EP0401306A1

EP0401306A1 - A stop valve

Info

Publication number: EP0401306A1
Application number: EP89904862A
Authority: EP
Inventors: Lars Lenberg
Original assignee: Tour and Andersson AB
Current assignee: Tour and Andersson AB
Priority date: 1988-04-21
Filing date: 1989-04-20
Publication date: 1990-12-12
Also published as: KR900700809A; SE461053B; JPH03504531A; DK253590A; SE8801490D0; AU3426589A; AU628048B2; WO1989010507A1; DK253590D0; FI905188A0; SE8801490L

Abstract

Vanne d'arrêt (1) comprenant un carter (2) ayant un passage (15) pour l'écoulement réversible d'un fluide pouvant être arrêté au moyen d'un corps de vanne (20) dont la surface d'étanchéité (25) est une section annulaire de sphère avec une extrémité aplatie (26). La zone de transition entre la surface d'étanchéité (25) et l'extrémité aplatie (26) est incurvée avec un très faible rayon de courbure (r) et le rayon de courbure (r1) de cette surface d'étanchéité (25) est inférieur au rayon d'action maximum (r2) du corps de la vanne. Ce corps de vanne (20) coopère avec un dispositif d'étanchéité (36) annulaire qui entoure le passage et qui comporte un corps annulaire (37), lequel, par le moyen d'un resserrement (38) est transformé en siège amovible (39). Lorsque la vanne est en position fermée, ce dispositif d'étanchéité (36) est au contact d'une plus petite partie de la section du passage qui abrite le corps de la vanne et d'une plus grande partie de l'autre section du passage. Le montage du corps de la vanne permet un réglage de la position dans la direction du siège, mais non dans la direction opposée au siège.Stop valve (1) comprising a housing (2) having a passage (15) for the reversible flow of a fluid which can be stopped by means of a valve body (20) whose sealing surface (25 ) is an annular sphere section with a flattened end (26). The transition zone between the sealing surface (25) and the flattened end (26) is curved with a very small radius of curvature (r) and the radius of curvature (r1) of this sealing surface (25) is less than the maximum working radius (r2) of the valve body. This valve body (20) cooperates with an annular sealing device (36) which surrounds the passage and which comprises an annular body (37), which, by means of a constriction (38) is transformed into a removable seat ( 39). When the valve is in the closed position, this sealing device (36) is in contact with a smaller part of the section of the passage which houses the valve body and a larger part of the other section of the passage. The mounting of the valve body allows adjustment of the position in the direction of the seat, but not in the direction opposite to the seat.

Description

A Stop Valve The present invention relates to a stop valve of the type described in more detail in the preamble of patent claim 1

The cap-shaped valve body of such valves causes a few problems, which are hard to remedy. The cap e.g. is to cooperate with a seal during an extended period of time, resulting in a preferably constant sealing action. Also, the pressure of the medium, which is to be controlled, must not open up/shut the valve body unintentionally. To the extent that there is no unambiguous exterior indica¬ tion of the position of the valve body, it is difficult to know the precise control position. Another problem re¬ sides in the fact, that it often is desirable to be able to control a flow in opposite directions, while the de¬ sirable properties of the valve are maintained. An addi¬ tional almost paradoxical problem is that the valve body, i.e. the cap, is to provide a satisfactory sealing irre¬ spective of the direction of flow and the pressure of the medium and yet be easily controllable. Finally, the con¬ ventional stop valves require often a lengthy, tedious and expensive mounting process, a so called automatic mounting being almost impossible. Despite this lengthy, tedious and expensive process several of the known valves constitute safety risks, since leakage and/or disintegra¬ tion under pressure may occur.

A valve according to the preamble of claim 1 is previous¬ ly known by US-A 4 257 576. The concept of this previous invention is to design a shut-off member large in rela¬ tion to a passage way into which it is to be fitted through one of two connecting ends of a valve housing which is made in one piece. Fig. 16 of this specification reveals the way of mounting the shut-off member within. the valve housing. As can be seen, the shut-off member has to be obliquely engaged in the main bore of the valve housing until an upper lug of said member arriveswithin a diverting spindle bore, while a lower, forked lug has to be engaged on a stub which previously has been secured to the housing as has a sealing gasket provided to co-operate with the shut-off member. Then, the latter is to be straightened rocking into a non-operative position, which is the only way to insert the shut-off member, which then has to be turned 180 , whereupon the spindle is inserted on to the upper lug.

