DE19849174C2 - Filling chute for non-segregating storage of granular or flaky and flour-containing goods in silo cells - Google Patents

Description

The invention relates to a filling shaft for not segregating granular or flaky and floury goods in silo cells.

Filling chutes become sensitive to free-flowing Bulk goods such as legumes, malt, feed pellets or mixed feed flour etc. for gentle filling of the Cell with anti-fall agents or without internals used. They also do the job of To avoid segregation of the stored products, by leading the falling product in the shaft and in each case from those free above the surface of the stored goods of outlet openings arranged along their length let out. If these shafts dated Cell inlet extend shortly over the cell outlet, they also serve to empty the cell from above. Such shafts are e.g. B. in DE 39 23 613 C2 or DE 36 31 557 C2 discloses and allow in this Embodiment a cell function according to the principle "first in - last out. Process engineering, however for z. B. composed of components Cells that the principle "first in first out are enough.

In US 3,490,655 there are conical downward opening Extraction shafts shown, which are closed at the top and therefore not to avoid segregation of the Filled goods can serve during storage. They have a mixing function for zones near the shaft during the Removal from the cell and are sufficient as the aforementioned Examples in no way the z. B. in the Feed industry usual principle first in - first out "for cell removal.  

The filling shaft shown in DE-GM 17 26 280 serves the non-segregating storage. However, he points always dead spaces below the drop-resistant slopes - and thus space for vermin infestation - and sharp Corners between slopes and shaft walls on, in which fill - especially floury good - at Draining "ironing" can. One down in the shaft flowing pillar always shows one large curve during the transition from the vertical Shaft wall on the slopes, leaving stuck goods in the mentioned corner areas. The Bottom of the slopes are when the Product is neither coated nor touched by it.

The filling shaft shown in EP 0 337 818 A2 opposing outlet openings serve gentle and non-segregating storage, however, it does not solve the residue-free problem Self-cleaning of all surfaces, especially at Emptying the cells and "ironing" when Leakage of floury contents in sharp-edged or to slightly rounded corner areas, that of the Shaft walls and the slopes are formed.

The slope angles of the filling material are only Slopes assigned the same angle of inclination in order to Filling to avoid loss of storage space. A Self-cleaning of the sloping undersides can, however not done by this.

For filling z. B. from regrind, vitamins and Mineral flour compound feed mixes were also smooth inside, e.g. B. at the cell ceiling Chains hung with over the entire shaft wall Distributed outlets provided shafts or Pipes used, from the cell inlet to the Outlet area significantly above the cell outlet rich and as so-called "anti-segregation pipes" were designated. Because of the significant occurring Ceiling loads due to summed tensile loads, too these pipes could lead to frequent tearing but not enforce. Telescopic tubes that are at increasing filling of the cell above the Push the rising filling material upwards, separate for cost reasons in most practical cases also from.  

Good that could be stored in silo cells in free fall So far, smooth inside, without distracting agents trained shafts with distributed over the height Outlet openings guided downwards without separation, but then almost deflected with Falling speed from the lower shaft openings in a ballistic track with a lot of dust above the product surface in the free cell space and segregated strongly because of specifically heavier particles like a wind sweep first down on the Product surface fall.

This is where the present invention intervenes and provides the task is simple, tubular in the cell to create fortified manholes that are not for segregating and drop-resistant or in free fall granular, flaky and / or floury to be stored Products are suitable, whereby when filling the cell To dreams can be avoided in the shaft and when emptying while avoiding Residual deposits the self-cleaning of everyone product-contacting inner and outer inclines or vertical shaft surfaces in order to avoid Contamination of subsequent cell fillings is caused. There is still the task of filling shafts without drop-inhibiting agents the segregating Shoot filling material out of the filling shaft into the free cell space above the product level appropriate equipment or arrangement prevent.

These tasks are characterized by the features of the claims 1, 3, 5, 8, 9 and 12 solved. The subclaims describe advantageous configurations.

The filling shafts according to the invention serve once for drop-inhibiting and abrasion-reducing non-segregating Storage of free-flowing, predominantly granular goods. Your bevels will be particularly sensitive Provide products with an elastic covering. they are however for predominantly flour or very flaky Storage goods are not suitable, as this is in the deflection can stow or set zones. Especially for such However, it is highly desirable that products Separation when stored in free fall in the cells to prevent. On the other hand, the wear problem plays no role or negligible role for them.  

