CH653568A5 - Method for mixing bulk material in a mixing silo - Google Patents

Description

The invention relates to a method for mixing bulk material in a mixing silo, which has a main silo space, to which the material is fed in the upper area, and a mixing chamber which is arranged at the bottom of the main silo space and is at least partially located in the main silo space and which removes the material from between the mixing chamber and the annulus located on the side wall of the main silo space is fed through openings in the wall of the mixing chamber, the material in the main silo space being ventilated both at the bottom of the annulus and on the mixing chamber ceiling.

The mixing effect of known mixing silos (DE-PS 1 507 888; DE-OS 2 657 598) is based on the fact that a coarse mixing to dampen long-term compositional fluctuations takes place in the main silo room and the homogenization takes place in the mixing chamber. The more recent development is to give the mixing chamber considerable size in relation to the main silo room. For example, it extends over almost half the height of the main silo room and its diameter is approximately half that of the main silo room. Given these size ratios, it cannot be assumed without further ado that the material in the main silo room above the mixing chamber participates evenly in the mixing movement caused by the fume cupboards in the annular space. Even if the main silo room above the mixing chamber is ventilated by ventilation devices on the ceiling of the mixing chamber, this material does not flow evenly to the troughs of the annular space. Rather, uneven movements can occur, which endanger a uniform premixing effect. Furthermore, the insufficient participation of the material above the mixing chamber in the mixing movement has the effect that the volume of the space used for active premixing is less than the volume of the main silo space, so that long-term fluctuations in the composition of the supplied material are less damped than it is in terms of size of the main silo room would be expected.

15 The invention is therefore based on the object of providing a method for mixing bulk material in the mixing silo mentioned at the outset, which uses the volume of the main silo space for the premixing movement and prevents the disadvantageous effect of uneven removal of material from the main silo space above the mixing chamber.

This task is not obvious because it is so far unknown that the main silo room above the mixing chamber does not fully participate in the mixing movement in newer types of this silo (in contrast to the older types with a small mixing chamber), and that therefore the Mixing effect of such silos can be improved.

The solution according to the invention consists in that the material on the mixing chamber ceiling is ventilated more than in the annular space.

30 While the previous practice was that the material on the ceiling of the mixing chamber is ventilated - if at all - at least as strongly as at the bottom of the annulus,

Because the ventilation was only seen as an aid to the movement of goods from the area above the mixing chamber to the annular space 35, the stronger ventilation according to the invention above the mixing chamber causes a fundamentally different type of movement of the goods, which is more closely related to the movement of goods in so-called homogenizing silos (AT -PS 192 331). In contrast, the principle of the mixing chamber silos is based on the idea of restricting the homogenization movement with its high energy requirement to the mixing chamber, while in the main silo room the mixing effect takes place with less energy due to the extraction movement. The invention now deviates from this principle insofar as greater ventilation is provided above the mixing chamber silo in the main silo room, which sets the material there in a movement which is similar to that in a homogenizing silo. This causes the material above the mixing chamber to be circulated on the one hand and, on the other hand, to reach a state in which it easily transitions into the active mixing flow of the annular space in order to participate in the withdrawal movement. In this way, a significant improvement in the damping of long-term fluctuations in the composition and an optimal utilization of the silo volume for the mixing movement is achieved. Surprisingly, the advantage of lower energy requirements of the mixing chamber silo system compared to homogenizing silos is not abandoned. There are three main reasons for this. First, the space above the mixing chamber, which is traversed by more intensive material movement according to the invention, is considerably smaller than the total volume of the main silo space. In terms of size, it roughly corresponds to the size of the mixing chamber, making up only one sixth of 65 to one third of the entire silo space. Secondly, the height of the column of material standing above the mixing chamber is limited, so that a relatively low pressure is sufficient to carry it out to generate the circulating movement.

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bump. Experience has shown that the pressure required to ventilate a given pillar of goods is much less than half the pressure required to ventilate a pillar of goods twice as high. Third, the agitation need not be as intense as is generally considered necessary for homogenization.

