UA69395U - High-voltage triplepole vacuum switch - Google Patents

Abstract

A high-voltage triplepole vacuum switch comprises three vacuum arc extinguishing chambers with stationary and movable contacts located therein, a support insulations, a mechanism for movable contacts control, the mechanism for movable contact control comprises series and functionally related a regulating member capable of rotation and connection of a power element, a disc made at least with one recess, two spiral springs, each of which is pressed to the disc; an insulator rigidly connected to the disc, having three similar pushers, each of which has a groove with a bearing installed therein and set on an axle, a bearing valve having two fixing bearings. The regulating element is made as an axle-regulator, both springs are made rotatable. In addition, the second disc is incorporated, which is made with a recesses and a supporting flange, a body made from two connected plates parallelly installed on supporting plate at a distance one from another; both discs rigidly installed on the axle-regulator and the bearing valve are located in the body.

Description

A useful model belongs to electrical engineering, in particular to high-voltage load switches with vacuum arc extinguishing chambers.

Well-known vacuum switches / High-voltage vacuum three-pole switches of types VVTZ-10-20,

VvtTP-10-20. Industrial catalog 02.05.08-68, Informzlectro, 1986/, in which the common drive shaft is connected to the moving contacts of the vacuum chambers through three-pole hinge-lever mechanisms and three isolators of influence on the moving contacts of the traction type vacuum chambers.

The use of hinge-lever mechanisms leads to significant energy losses with low reliability of the design, reducing the durability of the three-pole vacuum switch.

Well-known high-voltage three-pole vacuum switch / patent VO 2156006 7НО1Н 33/66,

NOTH 33/42/, containing three vacuum arc-extinguishing chambers, three-pole fastening elements, support insulation, insulating rods, a mechanism for controlling moving contacts, containing at least one electromagnet with a moving core, designed to control moving contacts of vacuum arc-extinguishing chambers. The vacuum arc-extinguishing chambers are arranged to form a triangle in space, the electromagnet is placed inside the triangle formed by the vacuum arc-extinguishing chambers, and its movable core is equipped with three protrusions connected to insulating rods and located in the direction of the axis of movement of the vacuum arc-extinguishing chambers.

The high-voltage three-pole switch has a fairly simple design, but significant disadvantages limit its use.

The presence of an electromagnet leads to the inertia of switching on and off due to transient processes in the electromagnet itself. The presence of a spring near one of the poles provokes non-simultaneous switching on and off of all poles. These reasons lead to unnecessary energy losses, burns, contact wear, and the need to replace them. If the contacts of one of the vacuum arc extinguishing chambers are welded (which almost always happens when short-circuit currents flow), an attempt to turn it off will cause a misalignment and damage to the control mechanism of the moving contacts.

The closest in essence is the high-voltage three-pole vacuum switch / OA patent

Mo 95761 НО1Н 33/66 (2006.01)/, containing three vacuum arc-extinguishing chambers with fixed and moving contacts placed in them, support insulation, fastening elements of three poles,

From the moving contact control mechanism, and the support insulation is made in the form of a plane to which the poles are attached, the vacuum arc extinguishing chambers are located with their axes forming a vertical plane in space, and the moving contact control mechanism contains a sequentially and functionally connected adjusting element, made with with the possibility of connecting a power element, a disk made with at least one notch, two spiral springs, each of which is pressed against the disk, a bearing latch that has two locking bearings.

Such a three-pole vacuum switch is low-energy and durable, because its design protects it from skewing and jamming of the control mechanism of moving contacts, but it cannot be used in the designs of automatic and semi-automatic switches, because it does not meet the speed criteria.

The useful model is based on the task of improving the three-pole vacuum switch to meet the needs of automatic and semi-automatic switches to ensure quick operation, while maintaining their low energy consumption and durability.

The task is solved by the fact that the high-voltage three-pole vacuum switch contains three vacuum arc extinguishing chambers with fixed and movable contacts placed in them, support insulation, a mechanism for controlling the movable contacts, and the mechanism for controlling the movable contacts contains a sequentially and functionally connected regulating element, made with the possibility turning and connecting a power element to it, a disk made with at least one notch, two spiral springs, each of which is pressed against the disk, an insulator rigidly connected to the disk with three identical pushers fixed on it at the same distance, each of which has a groove with with a bearing installed in it, mounted on an axis, rigidly connected through a pressure unit to a moving contact of the corresponding vacuum arc extinguishing chamber and a bearing latch, which has two locking bearings.

