15 consisting of a contact arc 16, an auxiliary current-carrying bridge 17, a long arc 18 and a short arc 19, which are separated by an insulating gap 20, is connected in series to VDK2 and the resistor 3. VDK1 and VDK2 have a common terminal 21 and two rockers 22 and 23, through which the cam 24 switches off and on VDK 1 and VDK2. The current axles 6 and 17 and the cam 40 24 are driven by a common shaft 25. This shaft rotates clockwise in a known manner by a spring energy accumulator not shown. First, the cam 24 opens through the rocker 22 VDK1 and the main current-carrying bridge 6 passes the gap 14 without current. Thus VDK1 is connected to the contact element 10 and a circulating current begins to flow through the circuit VDK1 VDK2. This circulating current is then switched off by VDK2 and the auxiliary contact bridge 17 passes the respective long arc and the short arc are connected to a second common contact element. The two common contact elements are connected to two adjacent deviations of the step winding of the transformer. 5

The supporting structure of the power switch consists of an insulating sector of a cylinder, an insulating carrier and a metal bottom. The two common contact elements are mounted on the upper end of the insulation sector. The main VDK and the auxiliary VDK are attached to the 10 insulating supports by current-carrying heads. At the bottom are rockers for actuation by humps of the two VDK. The overload clutch can be made with front teeth with 15 bilaterally angled sides. The input shaft has dowels on which a movable element supported by springs slides.

In another simpler embodiment, the shaft of the main switching contact system is 20 mounted directly on the base, wherein the embodiment has no overload clutch. The two arcs of the main switching contact system are equally long and the insulating gap is located at an alpha / 2 angle. In case 25, the preferred operating range of the main VDK is 2 / Zalfa, and of the auxiliary VDK - 1 / Zalfa. For single-phase power switches, the alpha angle can be 120 °, and for three-phase - alpha = 90 °.

The advantage of the power switch according to the invention is that it has a simple and light construction, which allows the main VDK to switch off only the operating current and the auxiliary VDK only the circulating current. The power switch is a separate mounting unit 3 5 and can be revised and tested by removing it from the oil pan.

Explanation of the attached figures

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

Figure 1 is an electrokinematic diagram of the output variant of the power switch 45;

Figure 2 is a longitudinal sectional view through the power switch, such as sections AA and BB of Figure 1; 3 are combined;

66471 Bl current-free gap 20. This completes the switching in this direction. When reversing, VDK2 opens and closes first, and then VDK1. In this case VDK1 excludes the sum of the operating current and the circulating current, which is a disadvantage. It is an object of the invention to avoid this disadvantage by ensuring that in both switching directions VDK 1 operates first and then VDK2.

How this is achieved is clear from Figures 2, 3 and 4. The position numbers of Figs. 1 are reserved. The supporting structure of the single-phase power switch consists of an insulating sector 26 of a cylinder connected to a metal bottom 27 and an insulating carrier 28. VDK1 and VDK2 are attached to the insulating carrier 28 by current-carrying heads 29 and 30. The contact elements 9 and 10, bearing the respective short and long arcs, are also mounted on the insulation sector. The drive shaft 25 is divided into three parts - an input shaft 31, a shaft of the main contact system 32 and a shaft of the auxiliary contact system 33. The shaft 31 is mounted to the bottom 27 and is coupled to the shaft 32 by an overload clutch 34, which in this case is a front with angled teeth. The movable coupling member 35 slides axially relative to the shaft 31 and is supported by springs 36. A cam 37 is mounted on the shaft 32, which interacts with the rocker 22 via a roller 38.

The movable contact element 39 of VDK 1 is connected to the other arm of the rocker 22 by a pin 40 and is supported by a contact spring 41. The discharge from the element 39 is in a known manner by a flexible connection 42. At its upper end the shaft 32 is connected by an insulating element 43 and a carrier 44 with the main current-carrying bridge 6. The shaft 33 is tubular and is mounted externally axially on the shaft 32. It also has a cam 45 which interacts in a similar way with the rocker 23. The current from the movable contact element 46 of VDK2 is via a flexible connection 47. The mechanical connection between the shaft 31 and the shaft 33 is made by tails 48 of the shaft 31. In the upper part of the shaft 33 there is an insulating element 49 and a carrier 50 connected to the auxiliary current bridge 17. The current bridge bridges 6 and 17 are composed in a known manner. of contact lamellae 51 and contact springs 52.

The current connection of the contact arc 5 with the head 29 of the VDK 1 is made by column 53. The end positions of the cam 37 are fixed by two supports 54 (Fig. 4). The end positions of the cam 45 are fixed by an arm 55 connected to 5 shafts 33 and supports 56.