Under stronger ventilation in the sense of the invention is to be understood as one that leads to the above-mentioned circulating movement of the good, which is characterized in that the good rises in places due to the ventilation due to reduced mean specific weight and decreases accordingly in other zones. This requires a higher ventilation pressure than in the area in which the material should only be made flowable near the ground in order to be able to be drawn off. Of course, the amount of pressure is also dependent on the load-bearing pillar, so that no general information can be given about the pressure ratio. As an indication, one can use the fact that with the dimensional relationships given above, in which the column of material in the annular space is approximately twice as high as above the mixing chamber, about 1.5 to 3 times the pressure for ventilation above the mixing chamber compared to the ventilation of the Annulus floor applies. The weaker ventilation of the annular space floor only leads to the fact that in the ventilated zones the material becomes free-flowing at the bottom, so that it can pass into the mixing chamber. By emptying the lower parts of the material, the material above it slips to form the so-called discharge or mixing drums, without actually being fluidized by ventilation. In contrast to this, the air supplied to the material located on the ceiling of the mixing chamber penetrates the entire column of material up to the top.

The term “stronger ventilation” used in the present context is also not to be understood as if it requires a greater air throughput through the ventilated area, since with the smaller column of material, which is based on the ceiling of the mixing chamber, the same specific amount of air may be sufficient to penetrate this column of material, while it escapes into the mixing chamber at the bottom of the annulus with the material being drawn off, without having previously reached greater heights of the annulus.

For the sake of clarity, it should be noted in this context that in the context of the present description, annulus denotes the entire radially outer part of the main silo space in which the exhaust streams develop and which includes the mixing chamber at the bottom and the part of the main silo room located above the mixing chamber.

The ventilation on the ceiling of the mixing chamber is expediently operated alternating zones, as is also common in the annular space of mixing chamber silos and in the mixing chambers themselves. Changing zones are strongly ventilated, while the other zones are not or only poorly ventilated. In any case, it is advisable to choose the ventilation in the heavily ventilated zone so strongly that the goods move upwards there. If the remaining zones are at least partially poorly ventilated, the goods are so flexible there that they can move downwards to compensate for the ascent movement over the heavily ventilated zone. The same effect can be achieved without the effort of an additional weak ventilation of this remaining zone if the zone-by-zone strong ventilation changes so quickly that in a non-ventilated area the material from previous strong ventilation is loosened enough to compensate for the im heavily ventilated sector can move downward movement. In general, in the method according to the invention, the communication of the part of the main silo space located above the mixing chamber with the annular space and its discharge stream is not critical, because the material above the mixing chamber is still in such a mobile state even in non-ventilated zones finds that it can easily pass into the discharge stream benches of the annulus. As a result of the circulation above the mixing chamber, it is also irrelevant whether the material from this part passes into the discharge stream above or below. Nevertheless, the ventilation sequence on the mixing chamber ceiling can be coordinated with that in the annular space. It is advantageous, for example, if the ventilation change in the annular space on the mixing chamber cover is controlled in such a way that a heavily ventilated sector with upward material movement on the mixing chamber ceiling is at least temporarily separated from a discharge stream in the annular space by an area with downward material movement. In such a case, näm-20 loaned the goods with the downward movement of the goods slightly with the goods also downwards in the neighboring fume cupboard. However, in other cases, in particular if the circulation movement over the mixing chamber is not very pronounced, such a control can also have advantages which, at least at times, bring about the proximity of a strongly ventilated sector on the ceiling of the mixing chamber with a discharge stream in the annular space.

The invention is explained in more detail below with reference to the drawing, which illustrates in a figure a schematic longitudinal section through a mixing chamber silo with the material movement indicated by arrows.

The main silo is built on the foundation 1, preferably with a cylindrical outer wall 2 and ceiling 3, through which the material to be mixed is distributed evenly over the silo cross-section by means of a conveying device 4. The mixing chamber 5 with a cylindrical side wall 6 and a mixing chamber ceiling 7 rises centrally on the foundation 1 within the main silo room. The mixing chamber has almost half the height of the main 40 silo room above the silo floor 8. Their diameter is about half the size of that of the main silo. An annular space 9 is located between the walls 2 and 6. For the purposes of the present invention, the space 10 located approximately in alignment above is also included in the term annular space. The ring-45 space 9 is only interrupted at one peripheral point by an emptying chamber 11, the function and parts of which do not require any further description at this point.

