EP0423572A1 - Apparatus for production of a pressure wave - Google Patents

Abstract

The invention relates to an apparatus for the intermittent production of a pressure wave in hoppers or other containers. For release of a pressure wave, a valve which, according to the invention, consists of a simple valve disc (10) between a storage housing (1) and an outlet pipe is opened suddenly. The opening of this passage by raising the valve disc (10) from the pipe (5) takes place in the usual manner by venting a pressure chamber (7) adjoining the valve disc (10). <IMAGE>

Description

The invention relates to a device for the intermittent generation of a pressure wave in silos or other containers, in which a tube for releasing the pressure waves, a storage housing surrounding the tube for the accumulation of compressed air and a flat sealing element are present, which in the charged idle state at the inner end of the Pipe is present, on the side facing away from the tube a pressure chamber, on one side with the internal pressure of the pressure chamber and on the other side outside the tube with the pressure of the accumulator housing and in the event of tripping by venting the pressure chamber to establish a connection between the accumulator housing and the pipe lifts up from the pipe end, the storage housing being fillable via a passage which encloses the pressure chamber.

From the European patent application 202 720 a device of this type is known, in which a valve plate can be moved within a nozzle, which alternately seals the tube for releasing the pressure waves or the outlet of the pressure chamber. There is a separate channel for filling the storage housing, which is operated using a separate valve. In addition, such a device is known from the French company Ermap, in which, instead of the disk sealingly guided in a pipe socket, a membrane is clamped above the valve-side pipe end, which closes off the pressure chamber. In order to avoid a separate line for filling the storage housing, the membrane has a calibrated bore outside the surface of the pipe for releasing the pressure waves. Filling takes place via the pressure chamber using the same opening through which the pressure chamber is also vented.

In the device from French production, a particular degree of simplification has been achieved, so that a relatively simple manufacture with reliable function is possible. The only part used is the membrane, which, due to the high load in the event of a pressure wave being triggered, must be carefully designed and made of high-quality material. The only serious disadvantage of this known device is that it takes a relatively long time to refill after the delivery of a pressure wave, because the entire amount of air has to flow through the calibrated bore in the membrane, which, for reasons of reliable function, must not be too large.

It is an object of the invention to improve a device of this type in such a way that very quick filling is possible while maintaining an uncomplicated structure, that is to say pressure waves can be emitted at the shortest possible intervals.

To achieve this object, the invention proposes that the flat sealing element is a non-clamped valve disc, the edge of which is elastic enough on the one hand to let the compressed air from the pressure chamber into the storage housing during filling, and on the other hand is stiff enough to hold the valve disc at least roughly center it.

In the German patent specification 24 02 001, a piston seal is presented on a device of the same type, which is designed to be air-permeable in one direction, but is sealing in the other direction. This requires the use of simple sealing sleeves, which are inherently due to their U-shaped cross-section and without exception have shaft. In the invention, however, the valve disc is designed in coordination with the pressure chamber, in such a way that, when it is filled, it lets the compressed air let into the pressure chamber enter the storage housing without any significant resistance, but on the other hand seals it so well against the pressure chamber that it seals in the case of venting the pressure chamber after a filling process, the inner opening of the tube for releasing the pressure waves is safely released. It is irrelevant whether the outer edge of the valve disc lies more or less close to the chamber wall, it is only important that the inflow of compressed air from the pressure chamber into the storage housing is not hindered and that there are leaks in the edge of the valve disc Trigger event does not lead to a backflow of the compressed air from the storage housing into the pressure chamber, but to the lifting of the valve disc from the inner end of the tube.

It has been shown that an extremely soft material quality can be selected for the outer edge of the valve disc, which may well have some ripple in the untensioned state. However, the rigidity must be of a certain minimum size so that the valve disc remains somewhat centered in the device, since the valve disc is preferably unguided except through the pressure chamber edge or the inner wall of the storage housing. If a very elastic quality is selected for the valve disc for cost reasons or for reasons of the particularly low masses, it may be expedient to reinforce the valve disc with a support disc which is arranged, for example, on the side of the valve disc facing away from the pipe end or as a core insert in the Valve disc is inserted.

