DE1907147A1 - Silo cell for bulk goods - Google Patents

Description

Silo cell for bulk goods The invention relates to a silo cell for Bulk goods, the wall of the silo cell made in the known sliding construction is.

Such silo cells are essentially vertical arranged shaft in which the bulk material is stored. Such a shaft has quite considerable dimensions; For example, it can be about 1 in the transverse direction measure up to 5 m and have a height of about 20 m and more. From this it follows that he was going to take up quite a substantial amount of the matter Bulk goods must be suitable. On the other hand, it is usually in the known sliding construction produced in which the wall of the shaft has a wall thickness that is constant over the length owns. This wall thickness must be chosen so that the cell can withstand the mechanical stresses.

These stresses are initially due to the weight of the in the silo cell contained bulk material given. It is essentially a radial one outward stress on the cell wall, the plan shape of the cell plays a certain role. This plan form is often because it is special is simple, designed as a square; but it can also be a rectangle, hexagon, Octagon or as a circle. In each case, there are corresponding similar ones Dimensions in consideration OX in another point of view, however, is that by the selected floor plan given space utilization. Often there are several such silo cells are arranged close together, and it should be clear that a circular floor plan appears disadvantageous in terms of space utilization, because the gussets left between the touching circles create one Show loss of space o The loss of space becomes negligibly small if a square or a rectangular plan is chosen, but this is the mechanical stress of the wall material larger. A floor plan, for example, can be a favorable compromise in the form of a regular hexagon, as this is already a good one Sewing to the most advantageous circular shape in terms of strength and doh the use of space is favorable.

In view of the amount to be accommodated in such a vertical shaft Quantities of the bulk material in question result from at the lower end of the silo cell the dead weight of the bulk material in the latter is quite considerable compression. That has with the result that the individual particles of the bulk material are correspondingly firmly pressed together so that it is difficult to achieve a regulated outflow at the lower end of the Silo cell can be brought. The particles in the bulk material can clump together form, and one has already looked at the problem, a suitable solution for to find the leakage problem. For this purpose, as for example from the German Auslegeschrift 1 157 549 shows near the lower end of a such cells are provided with a nose protruding into the cell space on a cell wall, while at the same time the opposite cell wall below the nose in a gentler way Curve was converted into a slope to run on the discharge opening.

It has been shown that with such a design of the silo cell a significant improvement in the discharge process could be achieved, the effect Such a nose must obviously be seen in the fact that the bulk material in the through the nose formed narrowest cross-section was compressed even further, the same afterwards however a relaxation experienced, so that it was in almost free flow from the nose can hike further downhill. Through the nose on the one hand and the gently guided Fillet on the other hand will be a reasonably smoother and smoother one Reached the course of the (imaginary) flow lines, and relieved the pressure below the nose In this way, bulk material can flow out without the difficulties encountered so far to be brought.

However, such silo cells with a nose-like projection have a quite significant disadvantage to 0 It has already been said that such silo cells be manufactured in sliding construction, and that means that such a nose wedge or a similar nose-like device manufactured as a separate component and is installed in the completed shaft. It will be clear that when flowing through of the bulk material through the narrowest point formed by the protrusion, very considerable wall pressures arise in the shaft material. The bulk material is attached to this Place strongly compressed, and a corresponding stress is thereby exerted on the wall of the cell. This results in wall pressures in the area the nose, which is several times higher than at the other parts of the silo wall, and such a stress therefore requires a correspondingly higher strength at the place of their occurrence0 As an example it is mentioned that the wall pressure in the area the nose when flowing through the bulk material about ten times that which would otherwise prevail Pressure can be.

Such considerable pressures can only be absorbed if the side and wall parts lying opposite the nose are reinforced accordingly. Such However, reinforcement means a considerable increase in the cost of the silo cell, since the rational Sliding construction is only to be carried out if the cell walls are from bottom to top be executed in the same strength. Reinforcement of the cell wall inwards is very difficult because of the flow conditions (the streamlines) in the bulk material can easily be unduly degraded.