The regulating element is made in the form of a regulator axis, both springs are equally reversible. The control mechanism additionally includes a second disk made with a notch and with a support shelf, a housing made of two connected, parallel mounted plates at a distance to the support plane, and the housing houses both disks rigidly mounted on the regulator axis, and bearing latch.

Preferably, the bearing latch additionally includes a latch shaft, two retainers mounted on the latch shaft, each having a locking bearing, a torsion spring mounted on the latch shaft between the retainers, and a flag attached to a mechanical switch mounted on the outer surface of the housing.

Preferably, the bearing latch additionally includes a solenoid mounted near the retainer, connected to the external electrical switch by an electrical connection.

It is better when one of the housing plates, which is located near the insulator, is made with a stop located on its surface, which is directed inside the housing, and the second (outer) additionally has a hole that is coaxial with the axis of the regulator and is larger than it in diameter.

It is better when the support shelf of the second disc is approximately equal in length to the distance between the body plates, placed perpendicular to the disc and attached mid-length to the disc.

Preferably, each coil spring is pressed against a separate disc, both coil springs are equally oriented and both are secured at their outer ends to a support shelf, with the inner end of the spring on the disc connected to the insulator secured to that disc, the inner end of the spring on the second disc - to the body plate.

It is better when the supporting insulation is made in the form of a plane to which the poles are attached, and the vacuum arc extinguishing chambers are located with their axes forming a vertical plane in space.

The linear arrangement of the vacuum arc-extinguishing chambers with the fixing of the poles on the planar insulation contributes to the vertical, distortion-free, movement of the movable contacts and, as a final result, to the durability of the circuit breaker.

The presence in the moving contact control mechanism of a sequentially and functionally connected adjusting element, made in the form of a regulator axis, with the possibility of turning and connecting to it a power element, two discs, two spiral springs, a bearing latch provides the possibility of programming the speed and mode of movement of all movable elements of the switch.

The dimensions of the spiral springs, the shape of the recesses, the design of the elements of the spring latches are selected according to calculations and each design is tested experimentally. Thanks to

From this, sufficiently large forces can be transmitted without jerks and breakage, which allows for the wide use of such a design, without limiting the dimensions of the switches.

The presence of the case protects the mechanism from the effects of the external environment, allows you to use its plates to create a stationary support during the rotation of the springs and thus accumulate mechanical energy, as well as limit the amplitude of movement of the disks, which contributes to their preservation and durability. The successful mutual location of the disks with the springs pressed against them contributes to the efficiency of the switch.

The use to limit the movement of the springs of the stop and the support shelf contributes to the synchronicity and immediacy of the movement of the discs and their return to their original position.

Since each coil spring is pressed against a separate disc, both coil springs are oriented in the same way and both are fixed with their outer ends to the support shelf, with the inner end of the spring on the disc connected to the insulator being fixed to this disc, the inner end of the spring on the second disc - to the outer plate of the case, then one of the disks performs the function of the master, the other the slave. Spiral springs, in addition to the function of transmitting rotation and storing energy, perform functions related to the function of closing the switch, the spiral spring attached to the driving disk is the closing spring, the spiral spring attached to the driven disk is the closing spring. The driving disk receives energy from the power element, and the driven one transmits it to the isolator, which provides, if necessary, an instant shutdown.

Rigid attachment to the isolator disk with the pushers fixed on it ensures transmission without loss of turning moment from the disk to the isolator.

Fixation at the same distance of three identical pushers contributes to the vertical, without distortions, synchronous movement of the movable contacts inside the vacuum arc extinguishing chambers.

The presence of a groove in each pusher, with a bearing installed in it, allows you to adjust the speed, mode and height of the moving contacts inside the vacuum arc extinguishing chambers. The shape of the groove can be set analytically or selected experimentally.

The use of rolling bearings allows you to minimize frictional losses during the transfer of energy inside each pole from the pushers to the moving contacts, contributes to the durability of the switch.

The design of the bearing latch with a mechanical and electric switch allows the switch to be used in automatic and semi-automatic designs.

Thus, the improvement of the three-pole vacuum switch ensures the creation of a durable, low-energy switch with high speed and a wide range of uses.

