前苏联专利SU1289393A3 Oil-pneumatic device for controlling high-voltage switch

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专利摘要:
The image relates to the field of electrical engineering, in particular to oil-pneumatic control devices for a switch. The purpose of the invention is to increase the speed. The device contains a moving contact actuator in the form of a hydraulic cylinder 1 with a spring-loaded piston 2 connected to moving contact 3, a fixed contact 4, a high pressure tank 5 with a valve and power supply and cleaning system 6, a reduced pressure tank 21, the high-frequency side of which is connected to the main tank 5 pipeline 20 with the main pipeline 14, the ratio of the volumes of the main tank 5 and the tank 21 is 100-1000. A 06-valve valve 25 is installed in the additional pipeline 24. In the cleaning pipeline 27 of the unit 15, a delay valve 28 is installed. The additional tank 21 is designed as a housing with a spring-loaded diaphragm and a support plate. 5 hp f-ly, 4 ill. A i CO go
公开号:SU1289393A3
申请号:SU843743761
申请日:1984-05-28
公开日:1987-02-07
发明作者:Ален Гратцмюллер Клод
申请人:Gratzmueller C A；
IPC主号:

专利说明:

one
This invention relates to oil to swivel control devices for an electric switch.
The purpose of the invention is. fast speeds,
FIG. 1 is a schematic diagram of an oil-pneumatic control device for a switch equipped with a compensation system; in fig. 2 is a variant of the device, according to which the connecting pipe, installed between the control unit and the switch jack, is simultaneously a hydraulic command supply pipeline and a power transmission pipeline; Fig. 3 is a variant of the device, according to which the compensation system re-feeds the intermediate valves of the hydraulic circuit; in fig. 4 - compensating battery with a membrane and a spring section,
The oil pneumatic control unit for the electric switch contains a hydraulic cylinder 1 with a spring-loaded piston 2 for driving the movable contact 3 in the direction of the fixed contact 4, the main oil-pneumatic high pressure reservoir 5, the valve and power supply and cleaning system for the selective piston chamber 7 of the hydraulic cylinder 1, either with a low pressure chamber 8 in the off position of the switch (Fig. 1), or with a high pressure reservoir 5 to bring and hold in the key switch is in the on position. The spring-loaded piston is returned to the off position by means of permanent elastic means such as spring 9 or the elastic pressure of the high-pressure accumulator 5 supplied to the upper chamber 10 of the hydraulic cylinder by the pipeline 11 indicated in FIG. 1, with intermittent lines .
The power and cleaning system 6 comprises a hydraulic switch 12 for a power and cleaning valve, which brings the valve switching body 13 to a position where high hydraulic pressure is applied to it via the main pipe 14, and returns the switching body 13 to the cleaning position shown in FIG. 1 continuous
one
89393 .2
By lines, the cat and the pumper are no longer supplied with a low pressure. The device also contains, according to the usual pattern, command command post 15 5, called an operating unit, which can be located at a distance from the switch and which contains an activation solenoid 16 and an off solenoid valve O 17 that controls the switching of valve 18,
The valve 18, in the position shown by continuous lines, connects to the low-pressure chamber 19 a connecting pipe 14 installed between the operating unit and the valve system 6, while in a different position of the valve 18 the pipe 14 is connected 20
c to high pressure supplied
either an auxiliary battery, provided for in the operating unit, or a main battery, 5, connected to the operating unit via pipeline 20,
The operation of such a device is well known and it is sufficient to recall that in the case shown in FIG. 1, pipeline 14, which may be
a large length, is only a command supply pipeline. A pressure supply or a pressure shut-off, while a large-capacity hydraulic power required to power the hydraulic cylinder 1 is supplied directly by the main accumulator 5,
To bring the switch to the on and off position
in this position, high pressure is supplied to the pipe 14 from the main tank 5, for example, of the order of 200-400 bar. To bring the switch to the off position
pipe 14 is brought to the cleaning position at atmospheric pressure. During this operation, the pressure of the oil contained in pipe 14 decreases as it was
it is indicated that, at least part of the pipeline 14 is left without oil or is filled with emulsion oil,
If the next activation command by applying pressure to the pipeline 14 is given in a short time, the pipeline 14 behaves as if it is filled with an elastic fluid.
3
although the response delay of switch 12 will be significantly increased and will vary from one operation to another,
The device provides a reduced pressure tank 21 of the high-precision side of which is connected to the main tank 5 via a pipeline 20 and which through its outlet 22 supplies a reduced pressure. The device also contains an additional reduced pressure tank 23, which is charged by the reduced pressure oil through a regulator and which is connected via line 24 to the pipeline 14,
A check valve 25 installed in the additional pipe 24 prevents the high pressure in the pipe 14 in the on position of the switch from entering into the low pressure section of the hydraulic circuit.
Preferably, the auxiliary piping 24 is connected to the piping 14 adjacent to the upper end section 26 of the latter, if we consider the oil mixing when the circuit 14 moves from the By-to-to-to-Free position, while this end portion 26 is most susceptible to oil shortage,
In this connection, the conduit 14, which is partially without oil (or filled with emulsion oil) when the pressure is turned off, is quickly replenished with oil in a liquid state under reduced pressure by means of an additional reservoir 23 of reduced pressure, which is immediately charged with oil through regulator 21,
In the off position, the reduced pressure tank 23 and the controller 21 could not continuously supply oil, in the cleaning line 27 of the operating unit 15, a delay valve 28 adjusted to a pressure, slightly exceeding the system pressure, is provided.
In this case, it is possible to provide several identical blocks of the reduced pressure reservoir regulator to feed several points of the hydraulic circuit most susceptible to
89393 4
lack of oil or the presence of emulsion oil, also from a single such unit to feed several points of the hydraulic circuit. g The volume of sections of the hydraulic circuit in which oil is present at the moment of shutdown of pressure is relatively small, therefore it is sufficient to have a reservoir of reduced pressure of a small capacity, for example, from a few cubic centimeters to several tens of cubic centimeters 1000 times smaller than the capacity of the main re-t5 tank 5).