It can hardly be argued, that such a concept requires a fair amount of difficult and time consuming manual assem- blance work. In spite of this, the mode of operation and reliability of a valve of this kind must be questioned. Firstly, when having succeeded to insert the shut-off mem¬ ber, straightening and turning it to its right shut-off position, this will have to be achieved against resistance and friction offered by the sealing gasket, most probably manually, as the spindle is to be inserted but after the 180° turn of the shut-off member. Anyway, it would hardly be possible to insert the spindle before, as the shut-off member is designed to be turned 90° only. This means, that there must be a considerable play between gasket and shut- off member in-order to have the latter slide along the gasket with the aid of a hand or some tool only. Secondly, the fork-shape of the lower lug, which shape is a must, is a.v considerable disadvantage, as in this way the shut- off member can exert an uncontrolled pressure on the gas¬ ket and damage or even blow away same atf.occasional high pressures like an ordinary shock-wave, which in a lever¬ like way is concentrated just and only on the gasket area juxtaposed the lower lug. Simultaneously, the upper lug may be damaged, if not the entire shut-off member. Un¬ doubtedly, due to this design, there is a high wear of the said gasket region, and sooner or later the gasket sealing won't operate any longer in the desired way. With the wore-off gasket region, the shut-off member won't attain a straight position any longer, but will be more and more oblique and continue to wear-off the said gasket area, until the valveceases to function properly. Mal¬ functions which easily may occur with this valve are non- desired self-opening and/or closing.

Also, using a valve housing made in one piece will ini¬ tially save very little money, which then will turn into high extra costs for extraordinary difficult and costly assembling or disassembling. Any subsequent inspection is impossible without firstly removing the valve housing from at least one connection pipe. Furthermore, there re¬ mains always the risk of a so called blow-out of the spin¬ dle at very high pressures, as the spindle is insertable from the outside in relation to the passage-way only. Last not least, this valve cannot be used for fluid flows in opposite directions, i.e. the direction of fluid cannot be turned, as the sealing gasket never would be sealingly affected and would tender to leave its position during the opening or closing movement of the shut-off member. Finally, the various shapes and modes of mounting the sealing gasket make obvious, that sealing properties, life time etc do not meet with high standards. The same may be said of the various shapes and reinforcements of the shut-off member. In open position, which is shown in

Eig. 7 in the said specification, the shut-off member is, of course, unprevented by the lower lug with open fork from being pushed further to one side and may even be sub¬ jected to vibrations or fluttering, while a subsequent shutting movement will have to take place against the fluid flow pressure, which means, that the fork may be more or less disengaged from the stub and the sealing gas¬ ket will be affected extra much and non-uniformly. The object of the invention is to counteract and as far as possible overcome the above-mentioned problems and to suggest a stop valve, which also in additional respects is conducive to technical progress in this field.

This object is attained, according to the present inven¬ tion, by designing a stop valve of the type discussed above in the way set forth in the characterizing clause of patent claim 1.

A so designed stop valve is considered to be very advan¬ tageous in various respects. As can be seen from fig. 4 of the attached drawings, the valve body does not obstruct or minimize any of the cross-sectional area of a passage¬ way. Also, it is possible to insert, inspect and remove a unit consisting of spindle, valve body and a lid with a bearing pin with both ends of the valve housing connected to pipes. There are no turnings or rockings of the valve body at all and the said unit can be fitted in a more or less coherent state. Once it is fitted, the valve body, being in proper closing position, offers itself in an ex¬ cellent way for properly positioning and fitting of the sealing ring, the sealing carrier and the lock ring, which all can be mounted easily, safely and in a very speedy manner. Furthermore, as the spindle is inserted from the inside of the valve body, as both ends of the valve body are positively secured all around, and as the lid carry¬ ing the said unit may project into the interior of the valve housing with a minor part, which thus is affected by a minor pressure while the exterior part of the said lid may be designed with a relatively large diameter and thus a considerable locking force, there is no risk for a so called blow-out even at very high pressures, which occasio¬ nally may occur in most valves.