A useful model is illustrated by drawings that explain the construction of a three-pole vacuum switch and its use, but do not limit the scope of its legal protection.

Fig. 1. General view of a high-voltage three-pole vacuum switch.

Fig. 2. View of the pole in the off state.

Fig. 3. Mechanism for controlling moving contacts in a discharged state.

Fig. 4. Mechanism for controlling moving contacts in a charged state in standby mode.

Fig. 5. The moving contact control mechanism is charged, the switch is on.

Fig. 6. The moving contact control mechanism is discharged, the switch is off.

Where: 1 - supporting insulation; 2 - pole;

C - vacuum arc extinguishing chamber; 4 - fixed contact; 5 - movable contact; b - mechanism for controlling moving contacts; 7 - body plate; 8 - housing plate (external); 9 - regulator axis; 10 - driving disk; 11 - driven disk; 12 - notch; 13 - spiral switch-on spring; 14 - spiral shutdown spring; 15 - insulator; 16 - pusher; 17 - groove; 18 - bearing; 19 - bearing latch; 20 - locking bearing; 21 - locking bearing; 22 - latch axis; 23, 24 - holders; 25 - twisted spring; 26 - flag; 27 - mechanical switch; 28 - solenoid; 29 - stop;

ZO - hole; 31 - support shelf; 32 - flexible current collector.

The high-voltage three-pole vacuum circuit breaker contains (Fig. 1-6) a support insulation 1 made in the form of a plane to which three poles 2 are attached. Three vacuum arc-extinguishing chambers C with fixed 4 and movable 5 contacts placed in them are arranged to form axes in the space of a vertical plane .

The control mechanism of the movable contacts 6 is placed in the case, which is made of two connected, parallel installed at a distance on the supporting insulation 1, the plate 7 and the plate 8, which is external to the entire switch.

The moving contact control mechanism 6 also contains a regulator axis 9 placed in the housing in series and functionally connected, two disks - the leading 10 and the driven 11, which are made with at least one notch 12, two spiral springs - 13, which is a switch-on spring, and shut-off spring 14, each of which is pressed against the corresponding disk 11 and 10.

An insulator 15 is rigidly connected to the disk 11 with three identical pushers 16 fixed on it at the same distance, each of which has a groove 17 with a bearing 18 installed in it, mounted on an axis rigidly connected through a pressure node to a movable bo contact 5 of the corresponding vacuum arc extinguishing chamber 3.

The bearing latch 19 has two locking bearings 20 and 21. The bearing latch also contains an axis 22, mounted on the axis of the latch 22, two holders 23, 24, each of which is fixed to the locking bearing 20, 21, a twisted spring 25, mounted on the axis of the latch 22 between holders 23, 24. The axis is fixed on the body plates, and the flag 26 is connected to the mechanical switch 27, installed outside the outer body plate.

The bearing latch 19 also includes a solenoid 28 mounted near a retainer 24 connected to an external electrical switch by an electrical link.

The plate 7 of the housing, which is located near the insulator 15, is made with a stop 29 placed on its surface, which is directed inside the housing, and the second (outer) 8 has an additional hole Z0, coaxial with the regulator axis 9 and larger in diameter.

The driving disk 10 is made with a support shelf 31.

The switch works like this. The external power element in the form of a drive key is connected through the ZO hole to the regulator axis 9 and the axis is rotated by 907. Together with the axis 9, the drive disc 10 rotates, which thus transmits rotation and, together with it, energy to the springs 13 and 14. At the same time, the bearing 20 is placed in the recess 12 of the disk 10. Springs 13 and 14 rest on the stop 29 and the support shelf 31. The switch is ready for operation and is in standby mode for switching on (Fig. 4).

When the switch is turned on mechanically (semi-automatic switch), the switch 27 is turned, and together with it counterclockwise, the flag 26 turns the holder 23 in the same direction, the spring 13 is discharged. The bearing 21, released from the engagement, releases the disk 11 fixed by it before that, which, under the action of the spring 13, rotates, rotating the disk 11. At the same time, the rotary insulator 15 also turns counterclockwise.

In each of the poles 2, the rotation of one of the pushers 16 causes downward movement by rolling along the groove 17 of the bearing 18, synchronous vertical downward movement of the pressing assembly and, associated with it, the movable contact 5 of the vacuum arc extinguishing chambers C (Fig. 2).

