PL157464B1 - Apparatus for automatically maintaining pressure in hydraulic props of self-advancing roof supports and regulating initial load supporting value of such pressure - Google Patents

Abstract

A device for self maintenance of pressure in hydraulic props of powered roof supports and for adjustment of initial support pressure, distinctive in that it consists of two slidable two-way hydraulic manipulators connected in a series and mounted on a common block (25); the block is linked with an under-piston chamber (3) through the permanently open manipulator (2) which can be closed with liquid fed by pressure to a chamber (10) of a shifter (11); the liquid causes a roof support section to advance towards a longwall face; the device is also equipped with a check valve (18) placed between the prop controlling manipulator (16) (4) and the prop valve block (17); this valve checks the flow of liquid from the manipulator (16) to the prop block (17); situated perpendicular to the check valve is a permanently open manipulator (15) that can be closed by pressure of liquid from the pipeline (19) linking the manipulator (16) with the prop block (17); the liquid reaches the manipulator (15) through a throttle/check valve (20).<IMAGE>

Description

The subject of the invention is a device for self-maintaining pressure in hydraulic props of a powered support and for adjusting the pressure of the initial support of the support, equipped with a system enabling the change of the flow rate of the liquid supplying the props, and adapted to move the support in contact with the roof.

Devices and valves for self-maintaining a certain pressure in the hydraulic props of the powered support, called devices for charging the props, ensure equal initial support for all support sections in a given longwall working and supplement liquid losses in the spaces under the pistons. In order for the casing with such devices and valves to function properly ^ without endangering the crew working in the longwall excavation, these devices must meet certain conditions: The device must ensure regulation of the flow rate of the liquid supplying the casing stands in the range from a dozen to several liters per minute: it must self-actuate exclude from the hydraulic system the damaged stand, from which the leakage of liquid occurs with a intensity greater than the allowable one; must ensure adjustment of the pressure of the initial support of the housing in the range from a few MPa to the maximum pressure in the pressure maagstral of the housing; must ensure safe sliding of the casing section in contact with the ceiling.

Devices and valves with high liquid flow rate cause water hammer in the final phase of filling up the hydraulic medium / charging / in the hydraulic stand. These impacts are transferred through the stand and canopy to the roof of the excavation, causing it to crack and destroy. If the device does not automatically disconnect the damaged stand from which the hydraulic medium is leaking from the hydraulic system, then the pressure of the liquid in the pressure housing drops in the hydraulic system, there are losses of the hydraulic fluid and the load of the pump feeding the housing.

Typically, a pressure balance, a liquid, is supplied to the housing at a pressure of 31.5 MPa or 25 MPa. In the case of weak and medium strand rocks, this pressure is too high as the pressure of the initial support of the casing, causing cracking and breaking of the roof. Such a situation can be prevented by a reduction in the pressure of the initial support of the casing, if the device for replenishing the pressure in the racks / for charging the racks / has the ability to adjust this support.

A device capable of disconnecting a leaky prop from the hydraulic system must be controlled to some extent by pressure from the plunger space of the prop. During the time when the lining section is moved in contact with the longwall working section, dynamic pulses act on the canopy, causing pressure surges of the liquid located in the spaces under the racks. Such a sudden increase / impact / pressure may cause snm ^ (^^ yene activation of the rack charging device while moving sections of the casing, which causes serious damage to the ceiling and creates a very dangerous situation in the longwall excavation. The rack charging device must be designed in such a way that did not allow this kind of threats.

The currently imported Voss rack supercharger, consisting of a valve assembly, does not meet any of the above requirements. These high-flow devices? liquid, I cause the formation of water hammer acting dynamically on the ceiling. They do not protect the hydraulic system of the housing against leaks exceeding even 20 ΙΗγΜι. and they turn on actively when the support section is moved in contact with the ceiling.

The Hans Berger Messiechnik GMBH device, imported from the dollar zone, causes water hammer and does not protect the hydraulic system of the housing against leaks of twice high flow rates. Moreover, both of these imported devices do not provide the possibility of regulating the preload pressure of the casing and cause the destruction of ceilings composed of weak and medium rock layers.

Devices for maintaining constant pressure in hydraulic systems, known from the applications P.267948, P.268199 and P.268861, registered in the Patent Office, have the ability to regulate the pressure of the initial support of the housing and protect the hydraulic system of the housing against leaks, but they are not adapted to move the sections casing in contact with the roof of the excavation.