The bottom of the annular space 9 is provided with ventilation devices 12 for the finely divided introduction of compressed air into the material. Corresponding ventilation devices are also located at 13 on the mixing chamber ceiling 7. In the mixing chamber ceiling at 14, a closable discharge opening is indicated, which leads from the main silo space into the mixing chamber and generally only needs to be opened when the silo is completely emptied. Of course, it can also be used during the mixing process.

The mixing chamber 5 is connected to the annular space 9 via openings 15 in the wall 6 near the annular space floor.

The mixing process is carried out in the following manner.

The main silo space is kept filled by the conveyors 4. The ventilation devices 12 of the bottom of the annular space 9 are alternately ventilated in zones. For example, 12 sector zones of the same size can be provided. In each case, the goods located in a ventilated zone become flowable and enter through the ventilation

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through the nearest opening 15 into the mixing chamber 5. There, the goods are homogenized by intensive quadrant ventilation before they are drawn off.

When the aerated material flows into the mixing chamber via an aerated floor zone 12, the still unventilated material located above it slips. This effect continues into the upper part 10 of the annular space and up to the Gutspiegel, so-called fume cupboards being formed. These are funnel-shaped or channel-shaped zones, within which the material sinks more or less evenly downwards, while the material adjacent to the drum is partly included in the tightening movement, insofar as it is flexible enough, but partly also remains uninvolved.

The upper part 10 of the annular space encloses that area 16 of the main silo space which is located above the mixing chamber 5. The ventilation devices 13 on the mixing chamber ceiling are, for example, in six sectors and a middle field (around the exhaust opening 14)

divided, which can be ventilated independently. While the midfield is constantly ventilated, only one of the sectors is ventilated at a time, while the other sectors are not ventilated. The ventilation 5 of the sectors changes in short intervals of a few minutes. The ventilation in this sector is always so strong that it detects the goods right up to the goods level. Its mean density is reduced so much that it rises (arrows 17), while the material lowers in the other ok areas, where it is still a little free-flowing due to poor ventilation or due to previous strong ventilation, and in the heavily ventilated Flows in the area below (arrows 18). As a result, the part of the main silo room above the mixing chamber is rolled around itself and at the same time also participates in the withdrawal movement, as can be seen at the top left, where the discharge flow formed in the annular space 9, 10 has the same movement character as that falling in the area 18 above the mixing chamber Well and therefore easily combined with it.

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1 sheet of drawings

Claims (7)

653 568 1. A method for mixing bulk goods in a mixing silo, which has a main silo, to which the material is fed in the upper area, and an arranged at the bottom of the main silo, at least partially located in the main silo, which removes the material from between the mixing chamber and the Side wall of the main silo space is supplied through openings in the wall of the mixing chamber, the material in the main silo being ventilated both at the bottom of the annular space and on the mixing chamber ceiling, characterized in that the material on the mixing chamber ceiling is ventilated more than in the annular space. 2. The method according to claim 1, characterized in that the ventilation on the mixing chamber ceiling is operated alternately zones. 2nd PATENT CLAIMS 3. The method according to claim 2, characterized in that the ventilation on the mixing chamber ceiling is so strong that the material moves upwards over the heavily ventilated zone. 4. The method according to claim 3, characterized in that the remaining zones are at least partially poorly ventilated. 5. The method according to claim 3 or 4, characterized in that the zone-wise strong ventilation changes so quickly that in a non-ventilated area the material from previous strong ventilation is loosened up so that it is directed to compensate for the upward direction in the heavily ventilated sector Movement can move downwards. 6. The method according to any one of claims 2 to 5, characterized in that the ventilation change in the annular space and on the mixing chamber ceiling is controlled, that at least partially a heavily ventilated sector with upward material movement is separated by a region with downward material movement from a discharge stream in the annular space becomes. 7. The method according to any one of claims 1 to 5, characterized in that the ventilation change in the annular space and on the mixing chamber ceiling is controlled so that at least at times a heavily ventilated sector on the mixing room ceiling is adjacent to a fume hood in the annular space.