The movable contact 5 is connected to the stationary 4, the current passes through the flexible current collector 32.

This is the simultaneous instantaneous switching on of all poles 2 of the switch.

To implement the shutdown mode when using the mechanical switch 27, turn it clockwise. The flag 26 rotates the holder 24 in the same direction, which removes the bearing from the disc recess 10, releasing the disc. Under the action of the spring 14, both disks 10, 11 and the insulator 15 rotate. Then the action is transmitted to the pushers 16. In each of the poles 2, when one of the pushers 16 rotates, there is an upward movement by rolling along the groove 17 of the bearing 18, a synchronous vertical upward movement of the pressing unit and, connected to it, the movable contact of 5 vacuum arc extinguishing chambers C (Fig. 2). The movable contact 5 moves away from the fixed contact 4. The flexible current collector 32 is de-energized. In this way, all poles 2 of the switch are turned off simultaneously.

When using the electrical shutdown (automatic switch), the retainer 24 is activated by the electrical signal received by the solenoid 28. Subsequently, the bearing latch operates similarly to its operation during mechanical switching.

In this way, the improvement of the three-pole vacuum switch ensures the creation of a low-energy switch, the increase in the durability of the three-pole vacuum switch, and high speed to meet the needs of automatic and semi-automatic switches, which significantly expands the ranges of use of the declared switches.

Claims (7)

USEFUL MODEL FORMULA 1. High-voltage three-pole vacuum circuit breaker containing three vacuum arc-extinguishing chambers with fixed and movable contacts placed in them, support insulation, a mechanism for controlling movable contacts, and the mechanism for controlling movable contacts contains a sequentially and functionally connected adjusting element, made with the possibility of rotation and connection of a power element to it, a disc made with at least one notch, two spiral springs, each of which is pressed against the disc, an insulator rigidly attached to the disc with three identical pushers fixed on it at the same distance, each of which has a groove with an installed in it has a bearing mounted on an axis, rigidly connected through a pressing unit to the moving contact of the corresponding vacuum arc extinguishing chamber, a bearing latch, which has two locking bearings, which is distinguished by the fact that the adjusting element is made in the form of an axis-regulator, both springs are made equally reversible , and additionally contain t the second disk, which is made with a recess and with a support shelf, the body is made of two connected, parallel installed at a distance on the support plane, plates, and the body houses both disks, rigidly mounted on the regulator axis, and a bearing latch. 2. The vacuum switch according to claim 1, which is characterized by the fact that the bearing latch additionally contains a latch shaft, two retainers mounted on the latch shaft, in each of which a locking bearing is fixed, and a torsion spring mounted on the latch shaft between the retainers and connected to a mechanical of the switch located outside on the outer plate of the case, the flag. 3. Vacuum switch according to claim 2, characterized in that the bearing latch additionally contains a solenoid mounted near the holder, connected to the external electrical switch by an electrical connection. 4. A vacuum switch according to any of claims 1-3, which is characterized by the fact that one of the housing plates, which is located near the insulator, is made with a stop located on its surface, directed inside the housing, and the second (outer) additionally has a hole , coaxial with the axis of the regulator and larger than it in diameter. 5. A vacuum switch according to any one of claims 1-4, which is characterized in that the support shelf of the second disk is approximately equal in length to the distance between the body plates, is placed perpendicular to the disk and is attached to the disk in the middle of its length. 6. A vacuum switch according to any one of claims 1-5, characterized in that each spiral spring is pressed against a separate disk, both spiral springs are equally oriented and both are fixed with their outer ends to the support shelf, and the inner end of the spring is on the disk, which connected to the insulator, fixed to this disc, the inner end of the spring on the second disc - to the body plate. 7. A vacuum switch according to any of claims 1-6, which is characterized by the fact that the support insulation is made in the form of a plane to which the poles are attached, and the vacuum arc extinguishing chambers are located with their axes forming a vertical plane. i I i A ks: zan B X soti i t Z ven s "A how ih ste Ptn y dn W s s V ve KN TR en ! - / 4 sh I Shana» soyu TSO Te ke dya (In BOTH sei nn prut vo / pi KO - SCHE for the benches and Kt PI anesyu i SUchaenya I Tu She i, yan, r X / g i x K I Zhe shchi i kh yno y ZE kv CHO 4 kh g. Z. y shen y y kh en Fig. 1