Moreover, it is noted that it is enough to have a small reduced pressure in order to feed areas that turn out to be without oil. Therefore, for an additional reduced pressure tank 23 and for the regulator 21, it is sufficient to provide a reduced pressure in the order of 2 to 10 bar, while a high pressure in the tank 5
25 is in the order of 200-400 bar.
In this case, it is necessary that the compensating battery 23 has a small inertia in order to quickly compensate for the lack of oil. Here is
30 why, as shown in FIG. 4, it is preferable to choose a battery with a membrane with a small stroke, while the mechanical spring is acting on the membrane by means of a support plate that is installed opposite the membrane.
FIG. 2 shows a hydropneumatic control system for a switch that contains such
40, the same basic elements as the system shown in FIG. 1, but in which the pipeline 14 connecting the operating unit 15 to the power supply and service valve 6, is not only 45 to the command supply line to the valve 6 (set in position Under pressure or without pressure), but also serves as a piping for powering the working chamber 10
0 hydraulic cylinder 1,
As an example, for valve 6, a valve of a known type is shown, called a quick cleaner, in which section 12, which forms the pore 5 shade of cleaning valve 29, is a hydraulic switch of valve 6.
The block containing the regulator 21 and the reservoir 23 reduced pressure
is identical to the unit shown in FIG. 1, and is preferably connected to the pipeline 14 via a pipeline 24 extending into the upper part 26 of the pipeline 14,
In addition, it is possible to provide a safety valve 30 connected to the portion of the hydraulic circuit 22. This safety valve is adjusted to a pressure slightly higher than the system pressure and protects the unit from any abnormal overpressure, for example in case of leakage in the non-return valve 25.
It is well known that in hydraulic control circuits for switches, end valves for supplying and cleaning hydraulic cylinders that have a large cross section are not directly controlled (as shown for simplicity in FIGS. 1 and 2), using several master valves and incremental intermediate valves section.
These driver valves and intermediate valves are included in the hydraulic command supply circuit, and at least some of the chambers they have are also subject to the circulation of emulsion oil or oil-free volumes. As with the pipelines shown in FIGS. 1 and 2, during the start-up operation, there is a shortage of oil or the appearance of emulsion oil in some areas of these intermediate valves or control valves, which negatively affects the response rate at the moment pressure is turned on.
Therefore, it is preferable to feed the reduced pressure oil with at least some of the chambers of these valves,
Fig. 3 shows the main elements of a conventional oil-pneumatic control device, similar to the device shown in Fig. 1, in the sense that the pipeline 14 connecting the operation unit 15 with the supply valve 6 and cleaning the hydraulic cylinder 1 It is only a command supply pipeline (Under pressure or Without pressure). Power supply with a large flow rate of the hydraulic cylinder 1 is provided mainly by the accumulator 5. As the power supply and cleaning valve 6, a conventional valve is shown, 89393 6
holding independent supply valves 31 and a cleaning valve 32, the hydraulic switch 12 of the valve being
5 piston valve section 32 cleaning.
FIG. 3 also shows the high pressure auxiliary reservoir 5 supplying the operation unit 15, the two batteries being connected together.
10 under pressure equilibrium conditions through conduit 33 with a small flow rate (shown in broken lines in FIG. 3) and charged in the usual way by
15 pump (not shown).
This control system typically contains intermediate valves 34,
This intermediate valve 34 has an inlet 35 of high pressure, outlet 36
A high-pressure connection 20 connected to a junction pipe 1-4, a cleaning outlet 37 and a control inlet 38 connected via a connecting pipeline 14 to an operating
25 by block 15, the valves 39 for supply and cleaning of valve 34 are controlled by a piston of a hydraulic cylinder 40,
The block containing a 2: 1 regulator and a reservoir 23 of reduced pressure,
30 is connected via pipe 24 to the cleaning chamber 41 of the intermediate valve 34. Upon a command to turn off the solenoid 17, the power supply valve 18 and the cleaning of the operating unit 15 are set to the cleaning position, shown by continuous lines. In this case, since the piston of the hydraulic cylinder 40 is no longer under pressure, the cleaning valve 39 opens and cleans the chambers 41 and the pipe 14. The pressure drop and oil circulation in these tanks leads to the appearance of an oil shortage and
45 emulsions. Block 21-23 immediately and directly feeds the intermediate valve chamber with oil and pipeline 14, thus ensuring a normal response time to the next 50 switching order.
A retention valve 23 adjusted to a pressure greater than the system pressure is provided in the purification pipe 24 connected to the pipe 24 connecting the unit to the intermediate valve chamber 34,
As can be seen from FIG. 3, the chamber 41 is never affected.
high pressure, as in the on position, the valve 39 closes and isolates the chamber 41. That is why in this embodiment there is no check valve in the pipe 24, similar to the check valve 25 in FIGS. 1 and 2,
The advantage of this option is that the reduced pressure tank 23 is recharged not only by the regulator 21, but also partially recharged by the cleaning oil supplied as the pressure in the pipe 14 decreases during each shutdown operation,
If there are one or more other brass weft valves, for example, in the operating unit 15, in place of the schematically shown simple valve supply and cleaning, the chambers of these intermediate valves, equivalent to chamber 41, can also be fed with system pressure oil from another compensating unit 21- 23 or from the block shown in FIG. 3,
It should be noted that block 21-23 is also valid for extended periods of shutdown in the off position, during which any possible return of air is prevented by the supply of oil under reduced pressure from the specified block. In this way, the timing of the response after the first power up operation is ensured.
The compensating accumulator 23 (Fig. 4) with a small capacity of the reduced pressure tank contains a variable-volume oil storage chamber 42, which is closed by a sealing membrane 43 interacting with the spring 44, with the installation of the support plate 45. Coupling sleeve 46, exit The conduit 42 is connected to the connection pipe 24 (FIGS. 1-3). Purifier 47 is also provided to remove air at the first filling. Such a battery has a small inertia, since the overall course of the membrane is. Here, 43 is, for example, 5-10 mm with a membrane surface of 20-40 square centimeters, i.e. tank capacity of about 10-40 cubic centimeters. Thanks small
25
89393 8
inertia provides a very fast compensation of vacuum volumes or volumes filled with emulsion
oil
five

