RU2020629C1 - Hydraulic operating mechanism for power high-voltage circuit breaker - Google Patents

Abstract

FIELD: electrical engineering; hydraulic drives for high-voltage circuit breakers, mainly for sulphur hexafluoride switches. SUBSTANCE: operating mechanism has operating cylinder 2 with piston 3 and rod 4 for coupling with movable contact 1 of circuit breaker, energy accumulator made in form of bellows 10 closed at ends by covers 11, 12 one of which is movable and filled with compressed gas; operating mechanism has also hydraulic accumulator, control valve 7, pumping unit and drain reservoir. Novelty in design of operating mechanism is that hydraulic accumulator is made in form of bellows 9 filled with working fluid and arranged between base of cylinder 2 and movable cover of gas bellows. Diameter of bellows 9 filled with fluid is 2 - 3 times less than diameter of gas bellows 10. EFFECT: enlarged operating capabilities. 3 cl, 1 dwg

Description

 The invention relates to high-voltage apparatus engineering, in particular to hydraulic drives of high-voltage circuit breakers, mainly to gas-insulated circuit breaker drives with an autocompression type extinguishing device.

 Known hydraulic drives of high voltage circuit breakers in which pneumatic accumulators are used as a pressure source [1]. Such a drive comprises a working power cylinder, the piston of which is connected via a rod to the movable contacts of the arcing devices; a pneumohydroaccumulator, which is a thick-walled cylinder, divided by a piston into a pneumatic cavity filled with nitrogen to a pressure of 25 ... 35 MPa, and a hydraulic cavity filled with a working fluid (oil), which is constantly hydraulically connected to the over-piston cavity of the working cylinder; a control valve with starting electromagnets, by means of which the piston cavity of the working cylinder communicates either with the hydraulic cavity of the accumulator or with a drain tank; pump unit for pumping spent working fluid from the drain tank into the hydraulic cavity of the battery.

 The disadvantage of this device is the relative complexity and reduced reliability of the seal assemblies of the movable piston of the pneumatic accumulator. In addition, such a drive is notable for its complexity and danger of operation, due to the need to refuel the batteries with compressed nitrogen at the indicated high pressure.

 A drive is known in which a large diameter large-diameter disk spring is used as the energy source, which directly contacts the movable accumulator piston, or transfers force to the specified piston through the pulling pins (Informational publication of the Air Force company N СН-А 156322). Having certain advantages (temperature independence of pressure, operational reliability, which is associated with the lack of a gas system), the design of the drive has several disadvantages. This is the complexity of manufacturing powerful disk-shaped springs of large diameter, (the absence of such technologies in the domestic industry), the instability of the dynamic characteristics due to a rather sharp drop in fluid pressure during movement of the springs during operation, as well as the decrease in spring stiffness during long-term operation due to relaxation phenomena.

 Closest to the invention is a hydromechanical drive of a gas-insulated circuit breaker [2], comprising a working power cylinder with a piston connected via a rod to a movable contact of the switch, a hydraulic accumulator including a cylindrical cavity filled with liquid with a large diameter piston, providing high-pressure liquid to the cavity of the working cylinder , a control valve, a hydraulic pump and a carrier of stored energy, made in the form of hermetically sealed caps from the ends and filled with compressed gas a bellows that transmits pressure to the accumulator piston via a stem.

 The disadvantages of this drive are primarily associated with the implementation of the accumulator in the form of a cylinder with a large diameter piston and a rod that transfers pressure from the bellows to the liquid. The complexity and reduced reliability of the seal assembly of a large-diameter moving piston that is constantly under high unilateral pressure determine the presence of significant fluid loss from the high-pressure cavity. Leaks lead to the need for frequent switching on of the pump to replenish the supply of fluid in the cavity of the accumulator. At the same time, the accumulator piston will constantly make a reciprocating movement even in the absence of operating with a switch. In addition, the presence of a bulky hydraulic accumulator, made in the form of a thick-walled cylinder with a cavity of large diameter and a gas bellows connected by a rod to ensure mechanical contact, complicates the layout of the drive and increases its dimensions.

 The basis of the invention is the task of creating a drive with a simpler and more reliable design of the accumulator, which, on the one hand, would eliminate the loss of fluid from the high-pressure cavity, and, on the other hand, would provide the opportunity to reduce the size and more rational layout of the drive.

 This is achieved by the fact that in a hydraulic actuator containing a working cylinder with a piston and a rod for communication with the movable contact of the circuit breaker, an energy storage device is made in the form of covers hermetically closed from the ends, one of which is movable, and filled with compressed gas bellows, a hydraulic accumulator, a control valve , pump unit, drain tank, hydraulic accumulator is made in the form of a bellows filled with a working fluid, located between the base of the working cylinder and the movable cover of the gas bellows, and the diameter of the bellows it is filled with liquid, 2 ... 3 times smaller than the diameter of the gas bellows.

 The upper movable cover of the gas bellows is made with a concave surface forming a cavity in which the hydraulic bellows is placed.

 The performance of the hydraulic accumulator without a movable pair of piston-cylinder, namely in the form of a bellows, leads to the absence of a complex and having low reliability of the seal assembly. This eliminates the main cause of oil leakage from the high-pressure cavity, which increases the reliability of the drive. In addition, the implementation of the hydraulic accumulator along with the energy carrier in the form of two sequentially arranged bellows led to a simplification of the design of these nodes, making it possible to compile them conveniently.

 Due to the absence of movable seals, these units do not require inspection and replacement of any parts during long-term operation, which simplified their arrangement. It is advisable to place them at the bottom of the drive.

 To exclude the deformation of the bellows above the required value, which could have occurred if the automation system failed to turn the pump unit on or off, the pump failed, the drive has stops that limit the bellows to stretch and compress. This is necessary to maintain the long-term strength and reliability of the bellows.

