DE1239154B - Shut-off device for line systems serving to guide mass particles - Google Patents

Description

Shut-off device for pipe systems used to guide mass particles In systems working with fine-grained mass particles, such as B heat exchanger systems or chemical plants, shut-off devices are required in the line systems, which on the one hand prevent a flow of mass particles, on the other hand after an interruption the mass particle flow, the parts of the pipeline system carrying different pressures seal gas-tight against each other. For such shut-off devices result Requirements that are difficult to meet in various respects, especially those resulting from that also through the presence of the granular mass particles in the line parts a completely gas-tight seal must not be disturbed. Impairments the sealing surfaces by the mass particles in that they move when they move of the closure part between the latter and the sealing surface must to be excluded with certainty; because like the experience with the known Shut-off valves for lock chambers with conical closure bodies that pass through Raising or lowering compared to massive funnel-shaped end walls in a final position are moved, show, result in the case of sticking only individual granular ones Particles between the closure body and the sealing surfaces disturbances that are significant Leaks and, after a short time, such shut-off devices becoming unusable have as a consequence. These disadvantages can also be avoided despite the use of pre-shutdown devices, which interrupt the flow of mass particles in front of the gas-tight main shut-off, with certainty do not avoid.

The invention relates to the simple design of shut-off devices in conduit systems serving to guide mass particles and for gas-tight shut-off of the parts of the pipeline system carrying different pressures, with the disadvantages the aforementioned known shut-off devices for gases and granular mass particles leading Line systems are avoided. The invention proceeds from one for this purpose Shut-off device with a sealing ring having at least one labyrinth cutting edge and consists in the fact that the closure part has a tight seal under the Influence of the pressure enabling resilient sealing collar and thereby the arrangement is made such that the above the resilient sealing collar arranged (n) labyrinth cutting edge (s) and the one arranged below the sealing ring resilient sealing collar when bringing about the conclusion an additional relative movement run parallel to each other. It is characteristic of the mode of operation of the invention that that due to this additional movement on the sealing collar possibly existing granular Mass particles are displaced so that the entrapment of mass particles is prevented and a gas-tight seal on the labyrinth cutting edges is achieved with certainty.

In the following the invention will be explained with reference to the drawing.

F i g. 1 shows an embodiment that relates to the training refers to a lock chamber, of which the upper closing organ in the drawing is reproduced; in Fig. 2 is a modification of the arrangement according to FIG. 1 shown.

In the embodiment of FIG. 1 means 1 the housing of a Lock chamber, which is only indicated in its upper part in the drawing. on The lock chamber is closed on its upper side by the cover 2. 3 is an inlet opening into which, if necessary, mass particles through the inlet nozzle 4 as well as gas can flow. 5 means a rotary valve housing placed on the connecting piece 4, whose rotary valve 6 blocks the flow of mass particles through the supply pipe 6 a makes possible.