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All these disadvantages of the aforementioned devices have been overcome thanks to the development of a device for self-maintaining pressure in the hydraulic props of the housing and for adjusting the pressure of the prestress of the housing according to the invention.

This device consists of a valve for charging the casing stands, equipped with a system for regulating the initial support pressure, connected to the space of the pillar's piston through a constantly open distributor / z ^ a ^ and ^ r / two-way, closed liquid under pressure supplying the space of the section shifter, which causes movement / shifting / sections towards the face of the longwall working. In addition, the device includes a constantly open manifold / valve / two-way, connected in series between the rack control manifold and the rack valve block, closed with the liquid under pressure from the conduit connecting these two elements, the liquid closing the manifold / valve / two-way flows to it through the throttle check valve. Parallel to the two-way manifold, between the rack control manifold and the rack valve block, a check valve was connected to close the flow in the direction from the V and stator control manifold to the rack valve block.

A variant of the device consists of a two-way slide manifold, fixed on one side by pressure from the piston space of the stand, and on the other side by a spring and a pressure of liquid supplying the shifter space to the section, generating a force to move the housing to the face of the wall, instructed with a pressure reducing valve equipped with a system for regulating the flow rate of a liquid from a permanently open two-way manifold / valve / two-way manifold connected in series between the manifold controlling the station and the rack valve block, closed by pressure from the connecting conduit, the manifold controlling the racks with a valve block. The same valve is connected to this manifold / two-way valve, between the rack manifold and the rack valve block ^^, a non-return valve passing the liquid in the direction from the valve block to the rack manifold. The liquid under pressure closing the manifold / valve / two-way valve is fed to it through the throttle-check valve, which protects it against water hammer.

The subject of the invention is shown in an exemplary embodiment in the drawing, in which Fig. 1 shows the hydraulic diagram of the device mounted on the housing section, Fig. 2 - cross-section of the rack boost valve, with the control system for the initial support of the housing, the basic component of the device, Fig. 3. hydraulic version of the device with a rack boost valve equipped with an additional, hermetic chamber connected hydraulically with the housing flap shifter system, fig. 4 - a cross-section of an additional hermetic boost valve chamber, equipped with a piston blocking the valve spool and containing a valve opening indicator, fig. S - version alteonasw * oą in cross-section, additional hermetic boost valve chamber, with JiέninnCowyn blocking the valve spool, equipped with a valve opening indicator, and fig. 6 - another alternative version, in cross-section of an additional hermetic boost valve chamber, without valve actuation indicator, in which the spool valve is locked with spring and liquid under pressure and dc supplied from the hydraulic system of the shifter section

The device for self-maintaining pressure in the hydraulic props of the powered support and to the rules of initial pressure of the support, consists of a boost valve 1 / Fig. 1/ of the props, the connection A of which is connected via a hydraulic conduit a and a constantly open manifold / two-way valve / 2-way, with a piston rod space 3 of the hydraulic stand 4. Port B of the boost valve 1 was connected through the conduit b and the shut-off valve 5 with the pressure pipe 6: the entire housing. The C port of the valve 2 is connected with the line c with the line 7 connecting the manifold 8, through the non-return-controlled valve 9, with the space 10 under the piston of the slider 11 of the housing section. Slider 11, through the piston rod 12 and the beam 13,

It is connected to the wall conveyor, and through the creatures 14 to the casing.

In this system, t ^ 2 ^ w. Inversion in the space 10 under the piston of the slider 11 A force is generated which moves the casing section towards the face of the wall. A two-way manifold / valve / 15, permanently open, is installed between the manifold 16 and the 17-valve manifold. In parallel to the manifold 15, a check valve 18 is installed, which enables the liquid to flow in the direction from the stand-up valve block 17 to the manifold 16. The two-way manifold / valve / 15 is closed with a pressurized liquid supplied to it from the conduit 19 through

157 454 20 throttle-check valve. The valve 20 counteracts the influence of water hammer on the control of the valve shaft / valve / 15, and the valve 18 allows the liquid to drain from the space 3 under the piston of the stand 4 when the manifold / valve / 15 is closed. Valve 2 is constantly open and consists of a piston 21 connected to a stator 22 which closes the opening 23 when the fluid under ^ έηίβπ ^ πι is introduced into the space 24. This fluid exerts pressure on the piston 21.

