DE9408840U1 - Open-plan silo cell - Google Patents

Description

Large capacity silo cell

The invention relates to a large-capacity silo cell for fine-grained and powdery bulk material, with a material distributor arranged approximately centrally on the top of the silo cell and designed to feed the bulk material, according to the preamble of claim 1.

Large-capacity silo cells of the type described are sufficiently well known in practice and are described, for example, in Walter H. Duda, CEMENT-DATA-BOOK, Vol. 1, 3rd edition 1985, pages 323 to 325 (in particular Fig. 17.6.3.). In this known design, a single large-capacity silo cell is fed with fine-grained and/or powdery bulk material via a material distributor, which has an essentially closed, container-like distribution pot with a ventilated base and a peripheral wall, to which a number of pneumatic conveyor troughs of essentially the same length are connected, whereby the silo cell is fed in an approximately ring-shaped outer peripheral area through filling openings in the silo cell ceiling. Large-capacity silo cells of this type are generally designed with a circular, possibly polygonal cross-section.

In practice, it has been shown many times that, especially when a mixture of fine-grained and powdery bulk material is filled into a large-capacity silo cell using the material distributor mentioned above, separations of the bulk material occur, i.e. the coarser material particles collect directly under the inlet openings of the silo cell, while the fine material parts are concentrated around the previously mentioned areas.

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accumulate, so that undesirable segregation occurs. The latter is particularly disadvantageous if the coarser and finer material fractions are of different qualities. This is the case, for example, in cement production, when raw cement meal made from different starting materials, which is later to be burned, is stored in a single large-capacity silo cell, with coarser material fractions with a relatively low lime standard being deposited in the area directly under the silo cell inlet openings and fine material fractions with a relatively high lime standard being deposited around the previously mentioned area. The resulting uneven material distribution or segregation can generally no longer be compensated for by designing the silo cell as a mixed silo.

The invention is therefore based on the object of creating a large-capacity silo cell of the type specified in the preamble of claim 1, which is characterized by a particularly favorable loading with fresh bulk material across its cell cross-section, counteracting the separation explained above.

This object is achieved according to the invention by the characterizing part of claim 1.

Advantageous embodiments and further developments of the invention are the subject of the subclaims.

In this large-capacity silo cell according to the invention (single, undivided in the silo space), the bulk material discharge channels connected to the peripheral wall of the distribution pot of the material distributor can be designed essentially the same and connected to the filling openings in the

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outer peripheral area of the silo cell, as in the known designs. However, it is important here that an annular wall is fixed in place inside the distribution pot at a distance from the peripheral wall, the ventilated floor and the top wall of this distribution pot and approximately centrally within it, and that a central outlet nozzle with a controllable shut-off device is arranged on the bottom of this distribution pot. These structural measures inside the distribution pot ensure that the fresh material fed in through the bulk material inlet nozzle is kept in a uniform state and can be evenly distributed to all outlet openings of this distribution pot (including the outlet opening provided in the bottom to the central outlet nozzle). The bulk material in this distribution pot can flow directly downwards through the central outlet nozzle and be deposited in the middle of the large-capacity silo cell, while the bulk material passes through the annular gap between the lower end of the ring wall and the floor and by flooding the upper end of this ring wall to the bulk material discharge channels connected to the side or the peripheral wall of the distribution pot and is deposited from there through the filling openings on the top of the silo cell into the outer, annular peripheral area. This results in an extremely advantageous mixing of the bulk material portions fed through the silo cell filling openings in the outer peripheral area on the one hand and the bulk material portions deposited through the central outlet nozzle in the middle of the silo cell on the other.

According to an advantageous embodiment of the invention, the ventilated bottom of the distribution pot is essentially flat and arranged essentially horizontally, and the open upper end of the central outlet nozzle is flush with the top of the bottom. The particular advantage of this design is that the entire distribution pot can always be completely drained after the bulk material supply is switched off or interrupted.