In the event of triggering, the valve disk is lifted off the tube, so that an annular gap opens between the storage housing and the tube. The prestressed gas in the storage housing suddenly escapes through this annular gap, so that the intended pressure wave leaves the tube in a directed manner. The annular gap through which the contents of the storage housing are emptied in the event of a trigger should, for reasons of the fastest possible discharge, be designed so large that not the slightest disability occurs at this point.

The device can be charged for a triggering event in a few seconds because the filling is not hindered by a restriction or the like at any point. Due to the quick fillability, the number of devices required for emptying a silo can often be reduced. A prerequisite is, of course, a correspondingly generous amount of air to quickly fill the device.

It has been found that the valve disk only has to be held approximately in its position in order to keep it essentially centered. This simplifies the production even further, because blanks punched out of meter goods can be used as valve disks. A very precise central assignment of the pressure chamber to the pipe is not necessary, since this is not important. Even without a central position, there is the desired sealing at the respective points, so that extremely low demands must be placed on the precision of the device. This makes the manufacture cheaper.

It goes without saying that the valve disc must be stiff enough to withstand the differential pressure between the pressure chamber and the pipe in the charged idle state without any significant deformation. It has already been pointed out that the valve disk can be provided with a reinforcement, which should be light-weight for reasons of low inertia. Below such a support disc, the valve disc then acts as a pure seal, which provides a seal between the support disc and the inner tube end when the device is loaded. In the simplest case, the support disk is attached to the valve disk with a central rivet. The support disc consists, for example, of a circular aluminum plate.

It happens again and again that devices according to the invention are used on containers and lines that are exposed to high temperatures. It is then expedient to form the valve disk from a thin, flexible metal disk, the sealing then being effected by a temperature-resistant ring made of plastic, cork or even aluminum, which is fastened to the metal plate and points towards the inner end of the tube.

• Figur 1 eine schematische Querschnittsansicht durch ein erstes Ausführungsbeispiel eines Gerätes gemäß der Erfindung in Rohrausführung,
• Figur 2 eine Querschnittsansicht durch den oberen Teil eines Gerätes in einem weiteren Ausführungs­beispiel,
• Figur 3 eine Ansicht gemäß Figur 2 eines weiteren Ausführungsbeispiels,
• Figur 4 eine herausgezeichnete Ansicht einer Ventil­platte mit einer Verstärkungsplatte,
• Figur 5 eine Ansicht gemäß der Figur 4 mit einer eingelegten Stützplatte und
• Figur 6 eine Querschnittsansicht eines Teils eines weiteren Ausführungsbeispiels der Erfindung.

Exemplary embodiments of the invention which are illustrated in the drawing are explained in more detail below; show in the drawing:

• FIG. 1 shows a schematic cross-sectional view through a first exemplary embodiment of a device according to the invention in tubular design,
• FIG. 2 shows a cross-sectional view through the upper part of a device in a further exemplary embodiment,
• FIG. 3 shows a view according to FIG. 2 of a further exemplary embodiment,
• FIG. 4 shows a drawn-out view of a valve plate with a reinforcing plate,
• Figure 5 is a view according to Figure 4 with an inserted support plate and
• Figure 6 is a cross-sectional view of part of another embodiment of the invention.

The embodiment shown in Figure 1 of a device according to the invention consists of a tubular storage housing 1, which is closed at both ends with a lower cover 2 and an upper cover 3 with the aid of conventional screw connections. A tube 5 is welded into the lower cover 2, while there is an opening 4 in the upper cover 3. It is used to hold a valve or a line, at the end of which there is a valve, with the help of which filling with compressed air or quick ventilation is possible at this point. The tube 5 is used for releasing pressure waves, which in turn are used to loosen free-flowing material in silos or other containers that tend to form bridges, stick or are difficult to free-flow for other reasons.

