CH637085A5 - Cellular lock - Google Patents

Description

The invention relates to a cell lock, in particular for a pneumatic conveyor system, with a rotating body, which is mounted in a housing and has at least one radially outwardly open cell and which is located between an inlet and an outlet of the housing, which lie on the path of the cell opening, opposite the Housing 15 is sealed and blocks the passage in any position.

The known cell locks of this type mostly have rotating bodies made of two parallel circular disks, between which radial bulkheads form the cells. The housing is tight on all sides of the rotating body. The aforementioned bulkheads run along it with their end faces, which can carry any sealing strip. The circular discs often have a kind of labyrinth seal with the housing.

These cell locks are operational up to about 0.8 atm pressure difference between their entrance and their exit. At higher pressures, the permeability becomes too great, especially on the end faces of the bulkheads and in the corner edges between the casing and the side walls of the housing.

In order to be able to work with higher pressures, you have to switch to other solutions. When emptying a building material silo for penumatic delivery to cleaning machines, e.g. the material falls in batches from the silo into an intermediate vessel attached below, then seals it off from the silo and then pneumatically feeds it at around 2 atm pressure. A dense cell lock would be far preferable.

The invention has for its object to provide a cell lock that allows larger pressure differences between 40 see their entrance and exit.

The cell lock according to the invention matches the known cell locks in the combination of features specified at the outset and differs from them in that the rotating body is an at least partially hollow ball which is located between two sealing rings arranged near the entrance and exit of the housing and which is used as a cell opening (s ) has a cutout or cutouts in the ball jacket in such an arrangement that in each rotational position of the ball one of the two sealing rings 50 abuts the ball surface all around.

This is the construction principle of the ball valve, applied to a cell lock. The ball valve has proven to be by far the most reliable and tightest shut-off device in pneumatic conveying. Its own 55 shafts are transferred here to a cell lock.

The blocking of the passage in any position of the ball means that, unlike the ball valve, the ball lock must firstly not provide a passage and secondly only one cell opening may cross a 60 of the two sealing rings, otherwise the space between the ball , the housing and the sealing rings at the entrance as well as at the exit of the lock would be accessible and thus offer a passage. One of the two sealing rings is always fully in contact with the ball, so that the cell lock is closed and sealed over its entire cross-section. The sealing ring remains unchanged, the ball slides past it with a constant surface, and the contact pressure can, only

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by axially pressing on the two sealing rings, between which the ball sits, set fairly high and can also be readjusted when worn. This results in a much better sealing effect than in the prior art. The new cell lock allows pressure differences of 2 to 4 atm. The tightness is also independent of the temperature of the material being conveyed; the sealing rings can absorb thermal expansion of the ball.

A particularly simple, expedient embodiment of the invention consists in the ball having only one cell essentially of the entire volume of the ball. So the sphere has only one cutout as a cell opening. The diameter of this cell opening can have approximately the size of the inner diameter of the sealing rings.

To increase the continuity of conveyance, however, the ball can also be provided with two opposing cells, the cell openings of which essentially extend only on one side of a cutting plane that is longitudinally through the axis of rotation of the ball, so that they do not simultaneously cross one of the sealing rings. In order to make the cell openings as large as possible, they can be given an approximately semicircular cross section with a diameter approximately the size of the inner diameter of the sealing rings.

Instead, the sphere can also be provided with two opposing cells with cell openings lying essentially on a spherical axis, into which lids of the shape of the cut-out spherical shell part can be inserted from the inside, so that an uninterrupted spherical surface is provided when the lid is inserted. The cells and the covers are then preferably designed as pistons and cylinders. The pistons can be movable by a mechanism, the movement of which is derived from the rotation of the ball relative to a fixed axis engaging in it. The pistons can also be moved by pneumatics or hydraulics, which are fed by a line inserted into the ball on the axis of rotation. The cell openings lying on a spherical axis preferably have a smaller diameter than the sealing rings, so that there is time to open or close the cell while the opening is inside a sealing ring as it rotates.

The ball is preferably mounted on one side by means of a drive shaft and on the other side by means of a fixed axle. However, the latter axis is not absolutely necessary, since the ball already has a defined fit due to the two sealing rings.

The housing preferably consists of a cylinder jacket and two annular end walls, which press the sealing rings arranged in the corners of the housing cross section into contact with the end walls, the cylinder jacket and the ball and which are axially adjustable relative to the cylinder jacket. By adjusting the end walls in relation to the cylinder jacket, wear on the sealing rings can be compensated. The sealing rings themselves take on the necessary seal between the end walls and the cylinder jacket; in the proposed arrangement, the sealing rings are naturally also pressed against the cylinder jacket. However, the seal can also be reinforced here by forming a sealing lip on the edge of the sealing ring, which is pressed against the cylinder jacket by the pressure of the medium which arises in the space in question.