As the valve body is provided to be inserted into the valve housing prior to mounting the sealing gasket, there is no problem whatsoever with obstruction, resistance and friction forces offered by the sealing gasket. Instead, the prior mounting of the valve body will favour the subsequent moun¬ ting of the sealing gasket with accessories as previously mentioned. When mounting the sealing gasket with accessories, this can be done at any desired compression or friction for¬ ces created by the sealing gasket, as the latter and its accessories may all be mounted in one straight mounting ope¬ ration, the pushing force of which easily may be chosen ade¬ quate to lock all parts safely in their intended position. Although, due to these characteristics, a so-called blow¬ out positively may be prevented, it is easily possible to design particularly the lock ring and the groove holding same, in such a way, that they will give way above a certain pressure level, e.g. for reasons of security. Normally, this is, of course, not necessary and the valve according to the invention will resist any medium pressures without having any part damaged due to such pressures. It will be appreciated, that reinforcements or any special designs of e.g. the valve body may be completely avoided due to the overall design men¬ tioned particularly in claim 1. All parts of the valve accor¬ ding to the invention may be designed without any play or with a certain play, which is unimportant due to the charac¬ teristics of the invention, which make any special considera¬ tion unnecessary. Even a certain wear of any part, the sea¬ ling gasket and the valve body in particular, won't render the valve less operative, as the design according to the in¬ vention incorporates per se compensation for wear and play. Unintentional self-opening and/or self-closing are practi¬ cally impossible. The valve body is safely held both in ope¬ ning and in closing position and this regardless of the di¬ rection of medium flow. This means, that without any problems the direction of medium flowmay be reversed and in such a case, again due to the characteristics according to the pre¬ sent invention, all properties of the valve will be main¬ tained, in particular a reliable sealing operation in closing position. Additional characterizing features and advantages of the present invention are set forth in the following descrip¬ tion, reference being made to the accompanying drawings, which partly schematicly show a few preferred, all the same not restricting embodiments and which show in detail:

Figs. 1-5 a stop valve according to the invention, in a lateral view, a view from below, a view from above, and views of its two ends;

Fig_* 6 a diametrical longitudinal section of the valve according to Figs. 1-5 in its closed position;

Fig. 7 a sequence of the cap movements from the closing to the opening position;

Fig. 8 the positions according to Fig. 7, transferred to one and the same figure on a larger scale;

Fig. 9 an axial view of the seal carrier on a large scale from the right in Fig. 7; and

Figs. 10 and 11 said cap, shown from below and from the left respectively in Fig. 6.

In the drawings a stop valve 1, taken as a whole, compri¬ ses a housing 2 and two connection ends 3 and 4, which can be designed as exterior hexagon heads having an interior threading 5 and 6 respectively. On one side of the housing, e.g. roughly in the middle of it, there is a control ele¬ ment 1 , suitably a handle, arm 8 of which being used as a position indicator for a valve body, which will be de¬ scribed below. Said control element is, e.g. via a screw 9, attached to the exterior end of a spindle 10, which is mounted in a projection 11 on housing 2 _r e.g. having a sliding plate 12 in an axial direction between an exterior spindle stop and an interior flange at the end of said pro¬ jection as well as an O-ring 13 around the middle of said spindle. The spindle is extended, with a control end 14, somewhat into a passage 15 for the medium to be controlled and formed by said housing. Said control end is provided with partly a diametrical groove 16 and partly a central and axial hole 17, designed to accommodate a rotary tongue 18 and a guide pin 19, which projects from said tongue, respectively, to a valve body designed, as a whole, as a cap and designated 20.

In order to transfer movements from said control element to said spindle the latter is provided with a square ele¬ ment 21, which projects from the housing and matches a corresponding cavity 22 in said control element. Further¬ more, in order to limit/define the opening and closing movements respectively the housing may be provided with a stop lug 23, which cooperates with two stop surfaces 24 on said control element, which stop surfaces can be de¬ signed having an angular positional difference of roughly 90°.

Cap 20 has an outer sealing surface 25, which constitutes a portion of an imaginary sphere and which has an annular shape, confining a flat, closed end portion 26. At the top of Fig. 6 a transfer arm 27 projects from this annu¬ lar sealing surface and is extended in a roughly horizon¬ tal direction adjacent to the free end surface on control end 14 and meshes, by means of said tongue 18, in said groove 16, and by means of said guide pin in said hole 17.

On the diametrical side a bearing arm 28 projects from the annular sealing surface in the same direction and is somewhat longer than said transfer arm and somewhat eccent¬ ric as compared to hole 17 and provided with a bearing drilling 29. The eccentricity may in a practical embodi¬ ment be as high as about 5 % and be directed away from a seat 30, v/ith which said cap is designed to cooperate. Said bearing drilling 29 is designed to receive a bearing pin 31, which projects upwardly from the interior of a lid 32, which is threaded into a threaded drilling 33 in a wider projecting portion 34 of the housing, which is used as a mounting opening for said spindle and said cap. Said lid may be hollow oh its outer side in order to form in the cavity engagement elements/surfaces 47 for a tool, e.g. a wrench (not shown) . Said bearing pin projects pre¬ ferably into said medium passage and is surrounded with play by bearing drilling 29, which due to said eccentrici¬ ty and the pressure/elasticity of seat 30 abuts against the pin on the seat side, while the play manifests itself as an opening 48 mainly on the opposite side. Also how¬ ever, if desirable, drilling 29 may be somewhat oblong having a longitudinal extension in the axial direction of said passage. Said pin may instead be wider in the cross- direction of said passage than in its longitudinal direc¬ tion.