A pressure chamber 7 is formed below the upper cover 3 with the aid of a pressure chamber housing 6 and is closed on its lower side by means of a valve disk 10. The wall 8 of the pressure chamber 7 has a smooth surface without abrupt transitions because it serves as a support surface for the valve disc 10 when pressure waves are emitted.

The exemplary embodiments shown in the figures of the drawing are available at predetermined locations on funnels or on the inner wall of storage containers or silos in single or multiple numbers and can emit a violent pressure jet in the form of a pressure wave, which has a dissolving effect on free-flowing bulk material. In order to emit such a pressure wave, the following operation of the device is required: Compressed air is admitted into the pressure chamber 7 via the valve already mentioned, which presses the slightly elastic valve disk 10 at the contact point with the pressure chamber housing 6 to release a passage gap. In this way, the storage housing 1 fills with compressed air, the valve disk 10 being pressed onto the inner end of the tube 5 in a sealing manner with increasing force due to the lack of counterpressure within the tube 5. After filling, the valve disk 10 returns to the starting position shown, in which its edge rests more or less loosely on the pressure chamber housing 6. At this contact point, there may even be residual gaps or small openings; the only thing that matters is that there are no openings that are too large in the contact zone.

If a pressure wave is to leave the device, the pressure chamber 7 is suddenly vented via said valve. Due to the lack of back pressure, the valve disc is moved towards the pressure chamber wall 8 by the air pressure present in the storage housing 1, the central portion of the valve disc 10 being naturally lifted off the inner end of the tube 5. The in the storage case 1 Collected air now leaves the device via the pipe 5 in a directed jet via the annular gap marked with "s". The valve disc assumes the shape shown in dashed lines. After the pressure wave has been released, the valve disk 10 returns to the starting position shown in solid lines on account of its own elasticity and dimensional stability. The process is now complete.

The area of the annular gap "s" should be chosen so that it corresponds approximately to the cross-sectional area of the tube 5. As a result, there is virtually no traffic jam at this point, which is conducive to rapid emptying of the storage housing 1 through the pipe 5. In addition, the light weight of the valve disc 10 ensures a particularly sudden release of the inner end of the tube 5 when triggered, which leads to excellent results. On the one hand, the pressure wave leaving the device is very strong, on the other hand, the range is considerable.

In the exemplary embodiments shown, the storage housing 1, the tube 5 and the valve disk 10 are circular and are arranged concentrically to one another. However, this is not a requirement. Rectangular or square shapes are also possible if appropriate installation conditions or the like call for these shapes. Regardless of the particular design, it can be seen that the valve disk 10 is subjected to practically no stresses, if one disregards the pressure on the end of the tube in the loaded idle state and the slight deflection during the emptying of the storage housing 1. Cheapest materials and simplest designs can therefore be preferred so that result in favorable manufacturing costs.

In the exemplary embodiments according to FIGS. 2, 3 and 6, the valve disk 10 is provided on its side facing the pressure chamber 7 with a support disk 11 which is fastened with the aid of a clip 20. In addition, a bulbous disk 21 can be provided to prevent the valve disk 10 from sliding off the clip 20. In this exemplary embodiment, the valve disk 10 is centered together with the support disk 11 by the storage housing 1, which is produced as a welded construction including a tube and flanges. The pressure chamber 7 is delimited by a pressure chamber housing 6, which consists of an internally conical ring with a bevel 15. Otherwise, the function is as described above, but the valve disc 10 forms a unit with the support disc 11, which is lifted from the inner end of the tube 5 when triggered.

The exemplary embodiment shown in FIG. 3 differs from the ones described above primarily in that the pressure chamber housing 6 is designed as a simple ring. In the event of tripping, the support disk 11 strikes the cover 3 of the storage housing 1, which does not further bother. When triggered, the elastic valve disk 10 rests against the inside of the chamber housing 6, which is designed as a ring, and returns to the state shown in FIG. 5 when it is filled.

