NL8005218A - AXIAL SHUT-OFF VALVE. - Google Patents

Description

V, i ί! * TO 0959

Axial shut-off valve,

The invention relates to a mechanical, forced-actuated, axial shut-off valve, in which a drive shaft is arranged at an angle with respect to the axial direction of the valve and the drive movement via a suitable gear mechanism on a closing piece movable in axial direction transferred.

Valves, slides, valves and taps are nowadays used as shut-off valves for general industrial applications. Tents have the advantage of a simple and reliable sealing on the seat, but their construction length and flow resistance are relatively large. Valves have the smallest construction length and lead to relatively low resistance values, but their sealing to the seat is subject to increased wear due to the dragging engagement 15.

The closing valves used are designed either as straight or oblique valves, i.e. the lifting movement takes place either perpendicularly or at an angle of up to 45 ° to the valve longitudinal axis.

20 axial shut-off valves, such as e.g. Known from U.S. Patent 2,266,485 and German Patent 1,060,683 are commonly used as control fixtures and are therefore expensive and of great construction length. The high cost is due to the usually very special requirements placed on such valves in view of the behavior when the supply is to be throttled and in order to adapt to the case-by-case characteristics.

The object of the invention is now to provide a relatively simple shut-off valve with a low resistance value for shut-off purposes. According to the invention it is proposed for this purpose that a disk wheel comprises a hub designed as a support tap bearing with an axially extending, internally threaded bore for receiving a tailpiece spindle, in which the lateral surface of the hub is designed as a radial bearing 8005218-2 and the front side of the hub as an axial bearing, while a plane containing the drive shaft perpendicular to the valve axis, intersects the hub.

For this solution, it has been succeeded in providing an axial direction closing valve, the resistance of which is considerably below that of the known and conventional valves. Furthermore, a construction length could be realized, as was usually only possible with shut-off valves, but not with valves.

In accordance with another constructive solution according to the invention, it is provided that a disk wheel comprises a hub designed as a support tap bearing with an axially extending bore for receiving a bearing tap, the lateral surface of said bore as radial bearing and the bottom of 15, which are designed as axial bearings, while the lateral surface of the hub is threaded for actuating the breech, and a plane perpendicular to the valve axis containing the drive shaft intersects the hub. However, a further, further elaboration according to the invention is also possible, in which one long hubs, or mutually differently long hubs on either side of the disk wheel, are arranged on the sole wheel, the lateral surface of the longest hub being threaded for actuation of the breech block and the shortest hub is designed as bearing location 25, while a plane perpendicular to the valve shaft, containing the drive shaft, cuts the longest hub. These embodiments are alternative, constructive solutions and realizations of the inventive idea.

Measures embodying further, alternative solutions according to the invention are set forth in the distinctive characterizing parts of claims 4-7.

The invention will now be further elucidated with reference to the drawing, in which various embodiments according to the invention are shown by way of example only for the invention.

8 0 C 5 2 1 8 * · w «- 3 -

Fig. 1 shows an embodiment with a non-pressure-relieved closing piece; Fig. 2 shows an embodiment with a pressure relief bonnet and a divided hub; Fig. 3 shows a hermetic seal of the gear and the alloy with respect to the flow medium; Fig. 4 shows an embodiment in which the piston action of the closing piece is compensated for; Fig. 5 shows a hub of the disc wheel mounted on an army stud; Fig. 6 shows a disk wheel provided with two hubs; Fig. 7 shows a similar embodiment to Fig. 6, but with a different alloy of the closing piece; Fig. 8 shows a disk wheel with helically rising toothing; and FIG. 9 shows a screw gear for actuating the breech.

In the exemplary embodiment according to Fig. 1, inside the housing 1 there is a hollow body 2, which is advantageously shaped in flow-technical view, in which a bevel gear gear mechanism, consisting of a pinion 3 and a disc wheel 4, is arranged. The pinion 3 is mounted on a drive shaft 5, which is actuated here by a hand wheel. The disc wheel 4 is provided with an elongated hub 7 formed as a supporting pin. Eat a spherical end 8. The hub 7 is in turn alloyed with sufficient play in the attachment part 9 of the hollow body 2. When the closing piece 10 with its sealing surface 11 abutting a housing sealing surface 12, power transmission takes place via a wedge spindle 13 on the disk wheel 4, this being then, on the basis of the hub designed as supporting stud bearing, with the convex surface 8 against an bearing surface 14 of the hollow body 2 is pressed. A locking element 15 is provided on the hub 7 for locking the disk wheel 4 in the axial direction. Rotation of the closing piece is prevented by a pin 16 arranged in the hollow body 2. The axial movability of the drive shaft 5 is limited by the fact that its end mounted in the housing is convex and runs against the attachment part 9.