The rack boost valve / fig. 2/ consists of a body 25 in which two sleeves 26 and 27 with a slider 28 are placed. One longitudinal opening 29 and two rows of circumferential openings 30 and 31 are made in the slider 28, by means of which the hydraulic connection between com ^ d ^^ 32 and 33 and is interrupted. The chambers 32 and 33 were sealed against each other with gaskets 34 and 35 embedded in the sleeve 26. The chamber 33 was connected with the valve port B, and the chamber 32 with the chamber 36 by means of an opening 37. At the end of the spool 28 ending in a head 38, a hermetic chamber 39 was made connected by an opening 40 with space 41 housing the spring 42 for adjusting the bias of the housing. At the opposite, cylindrical end of the spool 28, a non-sealed chamber 43 is made, in which the indicator 44 of the valve opening / valve activation / ended with a plug 45 pressed by a spring 46 against the spool 28 and sleeve 26. Οάροηίβάη ^ the thickness of the washers 47 controls the spring force 46 and the pressure opening the valve / moving the slider 28 to a position in which chamber 32 is connected to chamber 33 /. Indicator outlet 44 is covered with rubber caps 48 to protect chamber 43 from contamination. A sleeve 49 is placed between the chamber 36 and the space 41, connected by a shoulder 50 to the sleeve 51. A slider 52 provided with a longitudinal opening 53 and peripheral openings 5A passes through both these sleeves 49 and 51. A pin 55 is placed in the longitudinal hole 53, the diameter of which regulates the flow rate of liquid through the hole 53. The larger the diameter of the pin 55, the lower the flow of liquid through the hole 53. The spool 52 is sealed by a seal 56 against the sleeve 51 which is sealed with a seal 57 against body 25. The spring 42 presses the plug 58 against the spool 52 and the sleeve 51. the screw 59 adjusts the force of the spring 42 pressing against the plug 58. The position of the bolt 59 is fixed / counter-tightened by a nut 60. The space 41 is connected to the valve port A, the bolt 59 is sealed against the sleeve 61 by a gasket 62 and covered with a rubber cap 63. The sleeves 26 and 27 are pressed together by a plug 64 and a cap 65 threaded into the valve body 25, and the sleeves 49 and 51 are compressed between the sleeve 61 and the plug 66 connected together also with threads to casing 25. The hydraulic connections to ports A and B of valve 1 are shown in fig.

The variant of the device shown in Fig. 3 consists of the rack charging valve 1 equipped with three connectors A, B, C, of which the connection A is connected with a cable and the connection 2 of the space 3 underneath the rack 4, connection B - through the cable b and the shut-off valve 5 with the mainstream 6 is closed to the casing, and the port C is connected with the conduit c by the conduit 7 of the manifold 8, through the valve 9, connected to the piston space 10 of the shifter 11 of the casing section. The shifter 11, through the piston rod 12 and the beam 13, is connected to the wall conveyor, and through the pin 14 - to the bottom of the housing, Two-way distributor / valve / 15, open steel, installed between the divider 16 and the second block 17 valve. At the end of the manifold / valve / 15 there is a check valve 18 which allows the liquid to flow in the direction from the stand 17 valve block to the manifold 16. The two-way distributor / valve / 15 is closed with a liquid under pressure supplied to it from the line 19d through the throttle valve 20 - returnable.

The valve 1 for recharging the rack, in place of the water in the chamber 43 / fig.2/, has a hermetic chamber 43 / fig.4, fig.5 and fig.6 / connected to port C and sealed with gaskets 67 and 68. In the version shown in fig. .4 the poppet 45 of the valve opening indicator 44 is sealed by a gasket 69 against the cap 65, and the cap 65 is sealed by a gasket 70 against the valve body 25. Peripheral holes 71 are made in the cap 65. In the version shown in FIG. 5, a spacer sleeve 72 is mounted on the plug 45. In the line shown in Figure 6, the valve opening indicator 44 has been centrifuged, leaving only the poppet 45.

The device for self-maintaining pressure in the hydraulic props of the powered support and for adjusting the pressure of the pre-load support of the support, according to the invention, functions as follows.

