FI56811C - BUNKER MED TOEMNINGSANORDNING - Google Patents

Description

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B 11 UTLÄGGNINGSSKRIFT S68 1 1 J * S§Ä · C (45) Patenlti tjrdr.r.:Uy 13 tl 1910 iSpi ^ g Patent xoddelat ^ ^ ^ (51) Kv.lk. '/ Int.CI. * B 65 G 65 / ^ (21) P »tenttlh» k «mu * - Patenttniölcnlng 3728/7 ^ (22) HaktmiipilvI - Ansöknlngsdag 20.12.7 ^ (Fl) (23) Home - Glltighetsdag 20.12.7 ^ (41) Become Public - Blivit offantllg 08.07.75

National Board of Patents and Registration (44x Nlhttv »date of competition and publication -

Patent and registration authorities Aniökan utlagd och utUkrlftan published 31.12.79

(32) (33) (31) Privilege requested. — Begird priority 07.01.7H

Federal Republic of Germany-Förbundsrepubliken Tyskland (DE) P 21 + 005 ^ 7.8 (71) Astrid Alice Saxlund geb. Erichsen, Heidberg 1, 30UO Soltau-Harber,

Federal Republic of Germany-Förbundsrepubliken Tyskland (DE) (72) Oddmund Saxlund, Soltau, Federal Republic of Germany-Förbundsrepubliken Tyskland (DE) (7b) Leitzinger Oy (5 ^) Silo with emptying device - Bunker med tihningsanordning

The invention relates to a silo equipped with an emptying device, in particular for dusty, chipped or shredded goods, comprising a silo bottom with at least one elongate outlet and a gutter or the like arranged below to drain the pulled-out goods. , having a plurality of elongate pull-out elements delimited at least in part on one longitudinal side by a lead surface at an acute angle to the silo bottom.

In connection with dry silage goods, a conveyor member such as a conveyor coil or the like is generally arranged in a chute arranged below the silo bottom.

In silos with a substantially circular cross-section, it is known to provide a rotor-like emptying or pull-out element in the middle of the silo for unloading the silo goods from the silo. This consists of a central support piece to which, for example, leaf springs or other circumferentially retracting and radially extending drawbars are attached. As the float traction element rotates continuously, the goods to be unloaded must be moved in the circumferential direction over one or more radial lowering openings arranged in the silo. The goods fall from the landing openings into the trough below, where the goods are transported away.

In general, a silo with a circular or polygonal cross-section is most preferred for most known reasons. Emptying with rotating pull-out elements has also proved satisfactory in most cases. However, it has been found that with a considerable amount of certain types of substances, uniform unloading of the substance stored in the silo is not possible with the rotating extraction element. In particular, in the vicinity of the outer circumference of the silo, several substances show compaction of the substance, which causes the elastic bending of the extraction arms backwards more and more. This eventually results in an outer annular, tightly packed layer of material near the bottom of the silo that can no longer be pulled out or unloaded from the silo. Also, uniform unloading, which is necessary for the quantitative dosing of the silage, is not achievable in most cases with rotating pull-out elements.

On the other hand, emptying devices for rectangular or rectangular silos are also known, in which a plurality of adjacent and mutually movable sliding conveyor elements with goods transport elements extending transversely to the direction of movement are arranged on the bottom of the silo. In this case, the return movement takes place due to the profile shape of the transport members without any appreciable transport effect, so that despite the reciprocating movement of the transport elements, the transport takes place mainly in one specific direction. However, in practice, rectangular or square silos are used to a considerable extent. In addition, for example, GB patent publication 1,069,334 discloses a silo with a circular cross-section which is formed in such a way that the circular shape does not extend over the entire height of the silo. At the lower end of the silo, the circular shape changes to a rectangular cross-sectional shape via a transition area arranged above the silo bottom. Sloping walls are provided in this transition area. At a distance below the rectangular cross-sectional shape of the transition area, a silo pony is arranged with two inclined bottom portions running along parallel longitudinal sides. Slotted landings are arranged in the area of the longitudinal side edges, which can normally be closed with closing devices. Collection chutes are arranged below the landing openings. The closure devices are operated by pressure medium cylinders arranged so that the piston rods of the cylinders extend over the inclined bottom surfaces 56811 and have a plurality of transverse and successively spaced pull-out elements with steep gripping edges.

These strip-like pull-out elements, together with the closing devices, are moved back and forth along the bottom surfaces along the pressure medium cylinders for a short distance, the stroke length corresponding approximately to the width of the pull-out elements. The area of the roof base covered by the pull-out elements is thus small compared to the total area of the base.

The starting point of this type of silo unloading device is to solve the unloading of the silo material over the entire cross-sectional area of the silo evenly, whereby a uniform sinking to a trough arranged below the opening, so that the goods can be removed from the trough with sufficient uniformity and accuracy for its intended dosing.

According to the invention, this object is achieved in that, by means of a circular or non-angular cross-section of the silo, the extraction elements form a sliding frame perpendicular to the silo axis and guided on the silo bottom can be covered by extraction elements by transfer, approximately corresponds to the cross-sectional area of the silo.

An embodiment of the invention will now be described in more detail with reference to the accompanying drawings, in which Figure 1 shows a vertical section of the lower part of a silo equipped with a discharge device according to the invention and Figure 2 shows a top view of the silo of Figure 1.

In the embodiment shown, the cross-sectional shape of the silo is circular.

5681 1 Alternatively, it may also have a different or polygonal cross-section.