For such products, smooth surfaces are therefore used on the inside vertical filling shafts without constricting, moving or indoor distracting means suggested that preferably composed of shots at the Cell wall are attached, but also within the Silo cell can be hung. This Shots are with one over their entire length or with one or more over their partial length as well each over an angular range of its shaft wall extended large openings. It is a essential characteristic of the invention that when Store the shoot-out of filling material in free fall from the inside smooth, not narrowed shaft braking surfaces provided in front of the outlet openings is prevented. Such braking surfaces can by Sheet metal opposite the outlet openings or also silo walls are formed. You allow braking stagnation between the shaft and braking surface and redirected leakage of the goods with minimal Dust generation in calming non-segregating Pour directly onto the surface of the product in the Cell, since the length of the Discharge openings are also useful for braking Form sink zones within the shaft.

To ensure that the contents remain in the shaft to avoid when emptying a silo cell also proposed according to the invention that the Shot down for difficult products preferably continuously conical or in stages expand parallel-walled sections. It will further generally suggested that individual successive shots not by overarching Sleeves or cuffs in connection with each other stand, but left in self-cleaning columns each using several overlapping or engaging narrower Support bevelled cams against each other. As well it is suggested that every horizontal surface at the Edges of the shafts and their fasteners Avoid steep bevels to ensure that there are no Idling of the silo cells and shafts without any remaining To achieve residual deposits. With that, everyone Contamination of the successor product by a previously stored product excluded.

It is also a feature of the invention that the braking surfaces in front of the outlet openings so far  below the lower edges of the outlet openings extend that obliquely downward at an angle of 50 ° to horizontals shooting out of them Filling material also below the lower edge of the Outlet openings outside the filling shaft is braked effectively.

Another characteristic of the invention, namely the downward Increasing distance between the braking surfaces opposite the filling shaft, is not shown.

As a particularly advantageous embodiment of the invention are the strongly rounded transitions from vertical Inner shaft walls on the drop-resistant slopes to see which, the education or that "Fixed ironing" of dead running zones in the flow area of the Manhole sinking when the cell is emptied prevent. Furthermore, all subpages of fall-resistant slopes according to the invention steeper than that Slope angle of the stored bulk material trained and also go rounded in the Shaft wall over.

According to the invention, the residue-free, contamination avoiding emptying of the filling shafts and thus the Cells due to the self-cleaning steepness of the upper and undersides of anti-fall agents and through their strongly rounded transitions as well as the self-cleaning steep bevel of all production-related horizontal surfaces and the Avoidance of narrow gaps that pinch the product between the shaft sections in which there is filling material could fix, achieved. Everyone cleans themselves as well opening vertically or diagonally downwards Manhole areas by passing goods themselves.

Below are several based on the drawing Embodiments of the invention explained in more detail. It demonstrate:

Fig. 1 a longitudinal section through Füllschachtabschnitt along the line II-II in Fig. 2

Fig. 2 cross-section along the line II in Fig. 1

Fig. 3 longitudinal section through a filling shaft section

Fig. 4 longitudinal section through a filling shaft section

Fig. 5 longitudinal section through a filling shaft section

Fig. 6. Longitudinal section through a filling shaft section

Fig. 7 longitudinal section through a filling shaft section

Fig. 8 longitudinal section through a Füllschachtabschnitt along the line IV-IV in Fig. 9

Fig. 9 cross-section along the line III-III in Fig. 8

Fig. 10 shows the longitudinal section through a Füllschachtabschnitt along the line VI-VI in Fig. 11

Fig. 11 cross-section along the line VV in Fig. 10

Fig. 12 longitudinal section through a Füllschachtabschnitt along the line VIII-VIII in Fig. 13

Fig. 13 cross-section along the line VII-VII in Fig. 12

Fig. 14 cross-section along the line IX-IX in FIG. 12

Fig. 15 longitudinal section through a silo with a hopper (left) and a hopper (right) along the line XI-XI in Fig. 16

Fig. 16 cross-section through a silo along the line XX in Fig. 15

Fig. 17 longitudinal section through a Füllschachtabschnitt along the line XIII-XIII in Fig. 18

Fig. 18 cross-section along the line XII-XII in Fig. 17.