A reinforcement of the wall towards the outside is not applicable at all, since it then becomes impossible to place a cell directly in a silo as required to be arranged next to one or more others.

The invention is based on the object described above To resolve difficulties in such silo cells, this can be achieved if according to the invention in the silo cell a relief ring is arranged, its Ground plan corresponds to the ground plan of the silo cell and in the form of a double funnel in its upper part gradually narrows the free cross-section of the cell and then in its lower part again similar, but faster, until aut are original Value expanded, the ring is designed so that it is perpendicular to the direction of flow outwardly acting forces that result from the compression of the bulk material result when flowing through the ring, is able to take up without them even partially forward to the wall of the cell 0 This relief ring corresponds to in its ground plan the ground plan of the silo cell. Is it one in the plan? circular cell, the ring also has a circular shape in plan. At a square or hexagonal cell, the ring also has a square plan or hexagonal shape, it has been shown that when using such The walls near the nose are not subject to any particular mechanical stresses are more exposed and therefore do not need reinforcement. The mechanical forces are picked up by the ring itself. The effect of the ring is likely to be found in it be that the bulk material flowing downwards in the silo cell when passing the ring is constricted uniformly from all sides to a cross-section, the kS r is as the cross section of the cell. Of course, the ring experiences a mechanical stress acting radially outwards, but which is inherent in itself does not absorb un <3 on the wall the silo cell forwards. The prerequisite for this, of course, is that the ring is mechanically sufficiently resistant is constructed. This can easily be achieved, since this relief ring is is a separate component that is manufactured separately and subsequently in the silo cell is inserted.

The bulk material in the silo cell is so through the relief ring compressed to some extent. From the narrowest point of the relief ring on, however, the bulk material can now move on in a practically free stream; it is no longer through the face of the bulk material column above the relief ring loaded in this way can be on the route between the relief ring and the outlet of the silo cell a practically complete loosening of the bulk material particles reach so that the outflow is no longer hindered. Since furthermore in the area the bulk material moves in a practically free stream below the relief ring, the walls in the area of the nose-like protrusion are no longer in merklis either chemically stressed by dynamic pressures, so do not need any special strength-related Reinforcement. A certain dynamic load remains, of course, because the streamlines that were initially almost vertical in the hollow are deflected to the side but this stress is small enough not to reinforce the silo wall to require.

It is useful to design the silo cell so that the free cross-section at least the same at the narrowest point of the relief ring, but better still is smaller than the free flow cross-section of the silo cell @ at the narrowest Job the nose-like protrusion. Since the nose is again a compression to a certain extent of the bulk material flow, care must be taken that this compression no coherence or clumping of the bulk material is caused. From this it follows the requirement that the narrowest cross-sections mentioned be at least the same size do, because from the narrowest point of the relief ring, as described, the anZ approach the free flow of bulk material particles, which is no longer an obstacle Can be if the narrowest point on the nose has at least the same cross-section, better but has a slightly larger cross-section.

It is also advantageous to design the silo cell in such a way that the discharge ring in the silo cell above the nose-like projection at a distance from the latter is attached that is small enough to allow any appreciable compression of the individual Prevent particles of the bulk material by their own weight. This should be clear if you take into account that there is a considerable distance between the relief ring and nose below the ring the same conditions could arise as they arise without such a relief ring. It is therefore essential that the Relief ring arranged only at a relatively small distance from the nose is.

Finally, it can also be advantageous, according to a further development the invention to design the silo cell in such a way that the relief ring at the same time the nose-like projection forms, which is therefore evenly over the whole Extends the perimeter of the silo cell floor plan, with the fillet-like transition in an obliquely downward sloping wall with this together the same characteristic and the bulk material outlet is centrally located in the middle of the cell.

The purpose of the relief ring is to bear the weight of the bulk material column essentially take up and from then on the bulk material continues to flow in free flow allow. If you place another constriction behind the relief ring (the nose), the same process is repeated here, so that the loosening of the bulk material can possibly be improved by this measure0 each however, depending on the prevailing circumstances, just one may be sufficient the only such loosening point to be provided in the silo cell.