According to another advantageous embodiment of the invention, this large-capacity silo cell is characterized by such a control device for remotely opening and closing the shut-off device of the central outlet nozzle that the silo cell space can be filled alternately centrally via the central outlet nozzle or in the outer peripheral area via the bulk material discharge channels. This switching option means that when the separations or demixing of coarse and fine material fractions mentioned at the beginning occur, the coarse material fractions are collected alternately under the central bulk material inlet (central outlet nozzle) and under the filling openings in the outer peripheral area of the silo cell, so that when the bulk material is removed from this large-capacity silo cell, an extremely good mixing or blending of the material in this silo cell can be guaranteed.

The invention is explained in more detail below with reference to the drawing. In this drawing,

Fig.l is a vertical sectional view through the upper end of a large-capacity silo cell according to the invention with a material distributor arranged thereon;
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Fig. 2 a vertical sectional view through the distribution pot of the material distributor.

For the sake of simplicity, Fig. 1 shows only a vertical section through the upper end of the large-capacity silo cell 1 according to the invention, which is of particular interest here, on whose upper side or cell ceiling 1a an associated material distributor 2 for supplying bulk material is arranged. This large-capacity silo cell 1 thus encloses a single silo cell space 1b, which is undivided in cross-section, for receiving the bulk material supplied. The lower end of this large-capacity silo cell 1, which is not shown, can be designed in the usual way and, for example, have pneumatic discharge conveyor troughs, discharge or mixing carters and the like arranged on the floor.

The material distributor 2 arranged on the cell ceiling 1a contains - as shown in Figs. 1 and 2 - a substantially closed, container-like distribution pot 3, with a ventilated bottom 4, an approximately cylindrical peripheral wall 5 and a cover wall 6, which is essentially flat and is fastened directly to the upper end of the peripheral wall 5 - if necessary detachably. The material distributor 2 also includes a bulk material inlet nozzle 7 arranged approximately centrally in the cover wall 6 and several bulk material discharge channels arranged in the circumferential direction and distributed approximately in a star shape in the form of pneumatic conveyor troughs 8, which are connected to the peripheral wall 5 of the distribution pot 3 via outlets.

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outlet openings 9 and associated outlet nozzles 10 and are connected to filling openings 11 provided in the cell ceiling la in the outer peripheral area of the silo cell 1.
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Inside the distribution pot 3, an annular wall 12 is arranged approximately centrally and is held in place, for example with the help of upright flat iron pieces 13 or the like, in such a way that it has a suitable distance from the peripheral wall 5, the base 4 and the top wall 6.

A central outlet nozzle 14 is also arranged on the ventilated bottom 4 of this distributor pot 3, which is provided at its lower end with a controllable shut-off device 15, which can be a shut-off flap (as indicated in Figs. 1 and 2), a known flat slide valve or a known rotary slide valve. A material inlet pipe 16 is connected to this shut-off device 15, which runs essentially vertically downwards and projects centrally into the silo cell space 1b.

The ventilated base 4 of the distribution pot 3 is approximately flat and arranged essentially horizontally, as can be seen in Fig. 2. The open upper end 14a of the central outlet nozzle 14 is flush with the upper side 4a of the base 4. At least one air supply connection 17 0 is also connected to this base 4 in order to pneumatically loosen or fluidize the bulk material located inside the distribution pot 3 in a manner known per se.

For the practical operation of this large-capacity silo cell 1 and in particular for the feeding of this silo cell 1 with bulk material, it is particularly advantageous if - as only indicated very schematically in Fig. 1 - a control device 18 for remotely opening and closing the shut-off device 15 is provided and designed in such a way that the silo cell space Ib can be filled alternately centrally via the central outlet nozzle 14 and in its approximately ring-shaped outer peripheral area via the pneumatic conveyor troughs (bulk material discharge channels) 8. The pneumatic conveyor troughs are also connected to this control device 18 in such a way that they can be controlled in the sense of conveying and non-conveying, i.e. if the shut-off device 15 of the outlet nozzle 14 is open, then the conveying air supply to the pneumatic conveyor troughs 8 can be largely switched off, while the conveying air supply to the conveyor troughs 8 is activated in the sense of conveying goods when the shut-off device 15 is closed.