In order to be able to shut off the interior of the lock chamber in a gas-tight manner with respect to the nozzle 4 or the rotary valve chamber 5 after the mass particle supply has been shut off by the rotary valve 6, the opening 3 is assigned a shut-off element 7. This gas shut-off device consists on the one hand of the sealing ring 9 which is connected to the cover 2 with the inclusion of a seal 8 and which is provided with concentric sealing cutting edges 10 and a support edge 11. The sealing cutting edges 10 and the support ring 11 are arranged concentrically to one another and have a considerable distance, as a result of which circular gaps are formed between them. In addition, the shut-off element is formed by the plate-shaped closure piece 12. On the outer circumference, the plate-shaped closure piece has, on its side opposite the sealing ring 9, a protruding resilient sealing collar 13 made of a heat-resistant alloy, e.g. B. Thermal. The resilient sealing ring 13 is held on a partially slightly conical fastening part 13 a, which is clamped in a recess 12 a of the plate-shaped locking piece 12 by a retaining ring 14 a fastened to the locking piece by means of screws 14. It can be seen that when the closure piece 12 is moved into the closing position, the resilient sealing collar rests against the labyrinth cutting edges of the sealing ring, whereby the lock chamber space is closed off from the connector 4 . The closure piece or the retaining ring then rests against the annular stop 11 of the labyrinth ring 9. If the lock chamber is now brought into connection with a higher pressure chamber than is present in the nozzle chamber 4, the gate valve chamber 5 or the supply line 6 a, the gas pressure causes the resilient sealing collar to become through the opening of the closing element located on the lower side of the lock pressed with great force against the cutting edges 9 of the labyrinth sealing ring 8, the spacing of which ensures permissible stresses in the spring collar. In this arrangement, the closure piece 12 is driven by a drive 15 in such a way that the plate 12 can be removed from or moved into the locking position in a rotary stroke movement. The drive 15 consists essentially of the pivot lever arm 16, the drive shaft 17 and the drive crank 18. The pivot axis of the closure piece is inclined at an angle greater than the angle of friction. The pivot lever, the hub 16 a of which is coupled to the hollow shaft 1 by a fitting bolt, consists essentially of a leaf spring-like lever arm 16. The latter carries at its end on a spring part 16 c welded to it with limited spring travel a skirting 16 d, with which the plate-shaped closure piece 12 is connected by screws 19. The construction of the swivel arm 16 from resilient parts, which allow movement in planes perpendicular to each other, creates the possibility that the plate-shaped closure piece can be adjusted universally in order to take into account any changes in shape that result from thermal expansion.

The shaft 17 is guided in the bearings 22, 23 in the attachment 24 on the cover 2 of the lock chamber. The weight of the shaft 17 including the associated pivot lever and the locking piece is transferred via a flange-like support body 26 rigidly connected to the shaft 17 to the suspension spring 25, which is supported on the one hand on the intermediate cover 24 a of the housing attachment 24 , on the other hand against the spring plate 28 . A needle bearing 27 is connected between the spring plate and the support body 26. The support body 26 is provided with a cam collar 26 a to adjust the height of the shaft 17. The latter slides on a guide roller 30 which is attached to the upper end cover 24 b of the attachment 24. As can be seen, a displacement of the shaft 17 and the plate-shaped end part 12 connected to it via the pivot lever 16 can be brought about by a corresponding design of the guide curve of the collar 26 a when the shaft 17 connected to the support body 26 is rotated, in such a way that at the end of the movement of the closure piece in the closed position the same executes a rotary stroke movement instead of a simple pivoting movement, whereby first the resilient sealing collar rests against the labyrinth cutting edges and finally the retaining ring 15 rests against the stop part of the labyrinth ring.

As already indicated, the shaft 17 for the engine 15 can be made hollow in order to ensure cooling of the shaft and the bearing points with regard to the high temperatures. 40 means a line for the coolant duct, 41 are coolant drainage slots.

Of course, the lock chamber also needs in its lower one Part of a Absehlußorgan, which is basically designed in the same way can, like the closing organ shown in the figure of the drawing.

To the plate-shaped closure piece and in particular the resilient To be able to maintain or replace the sealing collar is advantageous in that Lid 2 of the lock chamber has an opening 50 that can be closed by a lid, which enables - if necessary after swiveling out the locking piece - to provide for the necessary overhaul work.

Details of the described arrangement can be carried out differently will. This applies, for example, to the drive device of the closure piece or the resilient sealing collar or the formation of the labyrinth sealing ring. The latter can, under certain circumstances, also be provided with a cooling system, such as the hollow drive shaft, be provided.

F i g. 2 of the drawing shows such a schematic sketch modified version of a closing organ for a lock chamber again, at which the closure piece is adjusted only by a simple lifting device. In the embodiment of FIG. 2 has the sealing ring 9 with the labyrinth cutting edges 9 ä an elongated opening 29. The closure piece connected to a drive spindle 34 31 is curved on its lower side, so that the resilient sealing collar 32, which protrude beyond the closure piece 31, a considerable amount relative to the horizontal Have a tendency. With 35 the feed channel for the mass particles is also referred to, 36 means the cylindrical lock chamber, 37 an outer one which is used for support Frame.

