BG112103A - A three phase step regulator of volatge with vacuum finger-arched chambers and reactors - Google Patents

Abstract

The step regulator works as a switch under a load. It is not mounted in a metal vessel, but in an oil one, made up of a carrier head (1), an isolation cylinder (3) and a bottom (4). In the carrier head (1) are located two floors. In the first one are placed the mechanism, which ensures a shift action of the vacuum finger arched chambers (VAC). In the second are located the mechanism, which through a spring-energy accumulators rotates saltatory and successively one pipe isolation valve (43), each carrying a VAC (46) per phase and one dense isolation valve (44), each carrying yet one more VAC (54) per phase. Each VAC has a metal head (50) with contact segments (51), which establish contact in shifts with P-shaped immovable contact elements (54), mounted on the internal surface of the isolation cylinder (3). Towards the movable outlets (47) of the VAC are linked contact elements (58), which slide continuously on rings (56). The movable outlets (47) of the VAC are operated by leavers (48) with rolls (49), which in stationary mode fall in radial channels in the rings (56). Sideways to the oil vessel is placed a pre-switch, which functions in a specific way.

Description

THREE-PHASE STEP VOLTAGE REGULATOR WITH VACUUM EXTINGUISHING CHAMBER AND REACTORS

FIELD OF THE INVENTION

The invention relates to a three-phase stepped voltage regulator with isolated phases, in which vacuum arc quenching chambers are used. Reactors that are located outside the step controller are used as current-limiting resistors.

BACKGROUND OF THE INVENTION

A three-phase step voltage regulator with vacuum arc quenching chambers and reactors (1) is known, comprising for each isolated phase a power switch and a selector with a preselector. The power switch has one vacuum arc quenching chamber (VDC), two parallel • · · ··· · · · · 2:: ·::: ·::

·· ···· ··· ·· ······ contact units and spring-energy accumulator. The three power switches of the three phases are mounted next to each other on insulation boards. The selector contains circular rails on the rails and a Maltese drive system. The rails are mounted on an insulating plate, on which the pre-selector is mounted. The elements of the three phases are located in a metal cauldron with a lid. The connection to the transformer boiler is made laterally at the insulating plate of the selector and the pre-selector.

£ A disadvantage of this three-phase step voltage regulator is that it is complex in construction, which makes it more expensive. Another disadvantage is that its installation to the transformer is complicated. Another disadvantage is that the overall dimensions of the transformer increase.

SUMMARY OF THE INVENTION

The object of the invention is to provide a three-phase stepped voltage regulator with isolated phases, which works according to a known circuit of switching with the help of reactors. It contains a spring-energy accumulator, a contact system with VDK and actuators. These assemblies are located in an oil seal vessel and the reactors are located outside it.

The fixed contact elements are arranged in a circle on the insulating elements. They are bypassed by movable contact slats commanded by Maltese gears.

According to the invention, on a drive shaft entering through the cover of the support head, a double gear is mounted, which rotates alternately two blocks, consisting of one Maltese and one gear. When the double translation is rotated 180 °, one block rotates, and when the next rotation is rotated in the same direction - the second block. In this case, the blocks are rotated at an angle of 60 °, but through accelerating gears, shafts with eccentric thumbs are rotated 360 °. The eccentric thumbs rotate the hubs, which tension the switching springs. They are two pieces. Alternately, one of the two translations connected to the hubs rotates abruptly, rotating a block consisting of one Maltese and one gear. The gear of one block is engaged with another gear connected to a tubular insulating shaft. One VDK per phase is attached to it. The gear of the second block is engaged with another gear connected to a solid insulating shaft located inside the tubular insulating shaft. One more VDK per phase is attached to the solid insulating shaft by means of supports.

Nine U-shaped fixed contact elements are arranged on the inner surface of the insulating cylinder. They are successively in contact with movable contact lamellas connected to metal heads of the respective VDK. The movable terminal of each VDK has a carrier to which contact lamellas are connected by a flexible connection. They are in constant contact with a ring mounted on the inner surface of the insulating cylinder. A drive lever with a roller is mounted to the carrier at the movable terminal of VDK. It falls into the radial grooves of the rings. These channels are located opposite the stationary position of the VDK. Thus, when the rotation starts, the VDK is switched off, and when the rotation is completed, the VDK is switched on.

In the bearing head of the step regulator is located a bearing structure consisting of a bearing flange and two flanges located above it. On the upper floor of the supporting structure are placed the mechanisms for shift actuation, and on the lower floor - the mechanisms for shifting. The supporting structure and the movable contact systems can be removed for inspection and control. The pre-selector is located on the side of the insulating cylinder. The movable contact slats are two pairs. They are actuated by an insulating rail connected by a lever, gear, fork and Maltese wheel to a double gear.

An advantage of the step voltage regulator according to the invention is that it is very simple as it works as a selector under load. Another advantage is that there is no metal boiler, but an oil pan is used, as with step regulators with resistors. Another advantage is that the step regulator is built into the boiler of the transformer, possibly above the reactors. This reduces the overall dimensions of the transformer.