Finally, it is proposed as a particularly advantageous embodiment of such a cell lock to mount it directly above a ventilation floor at the beginning of a pneumatic delivery line for emptying a building material silo and supplying cleaning machines.

The cell lock is much lighter, smaller and more manageable and therefore easier to assemble than the intermediate container mentioned above. The construction height of the building material silo can be reduced and thus the stability increased. In addition, the cell lock is much cheaper than the intermediate container.

The drawings show exemplary embodiments of the invention.

Fig. 1 shows a cell lock in a vertical section.

Fig. 2 shows another cell lock in a vertical section.

Fig. 3 shows a further cell lock in a vertical section.

At the lower end 1 of a standing silo filled with plaster of Paris, which runs out in the shape of a funnel, a closure flap 2 with its frame 3 is flanged on by hand. It is drawn in the open position.

In the same way, a cell lock 4 is attached to the frame 3 of the closure flap.

The cell lock 4 essentially consists of a housing 5, a rotating body 6 mounted therein and a drive 7 for the rotating body located on the side of the housing.

The housing 5 is composed of a cylinder jacket 8 and two annular end walls 9 and 10, which engage with annular projections 11 in the cylinder jacket 8 and are screwed to flanges of the cylinder jacket 8 at 12. The upper end wall 9 is provided with a funnel 13; this forms the transition from the frame 3 of the closure flap to the housing 5. A pneumatic conveyor unit 14 sits on the lower end wall 10.

Both end walls 9 and 10 hold between their annular extension 11 and a bend 15 on their inner circumference a sealing ring 16, e.g. made of Teflon, a. The sealing ring 16 extends outward beyond the extension 11 to the cylinder jacket 8. Here it lies on part of the axial height with a lip 17 which is formed by a groove 18. Towards the center of the housing, the two sealing rings 16 have an inclined contact surface 19 for the rotating body 6.

The rotating body 6 is a hollow ball, e.g. of 20 1 space, with a circular opening 20 approximately of the inside diameter of the end walls 9 and 10. It is supported on one side by a drive shaft 21 and on the other side by a fixed axis 22, both of which from inside the cylinder jacket 8 Support

Intervene 23 and 24 of the hollow sphere. The drive shaft 21 is sealed off from the housing 8 by a sealing ring 25, which surrounds it outside the cylinder jacket 8 in a bushing 26 welded to it. A seal against the ball is not provided. The drive shaft 21 is simply inserted into the socket 23 and is connected to it in a rotationally fixed manner by a spring 27. The nozzle forming the pivot bearing for the fixed axis 22

24 is closed at the inner end; the axis 22 sits close to the housing 8.

The drive 7 is a geared motor screwed to a flange 28 of the mentioned bushing 26 with, for example, two rpm on its output shaft, which serves as the drive shaft 21 of the rotating body.

The pneumatic conveying unit 14 comprises a pot 29 seated on the lower end wall 10, a ventilation base 30 arranged obliquely in the latter, a compressed air supply 31 and

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a connection 32 leading out of the pot 29 on the other side for a delivery line.

The procedure is as follows:

The rotating body 6 consisting of the hollow ball is continuously rotated by the drive shaft 21.

If the opening 20 moves into the upper sealing ring 16, material falls from the lower end 1 of the silo into the hollow ball and fills it. If the opening 20 moves into the lower sealing ring 16, the material falls from the hollow ball into the pot 29, where it is caught by the compressed air flowing in through the compressed air supply 31 and passing through the ventilation base 30 and discharged into the connection 32 of the delivery line. If necessary, the emptying of the hollow sphere can be supported by blowing compressed air through the axis 22 and the nozzle 24, which can be set up for this in a simple manner. The cross section of the housing 5 is always closed, either on the lower sealing ring 16 or on the upper sealing ring 16. The opening 20 crosses only one of the two; their diameter is smaller than the distance between the two sealing rings. If the opening 20 crosses the lower sealing ring 16, the space between the hollow ball and the housing wall is placed under the compressed air pressure as well as the inside of the hollow ball. The pressure then presses the lips 17 against the cylinder jacket 8 and thus reinforces the seal itself. The pressing force required on the contact surfaces 19 of the sealing rings with respect to the hollow ball comes from the screw connections 12, which can always be readjusted when the sealing ring wears out. The pressure of the sealing ring against the ball, due to the inclined position of the contact surface relative to the pressing force, creates a force acting outwards in the sealing ring, which leads to a further pressing against the cylinder jacket 8.

If the opening 20 crosses the upper sealing ring 16, the cavity of the ball and the gap between the ball and the housing are expanded upwards into the silo. At the lower sealing ring 16, the housing 5 is closed by the spherical jacket.

The cell lock shown in FIG. 2 has a slightly modified rotating body 33 instead of the rotating body 6

on. Otherwise, their structure is as described above. The same parts have the same reference numerals.