In the embodiment shown, the silo 1, the center line of which is marked 2: 11a, rests on its lower end on an octagonal frame 3 consisting of individual, rectilinear U-steel beams 3a -3c, which can be welded to each other into an octagonal frame. The outer cylindrical curtain surface of the frame 3 is slightly larger and the inner, cylindrical curtain surface slightly smaller than the silo 1. The frame 3 delimits at its inner edge 15 a sliding surface for the extraction element to be described in more detail, which is slightly larger than the silo cross-sectional area. The device could also be constructed so that the inner curtain surface of the lower frame 3 is equal to the cross-sectional area of the silo. Suitably, the surfaces are selected so that complete extraction of the substance from the silo by means of the extraction element described is possible.

The frame 3 is placed on the bottom of the silo 4, which is provided with two, along the diameter of the two sides of the hopper central axis 2 säteettäises-ti extending fall aperture 23 and 24, which are associated with the downwardly extending and downwardly in the circumferential direction of the expanding intermediate chamber 5 and 6. The two chambers 5 and 6, the lower ends are connected to each other by a groove joint 7, which extends to one side of the silo and is provided with a drive 8 in the trough 7 for working in the arrow direction of the screw conveyor 9, which is marked with the center line 18 and the shaft 11a 20 11a. In the region of the landing opening 23, the screw vanes 21 of the conveyor screw have a lower steepness and in the region of the landing opening 24 these vanes 22 have a higher steepness. The device is constructed in such a way that the screw is able to pull out the two extraction openings in the casting down-van agent uniformly without deposition and blockage in the direction of arrow 9 direction.

A second transport chute 10 is arranged above the chute 7, but below the silo bottom 4, which is open upwards to the inside of the silo. This chute 10, the center line of which is marked with 19, contains a tubular push rod 11 which, in the example shown, has a circular cross-section. This rod 11 can be freely pushed in the trough 10 in the direction of the center line 19. It extends from one side, as Figure 2 shows, out of the trough and this end is articulated to a closer shaft of pressurized medium cylinder piston 17, which can push the push rod from the position shown in figure 2 5 56 811 16 by a predetermined stroke in both directions of the double arrow extent.

As can be seen from the top view of Fig. 2, the center lines 18 and 19 of the conveyor screw and the push rod intersect at right angles, the projected intersection point being on the vertical center line 2 of the silo 1.

A pull-out element 12 located above or immediately above the upper surface of the silo bottom 4 is rigidly connected to the push rod 11, which is entirely immediately below the upper surface of the silo bottom 4. As such, the extraction element 12 forms a closed frame which is substantially fitted to the cross-sectional surface of the silo or to the cross-section of the frame 3 supporting the silo.

In the example shown, the pull-out element 12 has an outer closed, approximately octagonal frame 26 and an approximately square inner frame 27 placed therein, which is further filled with a cross member 28. The individual elements or circumferential portions of the circumferential slide are 29 format. The short surface of this cross-section running approximately perpendicular to the base 4 forms a gripping surface which, depending on the direction of movement of the push rod 11, conveys the substance in the direction of the landing opening 23 or 24, as shown by short arrows next to the frame elements. The longest side of the triangle forms a flat or sharp angle with the silo base 4, chosen so that, depending on the material to be fed from the silo and the frame moving in such a direction that this oblique surface forms the front edge of the peripheral slide, this surface can penetrate under material without significant friction the uptake or condensation of the substance occurs to a significant extent.

The frame structure covers a considerable part of the cross-sectional area of the silo. The length of the stroke at which the pull-out element from the position shown in Fig. 2 can be moved in both directions is small. However, a smooth and smooth supply of material from the edge parts of the silo to the outlet openings is ensured. In this case, the emptying of the lower material layer takes place in a forced and efficient manner, so that an even and continuous filling of the feed screw is ensured. By correspondingly shaping the extraction element 12 forming the closed lattice structure and by correspondingly fitting the frame 3, it is possible to ensure complete emptying of the silo from the material filled in it. The device is very robust and interference-free and can be manufactured with simple and inexpensive tools.

The extraction element 12 may also have a different arrangement of the individual frame elements in a circular or other type of cross-section of the silo. However, it is particularly advantageous when most of the frame seeds form an angle with both the center line 18 of the screw and also with the center line 19 of the push rod 11.

Claims (5)

5681 1 A silo provided with an emptying device (12), in particular for dusty, chipped or shredded goods, comprising a sieve bottom (4) with at least one elongate outlet (23, 24) and a trough (10) or the like and a discharge device guided over the silo base (4) and reciprocating substantially perpendicular to the landing opening (23, 24), having a plurality of elongate pull-out elements (26, 27, 28) delimited at least in part by one longitudinal side to the silo base (4). ), characterized in that by means of a circular or polygonal cross-section of the silo (1) the extraction elements (26, 27, 28) form a silo base (4, 24) with a downwardly extending opening (23, 24) running perpendicular to the silo shaft (2). ) on a guided sliding frame (12) with a circumference approximately equal to the cross-sectional shape of the silo (1), and that pi which can be covered by the pull-out elements (26, 27, 28) by moving the sliding frame (12) corresponds approximately to the cross-sectional area of the silo. Silo according to Claim 1, characterized in that the sliding frame (12) consists of a circular or polygonal frame whose dimension in the sliding direction (16) is smaller than in the direction perpendicular to it. Silo according to Claim 1 or 2, characterized in that the pull-out elements of the sliding frame (12) form a closed lattice structure and are oriented obliquely in both the sliding direction (16) and the longitudinal direction of the lowering opening (23, 24), the gripping edges of the elements facing the lowering opening (23, 24). ). Silo according to Claim 3, characterized in that the extraction elements form an outer octagonal frame part (26) and an inner frame part (27, 28) arranged inside it. Silo according to Claim 4, characterized in that the inner frame part comprises a rectangular frame part (27) and a cross-shaped frame part (28).