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While the casing is propped up under the ceiling, the liquid under pressure from the plunger space / fig. 1/ of the stand 4 acts through the open manifold / valve / 2, conduit a, port A of valve 1, space 41 / fig. 2/ and an opening 40 at the end of the slide 28 extending into the chamber 39, keeping it in a position in which the mosquito 32 is connected to the chamber 33. The liquid from the maggstral 6 of the pressurized housing flows through the shut-off valve 5 (Fig. 1/), line b and port B, into chamber 33 / Fig. 2/ in sleeve 27 and from there through openings 31, 29, 30, chamber 32 and opening 27, into chamber 36, where it exerts pressure on the slide 52. If space 41 is under pressure less than that set by spring 42, the spring is deflected and the slider 52 moves towards the screw 59. When the circumferential holes 54 pass the gasket 56, fluid flows through the holes 53 and 54 from the chamber 36 into the space 41 and further through port A, conduit a, conduit a /fig.1/, valve 2 and conduit d, to the plunger space 3 of the stand 4. When zeni 41 / Fig. 2/ and the space 3 of the stand 4 / Fig. 1/ the liquid reaches the pressure set by the spring 42, this spring pushes the slider 52 into the sleeve 51, into one original position, the circumferential openings 54 in the slider 52 are again outside gasket 56 and the flow of liquid through the opening 53 stops. This condition is characterized by the equation:

where ^ρ 35

P41 ^p 36 pressure of the liquid in the chamber and the pressure of the liquid in the chamber ^P 41

36,

41.

spring force 42, D - spool diameter 52.

The pressure pg is simultaneously the pressure of the liquid contained in the maaistrall of the pressurized housing, and the pressure p ^ is the pressure of the initial support of the housing. By tightening the screw 59, the spring pressure on the poppet 58 increases, and at the same time the pressure difference between the chamber 36 and the space 41 increases, i.e. the pressure of the initial support of the housing / is decreased.

If the flow rate of liquid through hole 53 is too high, then the surface area of flow through hole 53 is reduced by inserting pin 55 into it. The flow rate through hole 53 is particularly important because of liquid leakage that occurs when stand 4 / Fig. 1 / breaks and loses its tightness. Thus, when the leaks in the rack reach the pressure set by the pin 55, in the opening 53, the pressure drops in the spaces 3 and 41 and in the chamber 39, and the spring 46 pushes the slider 28 into the sleeves 26 and 27 and the chamber 39. As a result, circumferential the openings 30 pass the gasket 35 breaking the connection between the chambers 32 and 33. In this way, the damaged stand is isolated from the hydraulic boost system and the leakage of the liquid stops. When the pressure of the liquid in the spaces 3 and 41 rises above the preload pressure of the housing, the slider 52 is pressed against the plug 66, still separating the space 41 from the chamber 36.

The device variant shown in Figures 3 to 6 operates identically while the casing is pushed under the ceiling.

During the robbery of the casing, the liquid under pressure flows from the pressure steel 6 of the pressure casing / Fig. 1/, through the distributor 16, conduit i, to the stand of the valve block 17, and then via conduit f to the stand 4 above its piston, and from the space 3 of the piston rack 4, the liquid flows through the conduit d, through the pedestal valve block 17, conduit 19d, valves 15 and 18, conduit 19 and the manifold 16 to the outflow housing. In the spaces 3 and 41 and in the chamber 39 the pressure of the liquid drops and the spool 28 (fig. 2/ is moved by the spring 46 towards the plug 64), closing the flow through the valve 1 (fig. 1/). Rack topping is automatically disabled.

The device variant shown in Figs. 3 to 6 operates identically when robbing the casing.

When the casing section is moved in contact with the ceiling, the canopy slides on the ceiling surface, and 11 casing sections are supplied to the space 10 / Fig. 1/ under the piston of the shifter from Reage 6, through the distributor 8, the conduit 7 and the check valve 9, pressurized liquid. At the same time, this liquid flows through line c to port C and into the space 24 of valve 2. This liquid forces the piston 21, driving the cone 22 into the hole 23, which closes the flow through the valve 2. When seccc! the canopy catches on unevenness

157 464 of the ceiling, in the space 3 under the piston of the stand 4 there are sudden, temporary increases in pressure / water hammer /, which would activate the boost system in valve 1. However, the closed valve 2 does not allow these water hammers to valve 1, blocking the rack boost system, which allows for safe sliding of the housing section. Upon completion of the displacement of the housing section, the valve space 24 (Fig. 1/) is connected via port C, line c, line 7 and distributor 8 to the housing drain maagitral M. This causes the pressure in the space 24 to drop and the opening 23 to open by the spring S of the valve 2.

The variation of the device shown in Figs. 3 to 6, while the casing section is moved, works similarly. The liquid from r ^ age ^ al ^ 6, flows through the manifold 8, line 7 and the check valve 9, also flows to port C of valve 1.