The filling shaft section shown in FIGS. 1 and 2 has vertically offset, opposing outlet openings 2 , from the upper edges 1 of which rounded guiding surfaces 3 extend obliquely downwards into the filling shaft, which contact the inside of the filling shaft wall. When a shaft is filled, the material is guided through the guide surfaces 3 one after the other at the free outlet openings 2 and only runs out of the lowest still free outlet openings 2 above the filling material into the cell. With their increasing degree of filling, the filling shaft also fills without dead spaces being able to arise in the interior of the shaft, since the angle of inclination of the guide surfaces 3 is always steeper than the angle of repose of the stored goods.

When the cell is emptied, the filling shaft empties together with the goods from the cell funnel from below. Here, both the upper and lower sides of the guide surfaces 3 are smeared with the leaking material and thus also cleaned. Due to the rounded transition of the guide surfaces 3 in the upper edges 1 of the outlet openings 2 no good z. B. in a corner formed by a guide surface 3 and the shaft wall. This would always happen in the case of difficult-to-flow products if guide surfaces protrude from the upper edges 1 of the outlet openings 2 directly into the shaft at an angle, forming an angled corner.

Advantageously, the side edges of the outlet openings 2 near the silo wall 6 can be provided with extended deflector plates 5 beyond their lower edge, so that when granular material, e.g. B. feed pellets, no good scrub against a rough silo wall 6 and can generate abrasion.

The filler shaft section shown in longitudinal section in FIG. 3 has, near above its outlet opening 7, an approximately wedge-shaped body 8 , which extends approximately to the center of the shaft and whose obliquely sloping upper side 9 and rising lower side 10 merge into its shaft wall by means of roundings 11 . The underside 10 could also start directly at the upper edge 9 of the outlet opening 7 and would then not require a rounding 11 .

The body 8 above the outlet opening 7 is offset in height by another body 8 of approximately the same design. This arrangement is repeated in the shots of the shaft. Since the top sides 9 and bottom sides 10 are always inclined more steeply than the angle of repose of the goods to be stored and are rounded into the shaft walls, dead spaces cannot form when filling or residues of goods can settle in angled corners when emptying.

In. Fig. 4 is a filling shaft section shown in longitudinal section, the shaft wall has an outwardly protruding bulge 12 close above the outlet opening 20 , which, starting from the opposite shaft wall, is opposite a laterally adjacent, approximately wedge-shaped deflection body 13 with a sloping top and a sloping bottom. This deflecting body 13 preferably extends corresponding to the shaft diameter 15 approximately up to the central region of the bulge 12 .

When filling, the deflection bodies 13 exert a strong fall-inhibiting effect. Deflected material is directed past the outlet openings 20 through the lower slopes of the bulges 12 , so that it can advantageously only flow from the lowest free outlet opening 20 into the silo cell. The bevels of the deflection body 13 and the bulges 12 are steeper than the angle of repose of the stored goods.

Due to the rounded portions 14 , dead spaces or jamming in corners between the upper side of the deflecting body and the shaft wall are excluded, so that the filling shaft is completely emptied when the cell is emptied.

The filling shaft section shown in longitudinal section in FIG. 5 has a bulge 16 which is provided above the outlet opening 21 and which, in the interior of the shaft, is associated with an inclined sheet 17 , which lies on the inside and lies laterally in the shaft, approximately from the central region of the bulge 16 and which is inside the bulge 16 leaves a passage area 19 and a passage area 18 in the interior of the shaft.

During the filling process, the inclined plate 17, which is preferably inclined downwards towards the inside of the shaft, brakes the flow of material and only allows a small partial flow to continue through the passage area 18 , while the main flow overflows from the storage volume formed into the passage area 19 and, deflected by the lower slope of the bulge 16 , slows back into the interior of the shaft and flows past the opening 21 .

Since the angles of inclination of the bulge 16 and the inclined plate 17 are steeper than the angle of repose of the stored goods, no dead spaces or residual deposits can form. The shaft formed from such filling shaft sections runs completely empty when the silo cell is emptied.