Between arms 27 and 28 said annular sealing surface 25 is provided with a recess 35 on each side. Said recesses are comparatively flat. They are designed to, in a completely open position, allow a free and unobstructed flow through seat 30.

Seat 30 comprises an annular sealing 36, preferably made of rubber and having the cross-section shape shown in Figs. 6 and 7. Said sealing has an annular body 37, which may have a rectangular cross-sectional shape and which via a continuous circular constriction 38 is transformed into a seat ring 39 having a smaller diameter. Said seat ring is concentric with said body, but it projects inwardly somewhat and forms, on the side which faces away from said body, seat 30, which preferably is a bend of the free cor¬ ner, which is facing away from said constriction.

In the direction of said cap said body is supported with an axial limit surface by a flange 40, which projects in¬ to said passage and is a portion of said housing and against the interior side of v/hich said seat ring abuts with its envelope surface. On that side v/hich faces away from said cap a sealing carrier 41 is pressed into said passage. Said carrier is axially supported with a closed cylindrical portion 42 by that side of the seat ring, which faces away from said seat and in a radial direction outwardly against the inner side of said body, while a circular continuous collar 44, provided with holes 42, is supported by that side of said body, which is directed away from said seat ring, and is fastened, in this posi¬ tion, by means of a lock ring 45, which is pressed into a circular continuous groove 46 in said housing.

In the position shown with continuous lines in Figs. 6, 7a and 8 said cap occupies its closing position diametri¬ cally in relation to and completely blocking said passage. The annular sealing surface circumferentially deforms in this way seat 30 elasticly according to Fig. 8, a satisfac¬ tory sealing action being attained. This elastic deforma¬ tion partially is a condition for an exact utilization of the eccentricity described above, which however also or actually in principle can be utilized by the medium pressure in said passage, e.g. the pressure against the inner side of said cap, i.e. in the direction of said seat. Due to said eccentricity and the performed bearing drilling respectively, said bearing drilling having a larger width than the diameter of said bearing pin, said cap can, when substantial pressures are used with an effect in the direction of said seat 30, be displaced also to¬ wards said seat and furthermore compress said sealing ring, simultaneously improving the sealing action between said cap and said seat. Said bearing drilling then is dis¬ placed somewhat as compared to said bearing pin. In case such a displacement possibility had not existed, then the medium pressure could have compressed the sealing ring and a leakage between seat 30 and sealing surface 25 could have resulted.

In case the medium pressure is pressing in the opposite direction, then it acts primarily on said cap, which how¬ ever, due to the eccentric conditions described above, does not yield, when said bearing drilling on the seat side closely contacts said bearing pin. However, the me¬ dium pressure upstreams does not act solely on said cap but via holes 43 also on sealing body 37, which is comp¬ ressed and exerts a pressure via constriction 38 on seat ring 39, which is compressed from within and increases the pressure on sealing surface 25 via seat 30. In this way a satisfactory sealing action is attained also when the pressure is very high or is an overpressure.

Thanks to the described and shown design of the sealing, it is always firm and securely fastened and simultaneous¬ ly it is capable of performing the described functions.

If now said valve is to be opened up, then the forward portion of said sealing surface 25 in the turning or ope¬ ning direction exerts a compression pressure on the respec¬ tive portion of said ring 39, which is clearly shown in Fig. 8 in the lower corner to the left, while on the oppo¬ site side a disengagement from seat ring 39 takes place. This means, that said cap in the closing position indica¬ ted with continuous lines in Fig. 8 is in a position of equilibrium, in which seat ring 39 circumferentially cen¬ ters and holds said cap. An alteration of this position can solely be done by overcoming a resistance, which said seat ring is responsible for in said forwardly placed opening area and consequently an opening of said valve is possible only via a stronger compression of said seat ring, and in this way a portion of the compressed material of said seat ring can be displaced via said constriction 38 to said body 37. When the opening up is continued from the posi- tion indicated in Fig. 8 with dotted lines, the maximum compression area of said seat ring is passed and subse¬ quently fairly quickly a snap-in assistance of the con¬ tinued opening up movement takes place, the last contact portion of said seat ring thus being instrumental in a way in a repulsive movement regarding said valve body.