In the version shown in Fig. 4, this liquid enters the hermetically sealed chamber 43 through openings 71, where it presses against the plug 45, blocking the movement of the slide 28, which it tries to make under the pressure impulse initiated in the space 3 (Fig. 3). stand 4 as a result of hooking the canopy to the unevenness of the ceiling. Since the surface of the mushroom 45 is much larger than the cross-sectional area of the slider 28, it can successfully counteract any possible, significantly higher pressures generated in the space 3 of the stand 4, all the more so as the spring 46 force helps it block the slider 28.

In the version shown in FIG. 5, the pressurized fluid, fed through port C and openings 71 into the hermetic chamber 43, presses against the cross-sectional area of the spool 28 and the valve opening indicator 44. Under the pressure of this fluid, the indicator 44 moves in the cap 65 by pressing against the rubber cap 48. The spacer sleeve 72 prevents the indicator 44 from unduly slipping from the cap 65. By pressing against the cross-sectional area of the slider 28, the pressurized liquid presses the slider against the stopper 64 / fig. .2 / and locks it in this position. Possible water hammer in the space 3 of the stand 4, caused by hooking the canopy to the ceiling, I cannot turn on the valve 1 / Fig. 1/ and start the rack charging system.

In the version shown in the exemplary embodiment in Fig. 6, the liquid under the Jiśiieni, fed through the conduit c, through the connection C and the holes 71, to the hermetic chamber 43, presses against the cross-sectional area of the slider 28, pressing the slider against the plug 64 (Fig. 2). If the pressure in the space 3 of the stand 4 / Fig. 3/ and the mosquito 39 / Fig. 2/ increases, due to the canopy catching on the unevenness of the ceiling, to a value greater than the value of the liquid pressure in the chamber 43 / Fig. 6/, the spool 28 will be moved to contact with the poppet 45. In this situation, on the one hand, the pressure of the liquid from the chamber 39 / Fig.2/ acts on the spool 28, and on the other - the pressure of the liquid from the chamber 43 / Fig. 6/ and the force of the spring 46. This condition can be expressed by the equation:

. 5T. d ² + P.

p39 where: p ^ g - liquid pressure in the chamber 39 / fig. 2/, p ^ g - liquid pressure in the mosquito 43 / fig. 6/,

- force of spring 46 pressure on the poppet 45 / Fig. 6/, d - diameter of the slider 28.

By appropriately increasing the pressure force of the spring 46, by selecting the appropriate thick washer 47, it is possible to protect the rack boost system against large, possible water shocks, in the space 3 under the piston of the rack 4, occurring during the movement of the housing section in contact with the ceiling.

After the operation of the sliding of the housing section has been completed, the hermetic chamber 43 / fig. 4, fig. 5 and fig. 6 / is connected through openings 71, port C, cable c / fig. 3/, line 7 and splitter 8, with the outlet M bus. housing and the lock of the slider 28 is completed. The pressure in the hermetic chamber 43 is about the atmospheric pressure.

When expanding the housing under the foot from the main line 6 / Fig. 1/ of the pressure housing, through the manifold 16, conduit 19, manifold / valve / 15, conduit 19d, stand 17 valve block and conduit d, the liquid under pressure is supplied to the space 3 under the piston of the stand 4. This fluid also flows through valve 2, line a, port A, space 41 / fig.2/ and opening 40, into chamber 39, where the pressure on the spool 28 is equal.

157 464, the chamber 39 reaches the value set by the spring 46, the spring bends and the slider 28 is pushed into the sleeves 27 and 26 until the head 33 rests against the sleeve

27, connecting chambers 32 and 33. Thus, valve 1 / Fig. 1 /, which is indicated by the valve opening indicator ul / Fig. 2 / by pressing on the rubber cap 48 «The distributor / valve / 15 / figd / is adjusted so that it closes at a pressure slightly higher / 1 to 2 MPa / from the opening pressure of the valve 1. The distributor / valve / this 15 is closes by itself ^ (^; ^^ no ^: ie the pressure of the liquid that flows to it from the line 19 through the throttle-check valve 20. After the manifold / valve / 15 is closed, further pressurized fluid inflow into space 3 of the stand 4 takes place through the supercharging system, i.e. from mainland 6 through cut-off valve 5, line b, port B of valve 1, chamber 33, holes 31, 29 and 34, chamber 32, hole 37, chamber 36, holes 53 and 54, space 41, port A , conduit a / fig.1/, valve 2 and conduit d In this way, regardless of the will of the person / operator / casing operator, liquid can flow into the piston space 3 of the stand 4 when its pressure in this space / 3 / reaches the value set by the spring 42 and the screw 59. After the liquid reaches this pressure value in pr 3 of the stand 4, the slider 52 is moved towards the plug 66 and the flow through the valve 1 ceases and the stand 4 obtains a predetermined bias. Despite the still open manifold 16, no liquid enters the rack 4 from the pressurized housing. After connecting / switching / divider 16, the line 19 is connected to the drainage system M, and the fluid drains from the control system 15 through the throttle-check valve 20, and then the divider / valve / 15 opens.