When e.g. the contact of the sealing surface by the closing piece 10 and the sealing surface 12 of the housing 1 takes place not parallel but one-sided, the closing piece 10 adjusts as a result of the spherical surface 8 acting as an axial bearing and of the play between the radial Attachment portion 9 and hub 7 to the sleeve sealing surface 12 are active.

Since the friction radius between the spherical plane 3 and the flat plane 14 approaches zero, the frictional moment produced by the axial force in the axial bearing is very small. For easier adaptation of the closing piece 10 against the housing sealing surface 12, it is also possible to create a hinge connection between the closing piece 10 and the spindle 13 without any harm. The housing sealing surface 12 can optionally be made elastic or rigid.

The exemplary embodiment according to Fig. 2 shows a closing piece 10, which is sealed relative to the hollow body 2 by means of seals 17 and contains bores 18 for pressure equalization. The sealing of the closing piece 10 with respect to the housing 1 here takes place by means of a seat ring 19 arranged in the closing piece 10. Additional measures are possible to reduce the risk of contamination, e.g. elements which do not impede the escape of liquid from the internal space of the hollow body 2, which elements are present in the form of sieves. In this exemplary embodiment, the hub 7 acting as a support tap bearing is of two-part design, in which the spherical surface 8 acting as axial bearing 30 is formed by a separate bearing stone 20. In this exemplary embodiment, the position of the hub 7 is secured via the extended end. 21 of the shaft 5, which engages in a groove 22 of the hub 7.

Pig. 3 shows a similar embodiment to FIG. 1, with the difference, however, that the internal space of the hollow body 2 is sealed by means of a crimped collar 23 and the closing piece 10. The collar 23 is connected at one end to the closing piece 10 and at its other end to the hollow body 2 via a screw piece 24. The bellows 23 also acts as a lock against the rotation for the closing piece 10.

Under the apparatus shown, understandably, metal pleated bellows would be used.

The pressure equalization in the interior of the cavity can then take place via the stuffing box 25 which is exclusively provided for security and is not tightened completely. For the case of pleated bellows made of elastomers, versions with internally pressurized bellows or guides or support arrangements are of outside, pressure-loaded bellows conceivable.

For the pressure equalization, when the internal space of the hollow body 2 is sealed, the solution shown therein is provided in the exemplary embodiment according to Fig. 4. The hollow body 2 is here tubular, in which the closing piece 10 is mounted in the one end and sealed by means of O-ring 26, and a movable cover 27 is arranged on the other end and also by means of an O-ring 28 is sealed with respect to the hollow body 2. The closing piece 10 is moreover fixedly connected to the lid 27, so that when the closing piece moves, the lid follows this movement forcibly and so the space in the interior of the hollow body 2 remains the same. Of course, other types of seals are also possible.

Fig. 5 shows an alternative solution according to the inventive idea, in which the hub 7 of the disk wheel u 4 is provided with a recess which, together with an alloy spigot 29, acts as a radial and axial bearing. The tap 29 is fixedly connected to the hollow body 2 and thereby also fixedly connected to the housing 1. The movement of the closing piece 10 is effected by means of a movement thread, 8000218 - <$ -, which is mounted on the hub 7, and which interacts with a moving screw thread in the interior of the closing piece spindle 30 of the closing piece 10, which is tubular here. The tubular closing piece spindle 30 is also alloyed again in an insert 31, which in turn is fixed in the hollow body 2. The seal 32, which protects the inner gear parts, bearings and guides against contamination, can e.g. are designed as a lip seal. Thus, the penetration of flow media into the interior space when closing the valve is hereby prevented, without, however, allowing the pressure in the interior region to increase as a result of the piston action of the tubular closing spindle 30. The insert 31 is furthermore designed in such a way that it also serves for the axial fixing of the disk wheel 4. * As a locking against rotation of the closing piece 10, an elongated end 21 of the end piece 21 functions here, as in the embodiment according to FIG. drive shaft 5 »d $ t interacts with a longitudinal groove 33 of the tubular bobbin spindle 30.