In FIG. 4, the valve disk 10 and the support disk 11 are shown for clarification, connected by a clip 20 with a bulbous disk 21, in order to be able to recognize details more precisely. In the case of FIG illustrated embodiment, the support plate 11 is completely enclosed, that is covered by the elastic material of the valve plate 10 also on the side facing the pressure chamber. As a result, this exemplary embodiment is particularly suitable for pressure chambers 7 which are completely flat in themselves. The impact in the event of a trigger is well dampened.

The exemplary embodiment shown in FIG. 6 differs from the exemplary embodiments described above in that the valve disk 10 is held on the side facing away from the pressure chamber 7 with the aid of a support ring 22. The support ring 22 is welded to the storage housing 1 and bears openings 23 at intervals which let the air in the storage housing 1 pass when it is filled. If necessary. the valve disk 10 bulges slightly under pressure when filling between the tube 5 and the inside of the ring 22, so that the outer edge of the valve disk 10 is pulled slightly inwards. This opens the openings 23.

After filling, the valve disc 10, which can be made of a very elastic quality, again assumes the position shown in FIG. 6. The same applies after completion, during which the valve disk 10 is lifted off the tube 5. During this lifting too, the outer edge of the valve disk 10 is pulled slightly inward, but it remains in the region of the support ring 23, so that its position is ensured. In addition, a modification of the attachment of the support disk 11 to the valve disk 10 can be seen in FIG. 6, which primarily indicates that all possible attachments can be considered at this point.

The devices presented are generally only used when necessary because they have a relatively high air consumption and compressed air is relatively expensive. Another advantage of the device is that the valve disc 10 closes the tube 5 in the idle state, so that dusts located in the corresponding silo container cannot penetrate the device. A deposit within the tube 5 is harmless and does not last long; At the latest when the next pressure wave is released, these deposits are blown out.

Claims (11)

1. Apparatus for the intermittent generation of a pressure wave in silos or other containers, in which there is a tube for releasing the pressure waves, a storage housing surrounding the tube for the accumulation of compressed air and a flat sealing element which bears against the inner end of the tube in the charged idle state , on the side facing away from the tube, a pressure chamber seals, on one side the internal pressure of the pressure chamber and on the other side outside of the tube is subjected to the pressure of the accumulator housing, and in the event of tripping by venting the pressure chamber to establish a connection between the accumulator housing and the tube Pipe end lifts up, the storage housing being fillable via a passage that encloses the pressure chamber, characterized in that the flat sealing element is a non-clamped valve disc (10), the edge of which is elastic enough on the one hand to pressurize the compressed air from the pressure chamber (7 ) in the memory to leave here (1), and on the other hand is stiff enough to at least roughly center the valve disc (10). 2. Apparatus according to claim 1, characterized in that the pressure chamber (7) engages over the edge portion of the valve disc (10) or the storage housing (1) comprises the edge portion of the valve disc (10) and the valve disc (10) is otherwise unguided. 3. Device according to claim 1 or 2, characterized labeled in records that the valve disc (10) carries a stiffener in its central section. 4. Apparatus according to claim 3, characterized in that the stiffening is designed as a separate support disc (11) which is arranged on the side of the valve disc (10) facing away from the tube (5) and is attached to this. 5. Apparatus according to claim 4, characterized in that the support disc (11) consists of plastic or light metal. 6. Apparatus according to claim 4 or 5, characterized in that the support chamber edge facing the pressure chamber (7) is chamfered or the contour of the pressure chamber (7) is adapted. 7. Device according to one of the preceding claims, characterized in that the valve disc (10) consists of plastic or rubber. 8. Apparatus according to claim 7, characterized in that the valve disc (10) carries a fabric insert. 9. Device according to one of claims 1 to 4, characterized in that the valve disc (10) consists of a core plate made of steel, aluminum or a hard plastic with a polymeric coating. 10. Device according to one of the preceding claims, characterized in that the Gap area between pipe end and valve disc (10) when a pressure wave is emitted is at least as large as the cross-sectional area of the pipe (5). 11. Device according to one of the preceding claims, characterized in that the valve disc (10) consists of a thin, flexible metal plate, and that a temperature-resistant sealing ring made of plastic, cork or light metal is provided for sealing in the region of the tube (5).

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