The variant of the device shown in Figs. 3 to 6 operates identically during the expansion of the casing under the ceiling.

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48 44 68 47

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Fig.1

Department of Publishing of the UP RP. Circulation of 90 copies

Price PLN 5,000.

Claims (5)

Patent claims 1. A device for automatic pressure maintenance in hydraulic props of a stacked housing and for regulating the pressure of the initial load of the housing, characterized by the fact that it consists of two series-connected two-way hydraulic slide distributors, assembled in a common block / 25 /, space / 3 / podtłokowa stand / 4 / by means of a separator / 2 / constantly open, closed with liquid under pressure supplying space / 10 / shifter / 11 /. which causes the movement of the support section towards the face of the longwall working, while the valve / 18 / blocking the flow of the liquid from the distributor / 16 between the gap / 16 / steering rack / 4 / and the valve block / 17 / valve block / 18 / / to the stand-up valve block / 17 /, and parallel to this valve / 18 / the check valve has a constantly open manifold / 15 /, closed by the pressure of the liquid from the conduit / 19 / connecting the manifold / 16 / with the valve block / 17 /, which the liquid flows to the manifold / 15 / through the valve / 20 / throttle-return. Device according to claim 1, characterized in that the slide / 52 / of the block / 25 / is seated simultaneously in two sleeves / 49 and 51 /, connected to each other by means of a shoulder / 50 /, under which a seal / 5> 6 is sealing a slider / 52 / in relation to the sleeve / 51 /, and a pin / 55 / is loosely mounted in the opening / 53 / of the slider / 52 /, with the size of the diameter of which the liquid flow rate through the longitudinal opening / 53 / in the slide / 52 / is adjusted. Device according to claim 1 or 2, characterized in that the slide / 28 / of the block / 25 / is placed in two sleeves / 26 and 27 /, one of which / 26 / is in the frontal plane adjacent to the other sleeve / 27 / , two seals / 054 and 35 / sealing this sleeve /2.6/ against the slide / 28 / and the body / 25 / valve / 1 /. Device according to claim 3, characterized in that the slider / 28 / has a longitudinal opening / 29 /, blinded at one end, and two rows of circumferential openings / 30 and 31 /, connecting the circumference of the slider / 28 / with the longitudinal opening / 29 / one row of holes / 31 / in each extreme position of the slider / 28 / is connected to the chamber / 33 / sleeve / 27 / filled with pressurized liquid, and the other row of holes / 30 / in one extreme position of the slider / 28 / is in front of the seal / 35 /, sealing the slider / 28 / in relation to the sleeve / 26 /, and in the second extreme position of the slider / 28 / - behind this seal / 35 /. 5. A device for self-maintaining pressure in the hydraulic props of the powered support and for the pressure rules of the preliminary support of the support, characterized in that the valve / 1, Fig. 3 / has a hermetic chamber / 43 / a spring / 46 / pressing on the slider / 28 / through a mushroom / 45 /, connected hydraulically through a connection / 0 / and a conduit / o / with a conduit / 7 / supplying liquid under pressure supplying the space / 10 / shifter / 11 /, which causes the section of the casing to move towards the face of the longwall working, whereby between the distribution / 16 / controlling stkJakίem / 4 / and stand ^ w '! the valve block / 17 / has a check valve / 18 / that allows the liquid to flow in the direction from the stall block / 17 / to the distributor / 16 /, and parallel to this valve / 18 / it has a constantly open manifold / 15 /, closed by the pressure of the liquid from the conduit / 19d / connecting the stand block / 17 / the valve block with the divider / 16 /, which liquid flows to the separator / ^: ^^ ooru / / 15 / through the valve / 20 / glandular-zorotjy. 157 464