 The fact that the diameter of the hydraulic bellows is 2 ... 3 times smaller than the diameter of the gas bellows, allows not only to achieve a high level of pressure of the working fluid at a relatively low gas pressure, but also to provide an acceptable ratio of the longitudinal dimensions of the bellows, provided their deformation capacity is equal.

 The drawing shows a hydraulic actuator, a General view in longitudinal section.

 The high voltage circuit breaker 1 is shown schematically in the drawing. The drive contains a working cylinder 2 with a piston 3, which is connected via a rod 4 to the movable element of the switch 1, a pump unit including a pump 5 and an electric motor 6, a control valve 7, a tank 8 for collecting used oil, a bellows 9 filled with oil, and a bellows 10 , sealed by welding, closed at the ends by covers 11 and 12 and filled with compressed nitrogen.

 The hydraulic bellows 9 with one end is hermetically attached to the bottom of the working cylinder 2 through the flange 13, the other end is welded to the movable cover 11 of the gas bellows. This cover 11 is made with a concave surface forming a cylindrical cavity in which the hydraulic bellows 9 is placed. The high pressure cavity 14 formed inside the bellows 9 and filled with oil is constantly connected through the channel 15 to the over-piston cavity 16 of the working cylinder. The piston cavity 17 is connected either to the high-pressure cavity 14, or to the drain tank 8, through the control valve 7. The channel connecting the piston chamber 17 to the valve 7 is formed by drilling in the cylinder and the nozzle 18. The fixed cover 12 of the gas bellows 10 is connected through a power shell 19, covering the bellows, and the ring 20 with the cylinder body 2.

 Thus, the upper movable cover of the gas bellows 11 compresses the oil in the cavity of the hydraulic bellows 9, and the reaction from the lower cover 12 is transmitted through the shell 19 and the ring 20 to the cylinder body 2, its lower part partially recessed into the cavity 14. This is also along with the placement of the hydraulic bellows 9 in the cavity, which forms the top cover 11 of the gas bellows, reduced the size of the drive. To eliminate the non-calculated deformation of the bellows, there are stops 21 and 22, restricting the bellows during tension and compression.

In this particular embodiment, the average diameter D _{1 of the} hydraulic bellows 9 is 2, 6 times less than the average diameter D _{2 of the} gas bellows 10, which ensures an acceptable height-to-height ratio of the bellows and the required low level of nitrogen pressure at a sufficiently high oil pressure level. Calculations showed that, for example, to ensure the movement of the bellows 50 mm with a diameter of a hydraulic bellows D ₁ = 236 mm, its height in the free state will be 320 mm, with a diameter of a gas bellows D ₂ = 620 mm, its height will be 264 mm. In this case, the hydraulic bellows is designed for a working pressure of 20 MPa, gas - for 3 MPa. This size ratio ensured a convenient arrangement of these nodes and a sufficient volume of gas in the cavity of the bellows 10, providing a slight pressure drop when moving the bellows during the operation of the switch (about 15% when the bellows are completely moved by 50 mm).

 The performed calculation and design work showed that the ratio of the diameters of the hydraulic and gas bellows as 1 / (2 ... 3) provides acceptable ratios of heights of the bellows and a satisfactory ratio of gas and liquid pressures.

 The opening operation is as follows. When a signal arrives at the corresponding electromagnet (not shown) of valve 7, the latter, by moving the spool, opens the oil passage from the sub-piston cavity 17 to the drain tank. The piston 3 under the action of the pressure difference in the cavities 16 and 17 moves down, breaking the contact of the switch. The increase in the volume of the piston cavity 16 is compensated by the flow of oil from the cavity 14 of the hydraulic bellows 9. The latter will decrease, and the gas will increase in height by the same amount.

 In the off state, the piston 3 is held at the bottom due to the pressure difference on its upper and lower sides.

 To carry out the switching operations, the signal is supplied to the corresponding electromagnet, which transfers the valve spool 7 to the position providing high-pressure oil supply from the cavity 14 to the piston cavity 17. At the same time, high pressure acts on the piston 3 from two sides, however, due to the difference the area of the piston 3 will move upward, providing the closure of the contacts of the switch 1.

The stroke δ of bellows, which determines the high-pressure oil supply for performing on-off operations, is selected from the condition that the complete circuit breaker emergency protection cycle can be carried out in accordance with GOST 687 (0-t ₁ -BO-t ₂ -BO, where O is the trip operation , B - operation of switching on, t ₁ = 0.3 s and t ₂ = 20 s - dead times) without replenishment of oil in the hydraulic bellows 9 due to the pump. Such a choice of the compensating ability of the bellows ensures that the drive responds in emergency situations (short circuit on the power line, lightning strike) even if the booster system fails, which increases the reliability and quality of the drive.

Claims (3)

 1. HYDRAULIC ACTUATOR FOR A POWER HIGH-VOLTAGE CIRCUIT BREAKER, comprising a working cylinder with a piston and a rod for communication with the movable contact of the circuit breaker, an energy storage device made in the form of covers hermetically closed from the ends, one of which is movable, and filled with compressed gas bellows, a hydraulic accumulator, a control valve , pump unit and drain tank, characterized in that the accumulator is made in the form of a bellows filled with a working fluid located between the base of the working cylinder and the movable cover gas bellows, and the diameter of the bellows filled with liquid is 2 to 3 times less than the diameter of the gas bellows.  2. The drive according to claim 1, characterized in that the upper movable cover of the gas bellows is made with a concave surface forming a cavity in which the hydraulic bellows is placed.  3. The drive according to claim 1, characterized in that it contains stops that limit the movement of the bellows in tension and compression.