DE2430537A1 - Piston valve with inclined valve seat - uses fluid pressure to reduce valve closing force - Google Patents

Abstract

A shut off valve for fluids has a valve piston which moves across the flow at right angle. The leading face of the piston is inclined at 45 deg. so that it matches the valve seat which is inclined at the same angle. The piston is operated by a valve spindle or by remote control through a pilot cylinder. In order to reduce the piston operating force to a minimum, when shutting the valve the pressure increase in the fluid is allowed to act on the right angled trailing face of the valve piston. The inclined valve seat in the flow line does not restrict its cross section thus no losses occur when the valve is fully open.

Description

PATENTANWÄLTE O / O Π Γ O * 7

HELMUT SCHROETER KLAUS LEHMANN

DIPL.-PHYS. DIPL.-ING.

jan-10

3B / p

June 24, 1974

Slide valve

The invention relates to a slide valve according to the preamble of claim 1.

In known slide valves, a disadvantage is that in the open state the full width of the pipe to flow through of a fluid cannot be maintained. In general it is necessary to adjust the cross-section of the pipe narrow so that a seat for a sealing element is created. Also, in known valves, a great force of can be used externally so that a good seal is achieved in the case of a fluid that is under very high pressure will.

It is an object of the invention to provide a valve which opens with relatively little external force or can be closed. In the open state, the full cross-sectional width should be required for the fluid Pipe are available to flow through. In addition, a remote control of the Valve be possible.

_o A solvent of the invention is presented in the characterizing part *** of claim 1.

The special mode of operation of the slide valve results in that the valve piston which can be displaced to interrupt or reduce the flow rate of the fluid

D-707 SCHWABI &: H GMÜND - COMMON ACCOUNTS: Ρ-β MÜNCHEN 70

'' Telephone: (07171) 56 90 Deutsche Bank AG Postscheckkonto Telephone: (08 11) 77 89

H. SCHROETER Telegrams: Schroepat Munich 70/37 369 Munich K.LEHMANN Telegrams: Schroepat

Bocksgasse 49 Telex: (BLZ 700 70010) 1679 41-804 Lipowskystriße 1 0 Telex: 5 212 248 pawe d

- 2 - jan-10

which is introduced into the fluid transversely to the direction of flow., is arranged in its guide in a non-sealing manner. This allows the fluid to spread around the piston and also to an end that is opposite the sealing end can act. This results in the possibility that the inherent pressure of the Fluids the piston is pressed for sealing on a corresponding seat, whereby a good shut-off effect of the slide valve is determined. A special design of the seat for the piston allows that in the retracted state of the Piston the full width of the flow tube is released. This is possible because the area in which the seat lies is arranged obliquely to the direction of flow. Accordingly, the piston of the slide valve has an incline at one end Area that can come into engagement with the inclined seat.

In a further development of the invention, the valve piston can have a non-sealing continuation that extends into a the cylinder adjoining the guide of the piston takes place, this cylinder having a PCanal with which a connection to the outside world can be established. The adjoining cylinder can have a larger cross-section than have the first cylinder. The embodiment of the invention can be done so that the continuation in the seat direction acting pressure is greater than the pressure opposite to this direction -.-

In another embodiment of the invention, the the two cylinder spaces must be tightly separated from one another. In the second cylinder, a piston can be arranged with the cylinder wall assigned to it is in tight engagement and is in mechanical connection with the valve piston. Of the The piston in the second cylinder can be acted upon by a fluid in such a way that it moves back and forth and thereby locking or opening of the slide valve is achieved.

509842/0369

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In a further embodiment, the piston in the second cylinder can be used as an armature for a plunger coil magnet be designed.

Embodiments of the invention are based on the following of the drawings:

Fig. 1 shows a longitudinal section through a manually operated slide valve.

Pig. 2 shows a longitudinal section through a slide valve, which is caused by the effect of the inherent pressure of the fluid and is opened and closed by means of an auxiliary valve.

Fig. 3 shows a longitudinal section through a valve that over «Can be actuated in a pressurized auxiliary piston.

Fig. 4 shows a longitudinal section through a valve in which the auxiliary piston is designed as an armature of an electromagnet.

1 shows a pipe 1 on which a pipe part 2 is arranged at an angle. A piston 3, at one end of which a bevel 4 is provided, is arranged displaceably in the interior 5 of the tubular part 2. The handle 7 is attached to one end 6 of a shaft. The other end of the shaft is screwed into a cylindrical part 9 which is located in the piston 3. The pipe part 2 is closed by a cover 10. Seals 8 ensure that no fluid can escape from the interior of the pipe part 2 to the outside.