The operation of the power switch is as follows. From a known spring energy accumulator not shown, the shaft 31 rotates abruptly, which rotates through 10 the overload clutch 34 and the shaft 32 at an angle alpha / 2. VDK1 is switched off and the main current-carrying bridge 6 passes the gap 14 without current. Then the cam 37 releases the roller 38 and VDK1 is switched on. The second support 54 stops the shaft 32 and the teeth of the overload clutch skip, but the corresponding tail 48 of the shaft 31 interacts with the arm 55 and the shaft 33 rotates at an angle alpha / 2. In this case, VDK2 is disconnected from the cam 45 in a similar manner, the auxiliary contact bridge 17 20 passes current-free between the gap 20 and finally VDK2 is switched on. During the reverse switching in the first period alpha / 2 the overload clutch 34 rotates the shaft 32 and the tail 48 idles and in the second interval alpha / 2 rotates the shaft 33. 25 Therefore, in both switching directions first VDK1 switches off the operating current and VDK2 the circulating current.

A simpler version of the power switch with similar action is shown in FIG. 5 and FIG. 6. It does not have a shaft 31 and an overload clutch, and the shaft 32 is mounted directly on the bottom 28 and is actuated by the spring-energy accumulator. The insulating gap 14 is located at an angle alpha / 2 from the initial 35 position. The roller 38 is mounted on the elongated arm 57, the rocker 22 being firmly mounted on rolling bearings. The current-carrying bridge 6 has no change, and the current-carrying bridge 17 has been displaced slightly clockwise. When switching, the carrier 44 with the current bridge 6 rotates at an angle alpha, from one end position to the other. After move 2 / Zalfa is switched off and on VDK1, and then for move alpha / 3 is switched off and switched on 45 VDK2. In the reverse switching, VDK1 also works first, and after the free travel between the respective tail 48 and the arm 55 for angle alpha / 3, VDK2 works. In this case, the tails 48 are mounted to the shaft 32.

66471 Bl cylinder, insulating carrier (28) and metal bottom (27), the contact elements (9, 10) being mounted on the upper end of the insulating sector (26) and on the insulating carrier (28) by current-carrying heads (29, 30) ) are attached respectively the main VDK (1) and the auxiliary VDK (2), and on the bottom (27) are located rockers (22, 23) for actuation by cams (37, 45) of the two VDK (1 and 2).

Power switch according to claims 1 to 4, characterized in that when the input shaft (31) is rotated at an alpha angle, the operating range of the main VDK (1) is the first angle alpha / 2 traveled and the operating range of the auxiliary VDK (2) is the second angle alpha / 2, and in the case of reverse switching due to the presence of idling between the arm (55) of the tubular shaft (33) and thumbs (48) of the inlet shaft (31) the sequence is the same.

Power switch according to Claims 1 to 5, characterized in that the overload clutch (34) is a front gear with sides beveled at an angle, the sliding element (35) being able to slide on the input shaft dowels (31). ) and is supported by springs (36).

Power switch according to claims 1 to 5, characterized in that for a single-phase power switch alpha = 120 ° and for a three-phase power switch alpha = 90 °.

Power switch according to claims 1, 3 and 4, characterized in that the shaft (32) is directly mounted on the bottom (27) and the two arcs (7, 8) of the main switching contact system (4) are of the same length and the insulating gap (14) is located in the middle of the angle alpha, as the working range for the main VDK (1) is 2 / Zalfa, and of the auxiliary 40 VDK (2) - 1 / Zalfa.

Application: 6 figures

Literature

1. On-load tap-changers VACUTAP ⁴⁵ VRC, VRE, VRD, VRF, VRG - Maintenance Instructions (company MR - Germany).

Claims (4)

A power switch for a step voltage regulator with two vacuum arc chambers (VDK) per phase, comprising $ one main VDK, one auxiliary VDK, two switching contact systems and a drive shaft with control cams for actuating the VDK, characterized in that that the shaft (32) of the main switching contact system (4) is mounted in j θ tubular shaft (33) of the auxiliary switching contact system (15), and on the upper end of the shaft (32) is mounted an insulated carrier (44) with a main current-carrying bridge (6) of the main switching contact system (4), at the lower end of the shaft (32) $ there is a cam (37) for actuating the main VDK (1), while at the lower end of the tubular shaft (33) there is a cam 45) for actuation of the auxiliary VDK (2), and in the upper end of the tubular shaft (33) an insulated carrier (50) with auxiliary current-carrying 2θ bridge (17) of the auxiliary switching contact system (15) is mounted. Power switch according to claim 1, characterized in that the shaft (32) is coupled by an overload connector (34) 25 with an input shaft (31) mounted on a metal bottom (27) of the power switch. Power switch according to claims 1 and 2, characterized in that the main switching contact system (4) consists of a contact arc (5), a main current-carrying bridge (6), a short arc (7) and a long arc (8). ) with an insulating gap (14) between the two arcs, and the auxiliary switching contact system (15) consists of a contact arc (16), an auxiliary current-carrying bridge (17), a long arc (18) and a short arc (19) with an insulating gap (20) between them, the short arc (7) and the long arc (18) being connected to a common contact element (9) and the long arc (8) and the short arc being connected to another common contact element (10), such as the common contact arc elements (9,10) are connected to two adjacent deviations (12, 13) of a step winding (11) of a transformer. Power switch according to claims 1 to 3, characterized in that the supporting structure of the power switch is composed of an insulating sector (26) of