权利要求:
Claims (6)
[1]
1. An oil-pneumatic control device for a high-voltage circuit breaker containing a podO drive of a viscous contact in the form of a hydraulic cylinder with a spring-loaded piston, a sub-piston cavity of which is connected to a cleaning valve connected to a main oil-pneumatic reservoir, to a low-pressure chamber and hydraulic a switch, a control unit connected through a pipeline to the indicated hydraulic switch, and a low pressure rotary controller connected to the main oil-pneumatic switch The tank is equipped with an additional reservoir of reduced pressure, connected through an additional conduit to the main conduit, in order to improve speed.
[2]
2. A device according to claim 1, about 1 ton and 30 such that the ratio of the volumes of the main oil-pneumatic reservoir and the additional reservoir of reduced pressure is 100-1000.
[3]
35 3. The device according to PP. 1 and 2, that is to say that it is equipped with a check valve connected to the Additional reservoir of reduced pressure and the main pipeline.
[4]
4. The device according to PP. 1-3, characterized in that it is provided with a delay valve installed in the control unit.
[5]
45 5. The device according to PP. 1 and 2 or 4, characterized in that it is provided with an intermediate valve installed in the main pipeline, and an additional reservoir of reduced pressure is connected to the chamber of this valve,
[6]
6. The device according to PP. 1-5, about t - the fact that the additional reservoir of reduced pressure55 is made in the form of a housing with a spring-loaded membrane and a support plate.
- H
.2
ilr
figs
47
Editor V. Danko
Compiled by V. Popov
Tehred I. Popovich Corrector T. Kolb
Order 7826/60 Circulation 721 Subscription
VNIIPI USSR State Committee
for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab. D. 4/5
Production and printing company, Uzhgorod, st. Project, 4
CPU g A