If the spool valve from the open (Fig.l) position are placed in the closed, so the handle 7 ^ he can move the piston 3 by appropriate rotation. The bevel 4 and the nose-like

509842/0369

Approach end Ι3 to seat 12 and groove 11. Since the Piston 3 is not sealingly arranged in the pipe part 2, the space created above the piston will fill with fluid. As long as the bevel 4 and the end 13 are not yet in sealing engagement with the seat 12 and the groove 11, acts on the entire surface of the Piston roughly the same pressure. However, if the piston has been moved so far towards the groove 11 that in the Grooves 11 adjoining pipe sections prevail different pressures, so acts on the bevel 4, a lower pressure than on the remaining surfaces of the piston. If the surface of the bevel 4 is in sealing engagement with the seat 12, then the pressure that prevails in the pipe section 14 acts on the surface and the end face opposite the bevel 4. As a result: the piston 3 is depressed right from above with the same pressure. The one on the surface pressure acting on the piston compensates itself in the area in which there is no bevel. By doing The area in which the bevel 4 is arranged results in a force component that corresponds to the direction of flow of the fluid is parallel. So you have a horizontal pressure component. Are the surfaces of the piston 3 on which the pressure of the fluid acts, chosen so that the vertical and horizontal force components are equal in terms of their behavior are large, then there is a resulting force component which is perpendicular to the plane laid by the seat 12, if this is inclined by 45 ° with respect to the piston axis ". As a result, a force is achieved by the fluid that enables the slide valve to be securely sealed, without the need for a special external force to act on the shaft 6.

Another embodiment of the invention is shown in FIG. The piston 3 is in a position in which the flow of the fluid is interrupted. The bevel 4 is in sealing engagement with the seat 12. The nose-like end 13 engages in the groove 11. On the pipe 1 there is a pipe part 2 in which two different cylinders I5 and 16

509842/0369

ORIGINAL INSPECTED

are provided. The piston 3 is on that of the bevel 4 opposite end provided with a port setting, which has a larger cross-section. The lower part of the piston 3 can in the cylinder 15 in non-sealing engagement be moved back and forth. Porting 17 of the piston has essentially the cross-section of the cylinder 1β. The part setting 17 is not in contact with the wall of the cylinder 16 sealing engagement. A channel 18 is provided at one end of the cylinder. This channel can be via an auxiliary valve 20 can be brought into connection with a channel 19. The channel 19 stands with the downstream part of the river Line pipe 1 in connection. A force directed vertically downwards acts on the piston 3 through a spring 21.

In the position of the piston 3 shown in FIG. 2, the fluid is not only in the pipe section 1h, but it is also in the space between the piston 3 and the wall of the cylinder 15 and in the cylinder 16. In the continuation 17 of the piston 3 there can be an additional opening 22, as a result of which the filling of the cylinder 16 with fluid can be accelerated. A downward pressure acts on the piston 3, which pressure is proportional to the end face of the piston 3 opposite the bevel 4. A pressure acts in the opposite direction which is proportional to the difference between the cross-sectional areas of the piston 16 and the piston 15. However, this difference area is smaller than the face on which a downward pressure acts, so that a downward force component remains. The relationships on the side surfaces are the same as have already been described in connection with FIG. 1. As a result, a resultant force can result which is perpendicular to the plane in which the seat 12 lies when it is opposite the piston axis is inclined by 45 °.

50 98 42/036 9

ORIGINAL INSPECTED

- ⁶ - 243 & S-3?

If the sliding system 1 is to be opened, it is sufficient that To operate auxiliary valve 20. ' The anchor 23 is after pulled up so that a connection between the channel 18 and the channel I9 is made. As a result, that will Flow fluid from the cylinder 16 through these two channels. As a result, the pressure in cylinder 16 will be lower, than the pressure of the fluid prevailing in the pipe section 14. Between the continuation I7 and the inner wall of the cylinder 16 fluid can penetrate into the cylinder 16 itself. Are the dimensions of the channels 18 and 19 and the distance between the Continuation 17 and the inner wall of the cylinder 16 so dimensioned that the inflow of the fluid is less than the outflow, so will the pressure in the cylinder 16 remains lower than in the pipe section 14. As a result, a pressure acts on the underside of the continuation 17 which corresponds approximately to that acting in the pipe section 14. As a result, the piston 3 is up against the spring force moved so that the slide valve is opened. The fluid present in the cylinder l6 can be via the Exclude channels l8 and I9. On the bottom of the continuation 17 as well as on the bevel 4, the full pressure of the fluid now acts in the pipe section 14, so that the slide valve is opened remain. If necessary, channel 19 can be used

j - a direction-dependent valve can be provided which prevents the fluid from flowing through the channels 18 and 19 into the cylinder 16.

If the slide valve is to be closed, it is sufficient to do this To operate auxiliary valve 20, whereby the connection between the channels l8 and I9 is interrupted. By the force the spring 21, the piston 5 is slowly pushed into the flowing fluid until the bevel 4 with the seat 12 in sealing engagement comes. Then the fluid around the piston will rise into the cylinder 16 and the closing action of the Reinforced piston on the seat in the manner already described.