So far, this has been achieved with the help of the nose, but the ones described above Has disadvantages, while the replacement of the one-sided nose by a built-in, the relief ring replacing the nose can achieve the bleaching effect without Therefore, the economical sliding construction method for the silo cell should be abandoned got to.

If necessary, it can of course be used in particularly unfavorable cases the installation of several relief rings on top of each other can also be useful, be it with additional nose of the previously known type, be it without one.

For the use of a relief ring to replace the nose also remarked that in such a room the lower part of the double funnel is particularly special should be made brief. The previously known noses have proven to be cheap result, connect a part that recedes as abruptly as possible to the slope of the nose to leave, so that there is a sharp step. The same can be done for the relief ring be favorable if a separate nose is omitted.

ÅufSerdem has already been mentioned that when using a nose on the opposite wall side should be vorgesenen a chamfer, which in a Slant.

Now, according to the above-mentioned embodiment of the invention, the The nose replaced by a ring running around the entire circumference of the silo cell, For the same reasons, it is important to have a groove that runs all the way around to bring into use, which leads into a likewise circumferential slope. This leads all by itself to the bulk material outlet, which is at the end of the The slope is to be laid centrically in the middle of the cell.

In the drawing, two exemplary embodiments of a silo cell are shown of the invention shown schematically, with only the lower end of the silo cell shown 1 shows a silo cell with a relief ring according to the invention and nose and side outlet, and FIG. 2 shows a silo cell with only one relief ring and central outlet In Fig. 1, the broken off at the top is drawn silo cell itself designated by 1 and shown in longitudinal section. She sits upstairs go any further. The cell is near the lower end with the equipped per se known nose 2, which protrudes inward and a corresponding Quersctinittsverstrungung brings about, while the bulk material at the lower end over the Outlet 3 can leave cell 1 Shape a square or rectangular Ground plan on the nose 2 represents a separate component and is with the help of suitable fasteners 5 (e.g. anchors, dowels, screws, rivets) attached to the wall of cell 1 the invention, a relief ring is attached above the nose-like projection 2, which is designated as a whole with 4. This ring, which in plan corresponds to the cell plan is double funnel-shaped, as the drawing shows, and in its upper part 4a narrows the free cross section of the cell in the direction of flow of the bulk material gradually up to the narrowest point. Then it expands in its lower part 4b again similar, but faster, except for its original Werts The ring is constructed in such a way that it is able to use the in its range take up the resulting side pressure statically, without this side pressure is only partially passed on to the wall of cell 1 0 He takes the pressure off of the bulk material, i.e. its own weight, and is therefore with the wall of the silo cell similar to the nose 2 using appropriate fasteners 5 connected, which are indicated in the drawing as Nie te, but also any may have other shapes.

The dimensions of the silo cell shown in Fig. 1 can, for example Have the following values: the cross-section of the silo cell 1 is 5 m long and a square cross-section 25 m2 * This cross-section narrows at the apex the nose 2 on 5 x to the m 17.5 m2. The relief ring has 4 n its closest Set a clear cross-section of 4 x 4 m and thus a cross-sectional area of 16 m2. With these dimensions it is ensured in the manner described above, that the outflow of the bulk material is completely relieved, a uniform outflow is therefore assured.

For the sake of completeness it should be mentioned here that the wall the silo cell on the left in the drawing, just below the nose 2, has a fillet-like shape has a gentle bend 7 and merges into a slope 8, which finally runs out 3 ends In order to make the described relationships even clearer, Fig. 1 the imaginary flow lines 6 entered with dashed lines, which show how the loosening of the bulk material takes place and which tracks the bulk material particles on their way to the run 3, especially next to and under the nose 2, Furthermore, since the walls of the silo cell shown are not subject to mechanical stress are exposed to the usual extent in such silo cells without any installation it can go beyond the tried and tested sliding design with a constant over the entire length Wall thickness can be produced.