The seal 32 can also be used to seal the flow medium from the atmosphere.

In such a case, the outer spindle seal is e.g. in the form of a stuffing tube seal 25 only an emergency seal. This will hardly come into effect during normal use and can thus allow equalization of the volume displaced by the lifting movement of the valve disc.

Fig. 6 also shows an embodiment in which the cup wheel is provided with two mutually different hubs 7, 34. The cup wheel 4 is here bearing the longest hub 7 radially in the internal thread of the tubular closing spindle 30. The closing piece 10 itself is alloyed with its outer diameter in the hollow body 2. The shortest hub 34 here serves for axial alloy of the disk wheel 4. The axial locking of the disk wheel 4 is effected by means of the pinion 3 · 35 The embodiment according to fig. 7 shows an alloy of 80 52 1 8 * * - 7 - the closing piece 10 similar to FIG. 5, with the difference, however, that the locking against rotation of the closing piece 10 here takes place by means of a pin 35, which cooperates with a rib 36. As in the embodiment according to FIG. 6, the disk wheel 4 here comprises two hubs 7 and 34, the shortest hub 34 absorbing both axial and radial bearing forces.

A very simple embodiment is shown in Fig. 8. The disk wheel 34 here is provided with hubs 7 »54» arranged on both sides, the one hub 7 being provided with the moving thread of the closing piece 10 and also serving. for radial alloy, and the other hub 34 receives only the closing piece 10. The disk wheel 4 is designed in such a way that the toothing is arranged on a screw thread 57 and the pitch of the screw thread 37 is equal to or greater than the stroke of the closing piece 10.

In the embodiment according to Fig. 9, a helical gear or also a rack gear is used as the toothing. The closing piece 10 is here again mounted in the hollow body 2.

8005218

Claims (7)

1. Mechanical, forced-actuated, axial closing valve, wherein a drive shaft is arranged at an angle to the axial direction of the valve and the driving movement is transmitted via an appropriate gear to a closing piece which can move in the axial direction, with the characterized in that a disk wheel (4) comprises a hub (7) designed as a support-tapping bearing, with an axially extending internal threaded bore for receiving a bobbin spindle (13), the lateral surface of the hub (7) as a radial bearing and the front side of the hub (7) is designed as an axial bearing, while a plane perpendicular to the valve axis containing the drive shaft (5) cuts the hub (7). 2. Mechanical, forced-actuated, axial closing valve, wherein a drive shaft is arranged at an angle with respect to the axial direction of the valve and the driving movement is transferred via a suitable gear to an axially movable closing piece, with characterized in that a disk wheel (4) comprises a hub (7) in the form of a support trunnion bearing with axially extending bore for receiving an alloy stud (29), the lateral surface of the bore as radial bearing and the bottom of the bore designed as an axial bearing, while the lateral surface of the hub (7) contains a screw thread for actuating the closing piece (10) and a plane perpendicular to the valve axis, the drive shaft (5) comprising the hub ( 7) cuts. 3. Mechanical, forced-actuated, axial closing valve with a drive shaft mounted at an angle to the axial direction of the valve and the. drive movement is transferred via a suitable gear to an end piece movable in the axial direction, characterized in that a long hub on the disc wheel (4) or on both sides of the disc wheel has different lengths 8005218 - 9 - * »strings (7» 34) is arranged, the lateral surface of the longest hub (7) having a screw thread for actuating the breech (10) and the shortest hub (34) being designed as a bearing location, while a vertical position on the valve shaft upright, the drive shaft containing the plane cuts the longest hub (7), 4. Closing valve according to claim 3, characterized in that the cup wheel (4) is fixedly or movably connected to the cap (10), the cup wheel (4) has a hub (7) designed as a support tap bearing, on the lateral surface of which a thread acting as an army is arranged, while the disk wheel (4) is provided with a helical toothing (37) circumferentially 5. Closing valve according to at least one of the preceding claims, characterized in that at least one housing opening is the same size or larger than the closing piece diameter. Closing valve according to at least one of the preceding claims, characterized in that the axial bearing (34) is provided with a convex tread (8), Closing valve according to at least one of the preceding claims, characterized in that a driving device is provided, the toothing of which is designed as a worm, screw or rack gear, 8005218