Inside the distributor pot 3, the ring wall 12 is - as can be seen in particular in Fig. 2 - expediently designed in the form of an essentially cylindrical pitot tube with open upper and lower ends 12a and 12b and a completely closed peripheral wall 12c. The lower end 7a of the bulk material inlet nozzle 7 extends into the distributor pot 3 or its interior 0 approximately up to the area of the upper end 12a of the ring wall 12.

The outlet openings 9 or their lower edges 9a are installed at a distance A above the ventilated base 4 in the peripheral wall 5 of the distribution pot 3. Purpose-

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These lower edges 9a of the outlet openings 9 are arranged approximately at the height of the lower end 12b of the ring wall 12, as can also be seen in Fig. 2.

Claims (9)

- 1 Protection claims 1. Large-capacity silo cell for fine-grained and powdery bulk material, with a (la) the silo cell (1) arranged material distributor (2) designed to feed the bulk material, which has a substantially closed, container-like distribution pot (3) with a ventilated bottom (4) , a peripheral wall (5) and a cover wall (6) , and a bulk material inlet nozzle (7) arranged approximately centrally in the cover wall and several bulk material discharge channels (8) connected to the peripheral wall of the distribution pot and arranged distributed in the circumferential direction, which are provided with filling openings (11) are connected in the outer peripheral area of the silo cell , characterized in that
20 a) inside the distribution pot (3) an annular wall (12) is fixedly mounted at a distance from the peripheral wall (5), the base (4) and the top wall (6) and approximately centrally arranged, b) a central outlet nozzle (14) with a controllable shut-off device (15) is arranged on the bottom (4) of this distribution pot (3). 0 2. Large-capacity silo cell according to claim 1, characterized in that the annular wall (12) is designed in the form of a substantially cylindrical pitot tube with open upper and lower ends (12a, 12b) and with a completely closed peripheral wall (12c). (KO *· " 3. Large-capacity silo cell according to claim 2, characterized in that the lower end (7a) of the bulk material outlet nozzle (7) extends approximately into the region of the upper end (12a) of the ring wall (12) in the distribution pot (3) protrudes. 4. Large-capacity silo cell according to claim 1, characterized in that the controllable shut-off device (15) of the central outlet nozzle (14) is provided by a shut-off flap, a flat slide valve or a rotary slide valve. 5. Large-capacity silo cell according to claim 1, characterized in that a material inlet pipe (16) extending essentially vertically downwards and protruding centrally into the silo cell space (Ib) is connected to the shut-off device (15). 6. Large-capacity silo cell according to claim 5, characterized in that the ventilated bottom (4) of the distribution pot (3) is essentially flat and arranged essentially horizontally and that the open upper end (14a) of the central outlet nozzle (14) flush with the top (4a) of the base closes. 7. Large-capacity silo cell according to claim S ₁ , characterized by such a control device (18) for remotely operable opening and closing of the shut-off device (15) of the central outlet nozzle (14) so that the silo cell space (Ib) can be filled alternately centrally via the central outlet nozzle (14) or in the outer peripheral area via the bulk material discharge channels (8). 8. Large-capacity silo cell according to claim I ₁ , characterized in that the bulk material discharge channels are formed by pneumatic conveyor troughs (8) and are also controlled by the control device (18) of the shut-off device (15) are taxable in terms of promotion and non-promotion. 9. Large-capacity silo cell according to claim 8, characterized in that the outlet openings (9) to the conveyor troughs (8) are arranged at a distance (A) above the ventilated floor (4) in the peripheral wall (5) of the distribution pot (3) and the lower edge (9a) of these outlet openings (9) are arranged approximately in the height range of the lower end (12b) of the ring wall (12).