In the positions between Figs. 7b and c the opening up movement is not obstructed by said seal ring, but this occurs again in the positions according to Fig. 7d, in which that area of sealing surface 25, which trails in the opening direction, will contact the already described compressed area, in which anew a corresponding compression takes place, since the forwardly and backwardly placed areas of said valve body, in the opening direction, occu¬ py completely analogous positions regarding said seat ring. In order to attain a completely opened up position according to Fig. 7e said valve body with its area, which trails in the opening direction, must overcome the resis¬ tance caused by said seat ring and also in this case fi¬ nally a snap-like disengagement or repulsion to the comp¬ letely opened-up position according to Fig. 7e occurs.

When the valve is closed, the mode of procedure and the existing conditions are exactly opposite. Of course, the "opening snap" can be noticed best, when a complete or al¬ most complete disengagement from said seat ring has occurred.

This means, in a tangible manner, that the closing and the opening up of the valve also is indicated in a clear¬ ly noticeable way, which is an appreciated advantage and also guarantees that said valve body cannot quite easily be displaced from its opening or its closing position.

According to the invention the described functions are attained in a most advantageous way, provided the trans¬ fer area between sealing surface 25 and said flat portion 26 has a smaller bending radius r than bending radius r2 of sealing surface 25. In a practical embodiment, which also illustrates the relationships between said bending radii, the following values apply: rl = 10 mm, while r2 = 13 mm and r = 3 mm. In this connection rl designates the bending radius of the partly spherical sealing sur¬ face 25, while r2 designates the maximum action radius of said valve body. The ratios between r: rl: r2 consequently are 3: 10: 13. Of course, each one of said variables can be altered within certain scopes, e.g. by a 20 % reduction and a 20 % increase individually.

The present invention is not restricted to the shown and described features, but modifications and supplementary alterations can be done in an arbitrary way within the scope defined by the following patent claims.

Thanks to lid 32 and its particular design, bearing pin 31 being provided on its inner end, an automatic mounting is feasible without any problems. When accomplishing this, spindle 10 and associated plate 12 and O-ring 13 can be inserted through the hole in projection 34, subsequent to which said valve body can be inserted in the same way. The position of groove 16 in mounting end 14 can be deter¬ mined simply firstly by designing an insertion tool (not shown) with a shape v/hich is more or less identical with tongue 18 and pin 19 and secondly by easily retaining said spindle exactly in its predetermined position by means of handle 8 or the like, adjusted in its correct position. Subsequently, valve body 20 is inserted, while drilling 29 and possibly arm 28 easily can occupy an exact inser¬ tion position on any suitable insertion tool, the result being that tongue 18 and pin 19 safely can be guided into said mounting end of the spindle. Subsequently, a carrier element (not shown) can hold said valve body in place in its closing or its opening position, while said lid is screwed on and pin 31 penetrates drilling 29. In connec¬ tion with this or even earlier elements 36, 41 and 45 can be inserted through connection end 5 and be fastened simply and quickly.

It is also advantageous, that sealing carrier 41 has been inserted in a way "freely floating" in said passage, which partly facilitates an automatic mounting and partly ren¬ ders it possible to some extent to brake the pressure shocks in the respective parts of the passage due to the fact that a sudden overpressure can displace said sealing carrier somewhat in the direction of said valve body, said sealing ring being compressed. In extreme cases the described and shown design comprising a seal, a sealing carrier and a lock ring may also be used as a safety de¬ vice for extreme overpressures in that passage portion, which encompasses the valve body, in which case e.g. an extreme pressure shock may influence the sealing ring, which in its turn may compress the sealing carrier, which may displace lock ring 45, which is dimensioned for the existing purpose, groove 46 possibly being comparatively flat.