The rotating body 33 is again a hollow sphere, but with two cells 34. The openings 35 of the cells 5 are both on the same side of the central axis of the sphere; they each occupy approximately half of the opening 20 in the rotating body 6. In the drawing, this arrangement is shown rotated by 90 °, as indicated in the middle by the curved arrow. The result of this is that only one opening io 35 crosses a sealing ring 16 and the housing cross section is always closed on the other sealing ring 16.

FIG. 3 shows a third rotating body 36 in a cell lock of otherwise the same grand structure.

It also has two cells 37, but with opposing cell openings 38. The cells 37 are designed as cylinders in which pistons 39 can be displaced. The pistons carry spherical caps 40 in the form of the spherical shell section missing from the cell openings 38. 2o Both pistons 39 sit on a common piston rod 41 which is guided through a pneumatic cylinder 42 and is displaceable by this; the pneumatic cylinder 42 is held and fed via a coaxial line 43 which is in turn held by the connection piece 24 and through this as well as through 25 the fixed axis 22 out of the housing.

Whenever the two cell openings 38 have reached the rings 16, the two pistons 39 are shifted from their 30 one end position into the other by appropriate control of the pneumatics. The cell 37 is released at the top for the material intake and the material is ejected from the cell at the bottom and the spherical surface is closed by the spherical cap 40. When it subsequently emerges from the lower sealing ring 35 16, the housing cross section remains closed here, likewise later when it enters the upper sealing ring 16. Only when the openings 38 are completely in the inner circumference of the sealing rings does the pneumatic cylinder 42 move the pistons after the other Page. So that time 40 remains enough for this process, the diameter of the cell openings 38 is somewhat smaller than the inner diameter of the sealing rings 16.

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2 sheets of drawings

Claims (13)

637085 1. Cell lock, in particular for a pneumatic conveyor system, with a rotating body, which is mounted in a housing and has at least one radially outwardly open cell and is sealed off from the housing between an inlet and an outlet of the housing, which lie on the path of the cell opening and blocks the passage in any position, characterized in that that the rotating body (6; 33; 36) is an at least partially hollow ball which is seated between two sealing rings (16) arranged near the inlet and outlet of the housing and which, as the cell opening (s) (20; 35; 38), is a cutout or Has cutouts in the ball casing in such an arrangement that one of the two sealing rings (16) bears all around on the surface of the ball in each rotational position of the ball. 2. Cell lock according to claim 1, characterized in that the ball (6) has only one cell essentially of the entire volume of the ball. 2nd PATENT CLAIMS 3. Cell lock according to claim 2, characterized in that the diameter of the cell opening (20) has approximately the size of the inner diameter of the sealing rings (16). 4. Cell lock according to claim 1, characterized in that the ball (33) has two opposite cells (34), the cell opening (35) extending substantially only on one side of a longitudinally through the axis of rotation of the ball (33) section plane and have approximately semicircular cross-section with a diameter approximately the size of the inner diameter of the sealing rings (16). 5. Cell lock according to claim 1, characterized in that the ball (36) has two opposing cells (37) with cell openings (38) lying essentially on a ball axis, into which from the inside cover (40) of the shape of the cut-out spherical shell part can be used. 6. Cell lock according to claim 5, characterized in that the cells (37) and the cover (40) are designed as pistons and cylinders. 7. Cell lock according to claim 6, characterized in that the pistons are movable by a mechanism, the movement of which derives from the rotation of the ball relative to a fixed axis engaging in it. 8. Cell lock according to claim 6, characterized in that the pistons (39) can be moved by a pneumatic (42) or hydraulic system which is fed by a line (43) introduced into the ball (36) on the axis of rotation (22). 9. Cell lock according to one of claims 5 to 8, characterized in that the diameter of the cell openings (38) has a smaller size than the inner diameter of the sealing rings (16). 10. Cell lock according to one of claims 1 to 9, characterized in that the ball (6; 33; 38) is mounted on one side by means of a drive shaft (21) and on the other side by means of a fixed axis (22). 11. Cell lock according to one of claims 1 to 10, characterized in that the housing (5) consists of a cylinder jacket (8) and two annular end walls (9) which in the corners of the housing cross-section in contact with the end walls (9) , press the cylinder jacket (8) and the ball (6; 33; 36) arranged sealing rings (16) on the ball (6; 33; 36) and the mante opposite the cylinder! (8) are axially adjustable. 12. Cell lock according to claim 11, characterized in that the sealing rings (16) abut on the cylinder jacket (8) with a sealing lip (17). 13. Use of a cell lock (4) according to one of claims 1 to 12 above a ventilation floor (30) at the beginning of a penumatic delivery line (32) for emptying a building material silo (1) and supplying plaster 5 machines.