Fig. 6 shows in longitudinal section a Füllschachtabschnitt having above a discharge opening 22, a deflection 25 with subsequent reverse bend 26, wherein about 23 corresponds in a preferred embodiment, the offset of the shaft diameter 24.

Successive sections forming a filling shaft inhibit the free fall of the filling material through the outward and backward bends and always direct it past the free outlet openings 22 , so that it can emerge from the last free outlet above the surface of the material into the interior of the cell. The filling shaft empties completely and does not form dead corners when filling or emptying.

FIG. 7 shows a filling chute section in longitudinal section, in each of which an outlet opening 29 is provided between its bend 28 and its back bend 31 .

Bulk material flowing down from above is deflected by such bends 28 and deflected past the outlet openings 29 , in order to then be deflected again through the back bend 31 into a subsequent vertical shaft area, a further outlet opening 29 being provided below the rear bend 31 . Correspondingly, successive filling chute sections have alternatingly opposite outlet openings 29 at different heights.

In a preferred embodiment, the offset 27 of the outward and backward bends 28 , 31 corresponds approximately to the shaft diameter 30 , its slope being steeper than the slip or repose angle of the filling material. This avoids dead corners during filling and ensures that the filling material runs out of the shaft.

FIGS. 8 and 9 show an internally smooth, conically opening below Füllschachtabschnitt in longitudinal and cross section, the outlet opening 32 of the Silozellenwand 33 facing in the distance. Falling material is steered after rising in the shaft up to the outlet opening 32 exiting the latter against this silo wall 33 and runs back to the interior of the cell calmly on both sides of the shaft.

In Figs. 10 and 11, a Füllschachtabschnitt with erstreckter almost over its entire length outflow opening 35 is shown in longitudinal and cross-section, in front of this outlet opening 35 preferably forming a curved brake plate 36 is disposed. This brake plate 36 has the same function as the silo wall 35 described above. Due to the large length of the relatively narrow outlet opening 35 , a sink zone that migrates upward with the outlet area forms in the shaft when filling, which initially acts as a brake on the falling product before it emerges on several sides between the brake plate 36 and the filling shaft into the cell.

The sections shown in FIGS. 8 to 10 can each be contained in a conventional weft of 2 to 3 in length. However, a shot can also have one or more outlet openings 32 and 35 arranged in alignment or offset one above the other. An outlet opening 35 can also extend over the entire length of the shot, so that there is correspondingly an outlet opening 35 over the entire vertical length of a filling shaft.

In Fig. 12 to 14 such shots in longitudinal and cross section are shown, which have their total load in the silo wall 41 opening the upper attachment means 40 as a welded profile angle, not shown here, top and bottom horizontal bevelled edges. The lower ends of the shot are supported by narrow cams 42 , leaving a gap 44 against the subsequent upper end of the shot below. These cams 42 are shown beveled at the top and bottom, and the upper and lower edges of the wefts also have the bevels 43 on the outside. Since the gap 44 is a multiple of the maximum grain size of the filling material, filling material which is exposed to vermin or which causes contamination cannot settle on or under the edges or in the gap 44 .

In Figs. 15 and 16, a silo in a longitudinal and cross section is shown, as described in what left a composite made up of sections hopper square cross-section with drop-inflammatory agents, similar as a section of Fig. 3, and on the right a hopper, similar as a section of is shown Fig. 10 and 11, the latter, however, over the entire length of the shots ranged outlet openings 45 and spaced arranged in front brake plates 46th The cross section of the filling shaft shown widens conically continuously downwards. With this embodiment, products that contain a lot of flour or flakes can also be stored and removed without segregation. The sloping floors 47 beneath the filling duct conduct falling material against the brake plate 46 at a falling speed, so that it can emerge calmly without segregation and without excessive dust formation in the outlet funnel of the cell.

FIGS. 17 and 18 show a Füllschachtabschnitt round cross-section, wherein the outlet opening has along its side edges 39 in preferred construction, parallel to its center line outwardly abkragende side walls 37, the lower edges by an obliquely to the lower edge of the outlet opening erstrecktes and connected to this baffle 38 are connected. With this arrangement it is achieved that in the filling chute near the inner wall or outlet opening area falling filling material is partially z. B. due to air flow due to the outlet openings in the upper free cell area, but guided by the side walls 37 and collected by the baffle 38 is returned to the filling shaft. The angle of inclination of the guide plate 38 is in turn preferably steeper than the angle of repose of the contents.