Claims

1. A stop valve, which comprises a housing having a medium passage, which can.be closed or opened up respectively by means of a valve body, which is provided with a partly sphe¬ rical sealing surface, which valve body is controllable from the outside by means of a spindle and a handle or the like and which co-operates with an annular seat surrounding said passage, which seat consists of a seat ring preferably made of rubber, the control end of the spindle having preferably a diametrical groove and a centrical axial hole emanating from the groove bottom intended to receive a rotary tongue respectively a guide pin projecting from the latter, which tongue and which pin stand at approximately a right angle from the transfer arm of the valve body, on the side turned away from said spindle, a bearing arm extends from the valve body approximately in parallel relation to and in the same direction as the transfer arm, which bearing arm comprises an opening for co-operation with a bearing pin projecting in¬ to the passage from the side opposite to the spindle c h a r a c t e r i z e d in that slightly eccentrically ^■ in relation to the center axis of the spindle (10) and thus the rotary tongue (18), the bearing arm (28) surrounds with the opening (29) designed as an all around closed bearing drilling the bearing pin (31) and/or that the latter is ec- centricly provided with at least part of its circumference in relation to the said center axis, that said eccentricity and/or a corresponding design of the bearing pin (31) are of that type, that the valve body (20), at over-pressures and/or when wear _t or the like has occured is able to move somewhat closer to the valve seat (30) and improve its sea¬ ling capacity, but prevent a so called blow-out of valve bo¬ dy and seat at extreme pressures, that the valve body (20) Is provided, in its closing position, non-affected or nor¬ mally affected by the medium pressure, to abut with its bearing drilling (29) in the bearing arm (28) tightly that side of the bearing pin (31) which faces the seat (30)-', in which position the seat ring (39) is provided to be com- pressed all around and retain the valve body in a centered position, and thai the valve body is provided, overcoming a resistance against compression created by the seat ring, to attain the opening and closing position respectively, and being secured there by the said resistance.

2. A stopvalve according to claim 1, the part-spherical sea¬ ling surface having the shape of a ring surrounding a flat closed end portion, c h a r a c t e r i z e d in that the transition area between said surface (25) and said portion (26) is bent at a considerably less bending radius (r) than the bending radius (rl) of the sealing surface (25).

3. A stop valve according to claim 2, c h a r a c t e r i z e d in that said bending radius (rl) of said sealing surface (25) is smaller than the maximum action radius (r2) of said valve body (20), the ratios between rjrl;r2 preferably being app. 3:10:13.

4. A stop valve according to claim 1, c h a r a c t e r i ¬ z e d in that the bearing pin (31) projects upwardly from the interior of a lid (32), which is threaded into a threaded drilling (33) in an element (34) of said housing (2).

5. A stop valve according to claim 1 , c' h a r a c - t e r i z e d in that said sealing surface (25) of said valve body (20) on each side between the fastening areas of the valve body is provided with a recess (35), which allows a free flow through said seat (30) in the opening position of the valve and/or forms engagement and holding surfaces in connection with the mounting of the valve.

6. A stop valve according to claim 1 , c h a r a c ¬ t e r i z e d in that said seat (30) comprises a 'annular sealing (36), rpreferably made of rubber, having an annular body (37), which preferably has a rectangular cross-section and via a circumferential constriction (38) is transformed into a seat ring (39) having a smaller diameter, said seat (30) preferably being designed as a bend of that free cor¬ ner, which faces away from said constriction.

7. A stop valve according to claim 6, c h a r a c t e r i ¬ z e d in that said body (37) of the sealing and its seat ring (39) are designed to, with a gable side and an envelope surface side respectively, be supported by a circumferential flange (40) of said housing (2), which flange projects into said passage (15), and in that said sealing is designed to be retained in its position by means of a sealing carrier (41) having a cylindrical part (42) and a radial part (44) having recesses (43), said sealing ring and said sealing carrier (41) being retained in said passage preferably by means of a lock ring (45), which is pressed into a circumferential groove (46) in said housing.

8. A stop valve according to claim 1, c h a r a c t e r i ¬ z e d in that the spindle (10) is mounted in a projection (11) on the housing (2), e.g. having a sliding plate (12) in an axial direction between an exterior spindlestop and an interior flange at the end of said projection as well as an 0-ring (13) around the middle of said spindle.

9. A stop valve according to claim 1, c h a r a c t e r i ¬ z e d in that in order to transfer movements from said control element to said spindle, the latter is provided with a square element (21), which projects from the housing and matches a corresponding cavity (22) in said control element, and/or that, in order to limit/define the opening and closing movements, respectively, the housing is pro¬ vided with a stop lug (23) co-operating with two stop sur¬ faces (24) on said control element, which stop surfaces are designed having an angular positional differance of app. 90 •

10. A stop valve according to claim 1, c h a r a c t e r i ¬ z e d ini that the sealing (36) is designed to contact the two sides of said valve body (20), said sealing body (37) being exposed towards its part of said passage (15) with a considerably larger surface than said seat ring (39) towards its part of the passage (15).