509842/0399

ORIGINAL INSPECTED

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In the figure 3 an embodiment of the invention is shown, in which in a manner similar to that in Fig.'2 two different cylinders 15 and 16 are provided. Of the Piston 3 can move back and forth in cylinder 15. An auxiliary piston 25 can be moved back and forth in the cylinder 16 arranged. It is in sealing engagement with the inner wall of the cylinder 16 via a seal 26. On the one hand the auxiliary piston 25 is loaded by a spring 24.

The auxiliary piston 25 is connected to the piston 3 via a rod 24, for example. By seals 27 are the Spaces of the cylinders 15 and 16 are separated from each other. The seals 27 are designed so that the rod 24 through it can be moved therethrough with the rod itself in sealing engagement with the seals.

An opening 28 is located in the wall of the cylinder It is arranged between the piston 25 and the seal 27. A fluid can be introduced through the opening 28, see above that, when the pressure is sufficient, the piston 25 is displaced. Since the piston 3 with the piston 25 over a rod 24 is connected, the piston 3 is moved in the cylinder 15 at the same time.

In the embodiment shown in Figure 3 is located the piston 3 is in a position in which the flow of the fluid is interrupted. Since the piston 3 with the inner wall of the cylinder 15 is not in sealing engagement fluid is above the piston 3 and on its sides. In in the same way, as it has already been described above, a force component also arises here which essentially is perpendicular to the plane in which the seat 12 is located. As a result, the closing effect is also achieved here by the fluid itself of the piston 3 on the seat 12 reinforced.

SQ9842 / Q36 9

If the slide valve is to be opened, a fluid is introduced through the opening 28 so that the piston 25 of the seals 27 is moved. At the same time, the piston 3 is also moved, creating a distance between the bevel 4 and the seat 12 occurs. Depending on the amount of fluid supplied through the opening 28 the piston 3 is partially or completely lifted out of the pipe 1.

An exemplary embodiment is shown in FIG an electromagnet 3I for actuating the slide valve is provided. This consists of a coil 29 and an armature 30 that can be moved back and forth in it. The armature 30 is stationary for example via a rod 24 with the piston 3 in connection. If the armature 30 is moved back and forth, the piston 3 also moves accordingly. Flows through the coil 29 a current, the armature 30 is drawn into it. Through this the piston 3j moves its bevel 4 from the seat 12 releases so that the fluid can flow through the line 1 therethrough. If no current flows through the coil 29, then the piston 3 is pushed into the fluid by the action of the spring 21. This rises between the surface of the piston 3 and the inner wall of the cylinder I5 and fills the space above the piston. So that the fluid doesn't penetrates to the outside, a seal 27 is provided which is in sealing engagement with the rod 24. On the piston the pressure of the fluid that is in line 1 now acts. As in the previous cases, this also works here Fluid itself in such a way that the closing action of the slide valve is increased.

609842/0369

Claims (1)

jan-10 H3 / p June 24, 1974 Patent claims 1.) / slide valve for changing the through a pipe amount of a fluid flowing through, characterized in that one in one after externally closed, first cylinder (15) movable, non-sealing piston (3) at one end an inclined Has surface (4) which can be brought into sealing engagement with a seat (12) in the line (1), whereby the Flow rate of the fluid is variable. 2.) Slide valve according to claim 1, characterized in that the first cylinder (15) is a adjoins another cylinder (16) into which the piston (3) is continued and essentially its cross section assumes, and that the space adjoining the end opposite the inclined surface (4) has an outlet channel (18) Has. 3.) Slide valve according to claim 2, characterized in that that the cross section of the further cylinder (16) is larger than that of the first cylinder (15). 4.) Slide valve according to claim 2, characterized in that the outlet channel (18) through a valve (20) can be shut off. 5.) Slide valve according to claims 2-4, characterized in that the cross sections of the plungers (3,17) are chosen so that, when the valve (20) is closed, the end that acts on the end opposite the inclined surface and force trained on the seat; is greater than the opposite. 50984 2/0369 - 10 - 'j'an-lO β.) Slide valve according to claim 1, characterized in that the piston (3>) under the action a spring force (21). 7.) Slide valve according to claim 1, characterized in that the cross section of the line _f (1) is not reduced through the seat (12). 8.) Slide valve according to one of the preceding claims, characterized in that the plane passes through the seat (12) relative to the longitudinal axis of the piston (3). 45 is inclined. 9.) Slide valve according to claim 8, characterized in that the additional piston (25) with a Fluid can be acted upon. 10.) Slide valve according to claim 8, characterized in that that the additional piston is designed as an armature (30) for a plunger coil magnet (3I). 509842/0369 Blank page