Reference list

1

Top edge

2nd

Outlet opening

3rd

Guide surface

4th

Rounding

5

Deflector

6

Silo wall

7

Outlet opening

8th

body

9

Top

10th

bottom

11

Rounding

12th

Bulge

13

Deflector

14

Rounding

15

Shaft diameter

16

Bulge

17th

Sloping plate

18th

Passage area

19th

Passage area

20th

Outlet opening

21

Outlet opening

22

Outlet opening

23

Offset

24th

Shaft diameter

25th

Deflection

26

Backbend

27

Offset

28

Deflection

29

Outlet opening

30th

Shaft diameter

31

Backbend

32

Outlet opening

33

Silo cell wall

34

Outlet opening

35

Outlet opening

36

Brake plate

37

Sidewalls

38

Baffle

39

Side edge

40

Fasteners

41

Silo cell wall

42

cam

43

Weird

44

gap

45

Outlet opening

46

Brake plate

47

Sloping floor

48

Outlet opening

Claims (21)

1.Filling shaft for non-segregating storage of granular or flake and flour-containing goods in silo cells, which, standing or attached attached to their interior, extends vertically or zigzag-like from the cell inlet to the cell outlet area composed of shots and has a round or polygonal cross-section and its shaft wall Has outlet openings ( 2 ) with internally assigned deflecting means, which, starting from the upper edges of the opposite opposite outlet openings ( 2 ), extend as alternating obliquely downwardly directed guide surfaces ( 3 ) into the filling shaft, these guide surfaces ( 3 ) for residue-free and self-cleaning discharge of the filling material into the upper edges ( 1 ) of the discharge openings ( 2 ) by means of roundings ( 4 ), which have a bending radius that lies in the area of the lowest passage through the shaft and the angle of inclination of the guide surface n ( 3 ) is steeper than the angle of repose of the product. 2. Filling shaft according to claim 1, characterized in that when arranged near a silo wall ( 6 ) the wall-side vertical side edges of the outlet openings ( 2 ) are assigned baffle plates ( 5 ). 3.Filling chute for non-segregating storage of granular or flaky and flour-containing goods in silo cells, which, standing or attached attached to their interior, extends vertically or zigzag-like from the cell inlet to the cell outlet area composed of shots and has a round or polygonal cross-section and in its shaft wall , Has outlet openings ( 7 ) with internally assigned deflecting means, wherein in the area above the outlet openings ( 7 ) from the inside wall of the shaft, which laterally lies on the inside and protrudes into its central region, is wedge-shaped with a sloping top ( 9 ) and a sloping bottom ( 10 ) trained body ( 8 ) are mutually arranged. 4. Filling shaft according to claim 3, characterized in that the inclined upper and lower sides ( 9 , 10 ) of the body ( 8 ) by means of fillets ( 11 ) pass into the shaft wall. 5. Filling chute for non-segregating storage of granular or flake and flour-containing goods in silo cells, which, standing or attached attached to their interior, extends vertically or zigzag-like from the cell inlet to the cell outlet area composed of shots and has a round or polygonal cross-section and in its shaft wall Has outlet openings ( 20 ) with internally assigned deflecting means, the shaft wall in the area above the outlet openings ( 20 ) having bulges ( 12 ) that protrude outwards and which, from the opposite inner wall of the shaft, lie laterally on the inside to the central region of the bulge ( 12 ). Directional wedge-shaped deflecting bodies ( 13 ) with an inclined top ( 9 ) and an inclined bottom ( 10 ) are assigned. 6. Filling shaft according to claim 5, characterized in that the extension of the deflecting body ( 13 ) from the shaft wall to the central region of the bulge ( 12 ) corresponds approximately to the shaft diameter ( 15 ). 7. filling shaft according to claim 5 or 6, characterized in that the oblique lower and / or upper sides ( 9 , 10 ) of the deflecting body ( 13 ) with roundings ( 14 ) pass into its shaft walls. 8.Filling chute for non-segregating storage of granular or flake and flour-containing goods in silo cells, which, standing or attached attached to their interior, extends vertically or zigzagged from the cell inlet to the cell outlet area composed of shots and has a round or polygonal cross-section and in its shaft wall having outlet openings (21) with an internal associated deflecting means, above the Auslauföffungen (21) in a protruding outwardly Auswulstung a directed from the center region of any bulging (16) forth down into the shaft, inside the side-fitting oblique plate (16) (17) is arranged, which divides the crop flow into two passage areas ( 18 , 19 ). 