EXPLANATION OF THE ATTACHED FIGURES

An exemplary embodiment of the three-phase step voltage regulator with VDK and reactors according to the invention is shown in the attached figures, of which:

Figure 1 is an electrical diagram of the connection of one phase of the step controller to the windings of the load-adjustable transformer.

Figure 2 - longitudinal section in unfolded form through the three-phase step regulator. For simplicity, phase Y is not shown because it is the same as phases X and Z.

Figure 3 - another longitudinal section through the actuators of the step regulator.

Figure 4 - top view of the mechanisms performing sequential actuation of the two contact systems with VDK.

Figure 5 - top view of the two spring-energy accumulators, which switch the two contact systems with VDK separately.

:: ·::: ·::

·· ·· «· ··· ·· ······

Figure 6 - cross section through the contact systems with VDK and the pre-selector. The top right shows a top view of the two independent contact systems with one VDK each, and the left half shows the same contact systems seen from below.

EXAMPLES OF EMBODIMENT OF THE INVENTION

In FIG. 1 shows a known electrical diagram of the connection of one phase of the step regulator to the control winding PH and the main winding OH of the transformer. What is new in this case is that the nine contact elements 1 to K connected to the pH are located on the periphery of the insulating cylinder M. The two vacuum arc quenching chambers V _t and V ₂ are connected in series to one contact element (in case 1) or to two adjacent contact elements (eg 1 and 2). The last connection is known as bridge operation, in which a circulating current also occurs. On the other hand, V ₍ and V ₂ are in continuous contact with contact rings B। and B ₂ , to which are connected the two branches of the reactor R. The pre-selector P is located laterally on the insulating cylinder M. It connects in series contact element K with one of contact elements plus (+) or minus (-).

From the longitudinal sections through the step regulator (Fig. 2, Fig. 3) it can be seen that there is a shaped oil vessel of bearing head 1 with lid 2, insulating cylinder 3 and bottom 4. In the bearing head 1 are located the mechanisms for actuating the contact systems. . They are mounted in a supporting body consisting of a supporting flange 5 and two flanges 6 and 7 located above it. The three flanges are connected to each other by columns 8. On the upper floor of the supporting body are • · · ··· ···· 6:: '::: ·::

·· · · · · ··· ·· ······ the stepper drive mechanisms are located. From the drive shaft 9 connected to a known worm gearbox not shown, two blocks 11 and 12, each consisting of one Maltese and one gear, are actuated alternately by means of a double translation 10. The blocks are mounted on an axis 13 mounted between the bearing flanges 6 and 7. The gear of each of the blocks 11 and 12 is engaged in series with one small gear 14 mounted on a shaft 15, one large gear 16 on the same shaft 15 and a small gear 17 on the shaft 18 (Fig. 3, Fig. 4). The Maltese wheels of blocks 11 and 12 are actuated alternately by the two rear-facing rollers 19 on both arms of the double gear 10.

Towards the lower end of each shaft 19, under a flange 6, an eccentric pin 20 is gripped, which alternately actuate the spring-energy accumulators. At each 60 ° rotation of the respective Maltese wheel, the shafts 19 and the eccentric pins 20, respectively, are rotated 360 ° by the accelerating gears.

On the bearing flange 5 are attached two round columns 21, on which are mounted one Maltese translation 22 and above them - one hub 23. The translation 22 and the hub 23 are connected by a freewheel connector 24. An eccentrically mounted pin 25 (Fig. 3, Fig. 5) is mounted on each hub 23, to which one end of a switching spring 27 is attached by a rod 26. The other end of the spring 27 is attached to an axis 28 riveted to the bearing flange 5. On the bearing flange 5, under the drive shaft 9, is riveted a circular column 29, on which are mounted two blocks 30 and 31, consisting of one Maltese wheel and one gear. The Maltese gear 22 of the lower block 30 rotates its Maltese wheel, and its gear is engaged with a gear 32 mounted in the center of the bearing flange 5. Inside the gear 32 is mounted

Mtwrii:. ::. ::

• · ···· · · · · · ······ drive shaft 33 with a gear 34, which is engaged with the gear of the upper block 31. At the upper end of the drive shaft is mounted a Maltese wheel 35, which is actuated by a double gear 36 mounted on the upper end of the circular column 29. The double gear 36 is connected by a coupling 37 to the drive shaft 9. On the shaft 38 mounted to the bearing flange 5 there is a fork 39 connected by a gear 40 to a lever 41, driving the preselector.

A tubular insulating shaft 43 is mounted to the elongated part 42 on a gear wheel 32, and an insulating shaft 44 is mounted to the drive shaft 33. A VDK 46 is attached to the shaft 43 via an insulating carrier 45. a roller 49 and a metal head 50 connected to the contact plates 51. A second VDK 53 is attached to the insulating shaft 44 by an insulating bracket 52 and an insulating carrier 45. It has the same construction as the VDK 46.