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引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

US2920607A|1956-12-17|1960-01-12|Gen Electric|Hydraulically-actuated operating mechanism for an electric circuit breaker|

DE1238335B|1957-10-23|1967-04-06|Jean Louis Gratzmuller|Hydraulic remote control device|

US2977762A|1957-12-09|1961-04-04|Gen Motors Corp|Hydraulic governor pressure control mechanism|

FR76484E|1959-11-03|1961-10-20|Comp Generale Electricite|Method of oleopneumatic control of electrical apparatus and application to a circuit breaker|

FR1311326A|1961-10-25|1962-12-07|Alsthom Cgee|New provisions concerning hydropneumatic or hydraulic controls of electrical circuit breakers|

FR84825E|1963-10-25|1965-04-23|Comp Generale Electricite|Method of oleopneumatic control of electrical apparatus and application to a circuit breaker|

FR1482883A|1966-02-28|1967-06-02|Hydraulic relay|

DE2235074B2|1972-07-12|1979-05-17|Siemens Ag, 1000 Berlin Und 8000 Muenchen|Hydraulic actuator for an electrical switch|

US4213020A|1977-10-26|1980-07-15|Westinghouse Electric Corp.|Pneumatic operating mechanism for a circuit-breaker|

FR2422245B1|1978-01-04|1982-04-16|Gratzmuller Claude|

DE2828958A1|1978-06-28|1980-01-10|Siemens Ag|Hydraulic actuator for HV power switch - has energy storage piston controlled by spring loaded hollow needle|

DE3019626C2|1980-05-22|1984-06-20|Kraftwerk Union AG, 4330 Mülheim|Electro-hydraulic actuator for valves|

US4463818A|1982-09-07|1984-08-07|Applied Power Inc.|Tilt cab truck in which the cab is partially supported by the tilting cylinder while in the drive position|US4785712A|1986-05-27|1988-11-22|Mitsubishi Denki Kabushiki Kaisha|Hydraulic operating apparatus for electric circuit breaker|

CH684969A5|1991-09-06|1995-02-15|Secheron Sa|A control device actuated by a pressurized fluid in particular for closing and opening the contacts of a circuit breaker.|

CA2127744A1|1993-07-20|1995-01-21|George P. Kokalis|Hydraulic closed loop control system|

JP2015041555A|2013-08-23|2015-03-02|株式会社日立製作所|Fluid pressure driving device for circuit breaker|

KR101515216B1|2014-11-19|2015-04-24|토피도 티엔에이|Sylinder for jumbo hydraulic breaker|

RU2648266C2|2016-09-12|2018-03-23|Геннадий Феофанович Мамарин|Hydraulic drive for a power high voltage switch|

法律状态:

优先权:

申请号 | 申请日 | 专利标题

FR8308910A|FR2547108B1|1983-05-30|1983-05-30|OLEOPNEUMATIC CONTROL FOR ELECTRIC CIRCUIT BREAKERS|

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