9.Filling chute for non-segregating storage of granular or flake and flour-containing goods in silo cells, which, standing or attached attached to their interior, extends vertically or zigzagged from the cell inlet to the cell outlet area composed of shots and has a round or polygonal cross section and outlet openings in its shaft wall ( 22 , 29 ), with alternating successive bends ( 25 , 28 ) and back bends ( 26 , 31 ) are provided which have an offset ( 23 , 27 ) which is in the range of the shaft diameter ( 24 , 30 ) and which Inhibit the free fall of the filling material and guide it past the free outlet openings ( 22 , 29 ). 10. Filling shaft according to claim 9, characterized in that between alternating successive bends ( 25 ) and back bends ( 26 ) each have outlet openings ( 22 ). 11. Filling shaft according to claim 9, characterized in that between the bends ( 28 ) and the back bends ( 31 ) each have outlet openings ( 29 ). 12.Filling chute for non-segregating storage of granular or flake and flour-containing goods in silo cells, which, standing or attached attached to their interior, extends vertically or zigzag-like from the cell inlet to the cell outlet area composed of shots and has a round or polygonal cross-section, whereby its cross-sectional area expanded from top to bottom in sections or over its entire length continuously conically or in successive parallel-walled stepped sections and that the wefts have outlet openings ( 32 , 35 , 45 , 48 ) which they each extend over a large part or all of the length the shaft wall extend. 13. Filling shaft according to claim 12, characterized in that it has a rising inclined bottom ( 47 ) starting at the lower edge of the lowermost outlet opening. 14. Filling shaft according to one of claims 12 or 13, characterized in that the outlet opening in the round filling shaft cross-section along its side edges ( 39 ) have outwardly projecting side walls ( 37 ) which have a guide plate ( 38 ) binding them obliquely to the lower edge of the outlet opening. assigned. 15. Filling shaft according to claim 12, characterized in that the outlet openings ( 32 , 35 , 45 , 48 ) outside the filling shaft are assigned opposite braking or deflecting surfaces. 16. Filling shaft according to claim 15, characterized in that the braking surface opposite the outlet openings ( 35 , 45 ) is formed in each case by a curved braking plate ( 36 , 46 ) placed at a distance. 17. Filling shaft according to claim 15, characterized in that the braking surface opposite the outlet openings ( 32 , 48 ) is formed by the silo cell wall ( 33 , 41 ). 18. filling shaft according to one of claims 15 to 17, characterized in that the space  between the braking surface and the filling shaft downwards flared. 19. Filling shaft according to one of the preceding claims 1 to 18, characterized in that a single shot near one end by fastening means at a distance on the silo cell wall ( 6 , 33 , 41 ) is initially attached to its total load, while the other end is sliding by means of several overlapping or intervening arbitrarily designed narrow cams ( 42 ) are supported against the opening wall of the next shot, in a preferred embodiment the fastening means ( 40 ) are fastened to the silo wall ( 41 ) near its upper end and cams ( 42 ) which slide over are provided at the lower end are. 20. Filler shaft according to one of the preceding claims 1 to 19, characterized in that all horizontal upper and lower edges of the shot ends, outlet openings ( 2 , 7 , 20 , 21 , 22 , 29 , 32 , 35 , 45 , 48 ), brake plates ( 36 , 46 ) and holding devices are designed as bevels ( 42 , 43 ), the bevel angle being steeper than the angle of repose of the stored granular, flaky or floury material. 21. Filling chute according to one of claims 1 to 20, characterized in that a gap ( 44 ) is formed between the lower edge of a shot and the upper edge of the shot below it, the height of which corresponds to a multiple of the maximum grain size or flake size of the stored bulk material.