DE1151417B - Stopcock with spherical plug and sealing by ring piston - Google Patents

Description

Stopcock with spherical plug and sealing by means of an annular piston Stopcocks are known in which the spherical plug on the inflow and outflow side is sealed by ring pistons, which are screwed into the inlet and outlet nozzles of the housing are arranged coaxially to this, with each annular piston at the rear sealed by a packing and resilient by it and by the flow medium is pressed against the chick.

The invention relates to stop cocks of the aforementioned type. It is based on the task of further developing these shut-off valves in the direction that both a good seal between the annular piston and the surface of the ball plug reached as well as an exit of the medium flowing through the tap - independently from its direction of flow - from the indentations in the valve body leading to the annular pistons is prevented.

The inventive solution to this problem is characterized by that the annular piston housed in an otherwise known manner in an annular groove is and in the one formed behind him, in the installation position larger in the radial direction Expansion as a chamber having a sealing and spring ring in the axial direction is provided with a round cross-section in the uncompressed state, wherein however, the chamber is limited by flat surfaces, so that the sealing and spring ring migrate in the radial direction and depending on the direction of flow to one of the chambers create sealing walls delimiting the radial extent and thereby the medium can act on a sufficiently large area on the back of the annular piston.

It has already been proposed to have a sealing ring in a groove to be arranged and to allow him to evade in the radial direction in this groove, which has a greater extent in the radial direction than in the axial direction. Of the The sealing ring does not serve as a spring washer and is not axially pretensioned either. To the State of the art is to say that it is known to use sealing rings in gate valves axially preload in their installation position so that they are resilient in the sealing plates Hold the system on the locking piece. However, the sealing rings are not inserted into grooves and therefore cannot work in the manner intended here. With a well-known Faucets equipped with annular pistons with ball plugs are sealing rings in annular chambers arranged in the rear part of the outer circumference of the annular piston. These sealing rings but can only be moved axially. Plus it's no longer new, elastic rings to be used as resilient intermediate layers for measuring a metallic ring piston serve on the end wall of a slide plate of a gate valve. Be there the elastic rings are probably also used as sealing and spring rings. However, you are not in their retaining groove in the radial direction because of the shape provided there radial groove wall and the recess in the annular piston.

The invention has compared to the prior art explained above Technology has the advantage that due to the radial migration of the sealing and spring ring This chamber is securely sealed in the annular chamber behind the annular piston. The acted upon area of the annular piston is larger than with the known ones Shut-off cocks so that the annular piston rests against the plug with greater pressure.

In Figs. 1 to 3, an embodiment is shown.

Fig. 1 shows a longitudinal section through one equipped with a ball plug Stopcock according to the invention; Figures 2 and 3 illustrate on an enlarged scale broken longitudinal sections of the stopcock, in which the sealing rings are in different radial layers are located.

The shut-off valve has, in a known manner, a housing 1 with a longitudinal bore 2 and a transverse bore 3 perpendicular thereto. In the latter is the switching spindle 4, which is sealed off from the housing 1 by sealing rings 5. A plug 6 is attached to the switching spindle 4, the sealing surfaces of which are parts form a spherical surface. The plug 6 has a through hole 7, of which even if it is a multi-way tap acts, further Bores 8 can branch off. The two ends of the longitudinal bore 2 of the housing 1 are equipped with an internal thread 9, into each of which a connecting sleeve 10 is screwed which are sealed with respect to the housing 1 by a sealing ring 11 each.

On their side facing the plug 6, the connecting sleeves 10 each have a longitudinal bore 12 which merges into an enlarged bore with an internal thread 13 on the other side. The latter is used to connect pipes or hoses. An annular groove 14 is machined into the end face of the two connecting sleeves 10 facing towards the interior of the housing 1 and is delimited by an outer cylinder wall 15 and an inner cylinder wall 16, both of which are coaxial with the longitudinal bore 2 of the housing 1. In each of the two annular grooves 14, an annular piston 17 is arranged, the end face 18 of which, facing the plug 6, is adapted to the spherical surface of the plug 6. The rear side 19 of the annular piston 17 is flat. The axial depth of the grooves 14 and the axial slope of the annular piston 17 is dimensioned so that when the stopcock is assembled behind each annular piston 17 in the groove 14, a rectangular annular chamber 20 remains free, the radial width of which is greater than its axial length.

In each chamber 20 is an elastic sealing and spring ring 21 of circular cross-section, a so-called O-ring, inserted. Its cross-sectional diameter should be so large that it is in the assembled state of the stopcock in the axial direction Direction is compressed and thereby a contact pressure on the annular piston 17 exercises. The ring diameter of the O-ring is roughly the same as the mean diameter the annular chamber 20 match. As Fig. 1 shows, the O-ring is in contact when installed neither the cylinder wall 15 nor the cylinder wall 16.

The operation of the O-ring is shown below with reference to FIGS. 2 and 3 briefly described. As shown in Fig. 2, step from the left in the direction of arrow 22 pressurized fluid around the plug between the outer cylinder wall 15 of the annular groove 14 and the annular piston 17 in the annular chamber 20, then the O-ring pressed inwardly against the cylinder wall 16 in the manner shown in FIG and seals the annular piston 17 and the annular groove 14 against the on this side surface Passage of liquid. The same goes for the liquid that comes out of the the spindle 4 surrounding space 23 wants to exit into the outlet port.

According to FIG. 3, hydraulic fluid occurs from the right in the direction of arrow 24 between the inner. Cylinder wall 16 of the annular groove 14 into the annular chamber 20, then If the O-ring is expanded radially and pressed against the outer cylinder wall 15, see above that it prevents the passage of the liquid along this side surface. In In each case, a fluid pressure is formed in the annular chamber 20 according to the respective fluid pressure corresponding pressure that provides the contact pressure required for a secure seal the annular piston 17 to the plug 6 to a degree that is dependent on the fluid pressure causes and thus the stress and wear of the sealing surfaces on one Minimum size limited.

In the case of the annular piston 17 shown in FIGS. 2 and 3, this is the case provided with a conventional sealing insert 25, with which he is attached to the chick 6 creates.

Claims (1)

PATENT CLAIM: Stopcock with a spherical plug on the and the outflow side is sealed by annular pistons, which are turned into and out of the inlet and outlet Outflow stubs of the housing are arranged coaxially to this, with each annular piston sealed at the rear by a packing and resilient by it as well is pressed against the plug by the flow medium, characterized in that that the annular piston (17) in an otherwise known manner in an annular groove (14) is housed and in the one formed behind it, in the installation position in radial Direction of greater expansion than in the axial direction having chamber (20) Sealing and spring ring (21) with a round cross-section when not compressed is provided, but the chamber (20) is delimited by flat surfaces, so that the sealing and spring ring (21) migrate in the radial direction and depending on Direction of flow to one of the walls delimiting the chamber (20) in radial extent create a seal, giving the medium a sufficiently large area on the back of the annular piston (17) can act. In. Publications considered: German U.S. Patent No. 896,583; German utility model No. 1688102; Swiss U.S. Patent No. 230,557; British Patent Nos. 718 329, 669 933; U.S. Patents No. 2,628,060, 2,599,774, 2,558,260, 2,194,261, 2109,042, 2,049,805 Older patents drawn: German Patent No. 1116 003.