Of course, the design of the sealing ring and the shape of the labyrinth cutting edges provided on it must also be adapted to the inclination of the resilient sealing collar 32. Expediently, with the arrangement according to FIG. 2 with a rectangular passage cross-section, round off both the sealing ring, closure piece and the protruding resilient sealing collar at the transition to the narrow sides of the closing opening with a larger radius of curvature in order to limit the material stresses in the resilient sealing collar in the area of the narrow sides. In the arrangement according to FIG. 2, the locking piece 31 only needs to be raised or lowered in the vertical direction by a lifting device. 33 is another filler body that fills the free space of the lock chamber and enables the gas content of the lock chamber to be reduced. The arrangement according to FIG. 2 is particularly suitable when the lock chamber - for example for several mass particle flows of different temperatures - is divided into smaller sections in the direction of the longitudinal extent of the opening 29 by several transverse walls.

Claims (10)

Claims: 1. Device for locking in for the management of Line systems serving mass particles through which, after interruption of the mass particle flow the different pressures leading parts of the line system gas-tight against each other can be concluded, d a -characterized in that they are known per se Way on the one hand from a sealing ring having at least one labyrinth cutting edge and on the other hand a closure part with a tight seal under the influence the pressure enabling resilient sealing collar is formed and that the above of the resilient sealing collar arranged (n) labyrinth cutting edge (s) opposite the resilient sealing collar arranged below the sealing ring when brought about of the conclusion one - apart from one directed perpendicular to the sealing surface Movement - perform additional relative movement parallel to each other. 2. Establishment according to claim 1 with vertical movement of the closure piece, characterized in that that the cooperating with the labyrinth cutting parts of the resilient sealing collar are inclined at an angle to the direction of movement of the closure piece. 3. Device according to claim 1, characterized in that to limit the closing movement of the closure piece a known stop part is provided to which the closure piece only after the sealing cutting edge has hit the springy one Can apply sealing collar. 4. Device according to claim 1, characterized in that that in a manner known per se when the sealing cutting edges are arranged in one plane and with a corresponding planar design of the closure piece, the arrangement is such it is taken that the sealing plane has an inclination with respect to the horizontal, which is above the angle of friction (angle of repose). 5. Device according to claim 1, characterized in that a device known per se for shut-off devices is provided, mass particles stuck to the sealing surfaces on mechanical or pneumatically. 6. Device according to claim 1, characterized in that that the closure piece via a swivel arm of a rotatable and height-adjustable, is carried laterally next to the opening to be closed, the shaft depending on the rotary movement in its altitude through a curve guide is adjusted. 7. Device according to claim 6, characterized by such Formation of a curve guide for the control of the swivel arm that the locking piece when moving into the final position, a large one in relation to the lifting movement Rotary movement executes, on the other hand, initially only when moving out of the final position is subjected to a lifting movement. B. Device according to Claim 1, 6 and 7, characterized characterized in that the resilient sealing collar of the closure piece by means of a conical ring collar on a corresponding conical surface of the rigid closure body part fastened by a retaining ring embedded in a recess in the latter is. 9. Device according to claim 6 or 7, characterized in that the the The swivel arm carrying the locking piece is constructed from spring members, one on all sides enable movable resilient adjustment of the closure piece. 10. Establishment according to claim 2, characterized in that the one for shutting off an approximately rectangular Cross-section serving closure piece has a curved design and with a on the long sides inclined protruding spring collar is provided, the sealing ring and the labyrinth cutting edges have a correspondingly inclined position. Into consideration printed publications: German Patent Specifications No. 568 413, 845133; Austrian U.S. Patent No. 156,309; Swiss Patent No. 1211; French patents No. 487 311, 729 999, 1282 630; U.S. Patent No. 1598 288.