As already mentioned, the relief ring 4 is its own Component and is inserted into the silo cell after completion. He takes the weight of the bulk material column, what it is able to do because of the flow of bulk material in the relief ring 4 from all sides evenly on the narrowed cross-section is constricted. The bulk material compressed in the narrowest area is effective similar to a coherent floor, so that the relief ring actually takes up the entire bulk weight. After sitting the closest Job of the relief ring 4 can be the bulk material back to the full width of the Silo cell 1 (at the beginning of the nose 2) outden, and the flow lines 6 indicate the Conditions inside the silo cell during the flow. From them is can also be seen that in the area of the nose 2 or just below the nose a slight dynamic loading of the walls 7, 8 can arise, but none Requires consideration.

A further embodiment is shown in FIG. 2, with the same reference numerals have been used, since these are the same details as in Fig. 1 acts. Here, only one relief ring 4 is provided in the silo cell 1, the has the same effect as in the case of Fig. 1. However, its funnel shape in the lower part 4b much steeper than in Fig. 1, because with to a certain extent the same effect should be achieved as with a nose that has been completely omitted in this embodiment.

It should be clear that the inclusion of the bulk weight here as well with the help of the relief ring 4 takes place as in Fig6 1, and that the narrowest Bulk material leaving the ring 4 has been completely relieved, so that the onward transport can take place in a free flow. As already mentioned, one can this ring 4 as one running around the circumference of the silo cell Look at the nose, and consequently, in the case of the silo cell 1 according to FIG. 2, each wall is below of the relief ring 4 is provided with a groove 7 which merges into a bevel 8. The outlet 3 arises here in the middle of the lower cell part, and the four bevels 8 tapering towards it determine its arrangement entirely by themselves.

The outlet 3 can also be relocated as required, for example in the form of Fig0 1 or by lateral or the like. Arrangement It must then of course the required design of the lower shaft part of this desired Position of the outlet can be adjusted.

Also in Fig. 2 are the imaginary streamlines 6 of the bulk material particles sketched in, and the figure shows that this Design results in a very even, undisturbed flow, which is also a steady one The bulk material flows out of the outlet to the pole. Regarding the attachment of the relief ring 4, the same applies as in FIG. 1; for this are also Rivet 5 provided0 Also with regard to dynamic stress on the cell subdivision In the area of the wall parts 7, 8, the same applies as was stated above for FIG. 1.

Claims (4)

Patent claims: 9 bulk material silo cells, with one near the bottom arranged nose-like projection serving to relieve the bulk material outlet, wherein the wall of the silo cell is made in the known sliding construction and compared to the nose-like projection in the manner of a chamfer in an oblique direction wall facing towards the other side passes below, characterized in that in the silo cell (1) a relief ring (4) is arranged, the plan of which the Corresponds to the outline of the silo cell and in the form of a double funnel in his upper part (4a) gradually narrows the free cross-section of the cell and then in a lower part (4b) similar again, but faster, except for its original Value expanded, the ring is designed so that it is perpendicular to the direction of flow outwardly acting forces that result from the compression of the bulk material result when flowing through the ring, is able to take up without them even partially forward to the wall of the cell. 2. Silo cell according to claim 1, characterized in that the free Cross-section at the narrowest point of the relief ring (4) is at least the same, better but still smaller than the free flow area of the silo cell (1) at the narrowest Place of the nose-like projection (2) is selected. 3. Silo cell according to claim 1, characterized in that the relief ring (4) in the silo cell (1) above the nose-like projection (2) at a distance attached to the latter, which is small enough a noteworthy one Compression of the individual particles of the bulk material by their own weight impede. 4 silo cell according to claim 1, characterized in that the relief ring (4) at the same time-forms the nose-like projection, which is accordingly evenly over extends the entire perimeter of the silo cell floor plan, the concave-like Transition (7) into a wall (8) striving obliquely downwards with this has the same property and the bulk material outlet (3) is centered in located in the center of the cell. L e r s e i t e