Nine U-shaped contact elements 54 (Fig. 1, Fig. 2, Fig. 6) with outlets 55 outside the insulating cylinder 3 are arranged on the inner surface of the insulating cylinder 3. Contact plates 51 of VDK 46 and VDK 53 contact them. Above the VDK 46 and below the VDK 53, two contact rings 56 are mounted to the insulating cylinder 3. On the support 57 of each VDK, at the movable terminal 47, contact plates 58 are connected by non-shown flexible connections, which are in continuous contact with the contact rings. The contact rings 56 have grooves in which the rollers 49 sink into a fixed position and the VDK is engaged. The tubular insulating shaft 43 and the insulating shaft 44 are mounted 59 to the bottom 4.

The pre-selector (Fig. 2, Fig. 6) is located on the side of the insulating cylinder 3. An insulating pipe sector 60 is caught between the support head 1 and a lower metal sector 61 mounted to the bottom 4. A bearing lever 62 is mounted on it, • · · · · · · ·· ♦ 8:: ·::: *::

·· ···· ··· ·· ··· ··· as between it and the lever 41 are mounted drive insulating rails 63. To them are attached the movable contact plates 64 of the preselector. They are two pairs in contact between the U-shaped contact element 65 connected to the contact K (Fig. 1) and the U-shaped contact element 66 mounted on the insulating sector 60. The busbar 67 is connected to the U-shaped contact element 65 with in order to more conveniently connect the wires from the pH control winding (Fig. 1).

The operation of the three-phase step voltage regulator is as follows: The drive shaft 9 rotates 180 ° and rotates block 11 60 °. Through the gears 11-15 and 16-17 the shaft 19 and the eccentric pin 20 are rotated 360 °. The hub 23 tightens the switching spring 27 and the gear 22 and block 30 rotate abruptly. The tubular insulating shaft 43, which carries the VDK 46, is rotated 40 ° through the gear wheel. of the VDK 46 and the jump from the contact lamellae 51 of the operating U-shaped contact element 54 of the adjacent joint without flowing current. At the end of the rotation, the VDK 46 is switched on again.

At the next rotation in the same direction of the double gear 10, the other block 12 is actuated and by the other spring-energy accumulator and block 31, the gear wheel 34 and the insulating shaft 44 are rotated by 40 °. Then VDK 53 is switched off and on, as in the case of VDK 46. Thus, all U-shaped contact elements from 1 to K are traversed (Fig. 1). The Maltese wheel 35 and the gear 40 then switch in a known manner the contact blades 64 of the pre-selector.

The preselector (Fig. 2, Fig. 5, Fig. 6) works in a known manner. Upon reaching position K (Fig. 1), the Maltese wheel 35 overturns the fork 39 and • · · · · · · ···:: *::: ·::

·· ···· ··· ·· ······ through the gear 40 and the lever 41 rack 63 switches the contact lamellae 64 from one fixed contact element 66 to the other.

Claims (4)

PATENT CLAIMS 1. Three-phase step voltage regulator with vacuum arc quenching chambers and reactors, comprising a drive shaft connected to gears and Maltese mechanisms which actuate vacuum arc quenching chambers (VDC) and movable contact lamellae contacting alternately with circularly arranged fixed elements the hopping is performed by a spring-energy accumulator, characterized in that a double gear (10) is mounted on the drive shaft (9), which rotates alternately two blocks (11, 12), consisting of one Maltese and one gear, by means of gears (11-14, 16-17) two shafts (18, 19) with an eccentric pin (20) make one switching turn and actuate a hub (23) with a switching spring (27) connected by a coupling with a free a stroke (24) with a gear (22) which rotates a block (30, respectively 31) consisting of one Maltese and one gear, the gear of one of the blocks (30) being engaged with a gear (32) connected with insulations tubular shaft (43), the gear of the other block (31) is connected to a gear (34) and an insulating shaft (44), on the tubular shaft (43) are mounted one VDK (46) per phase, on the insulating shaft (44) by brackets (52) are mounted one VDK (53) per phase, and on the inner surface of the insulating cylinder (3) are located U-shaped fixed contact elements (54), which successively contact the contact lamellae (51) attached to metal heads (5) of VDK (46, 53). Three-phase step voltage regulator according to Claim 1, characterized in that at the movable terminal (47) of • · · · · · · · 2:: ·::: *:: ·· ···· ··· ·· ······ each VDC (46, 53) has a carrier (57) to which contact lamellas (58) are connected by a flexible connection, contacting continuously with a ring (56) , mounted on the inner surface of the insulating cylinder, and on the ring (56) there are radial grooves in which fall in a stationary position rollers (49) of drive levers (48) connected to the movable terminal (47) of VDK (46, 53) . Three-phase step voltage regulator according to Claims 1 and 2, characterized in that a support structure consisting of a support flange (5) with two flanges (6, 7) arranged above it is arranged in the support head (1). , as in the upper floor there are the mechanisms for alternating actuation, in the lower floor - the mechanisms for hopping, and to the bearing flange is connected a removable part of the movable contact elements. Three-phase step voltage regulator according to claims 1, 2 and 3, characterized in that the pre-selector is located on the side of the insulating cylinder (3), its movable contact lamellas (64) being two pairs and actuated by an insulating rail (63) connected by a lever (41), a gear (40), a fork (39) and a Maltese wheel (35) to a double gear (36).