DE102015105703B4 - Fahrsilo - Google Patents

Abstract

Travel silo, comprising a base plate (12) and side walls formed from wall elements (1), the wall elements (1) each having a base body (2) made of concrete, characterized in that on one surface side of a wall element (1) one or more plates ( 3) of polymer concrete are applied or cast, wherein the wall elements (1) are arranged so that the plates (3) made of polymer concrete on the inner sides (4) of the side walls, wherein the joints between the wall elements (1) with an acid-resistant Joint material are sealed and wherein joints between the wall elements (1) and / or joints between adjacent plates (3) made of polymer concrete are sealed with an acid-resistant joint material.

Description

The invention relates to a silo, as is known from the DE 20 2013 102 699 U1 is known.

Silos are used in agriculture for the preservation and storage of vegetable raw materials, in particular of green fodder for animal feed. However, silos can also be used for the preservation and storage of vegetable raw materials that are to be used for energy production. The vegetable raw materials that are introduced into the silo are transferred there by lactic acid fermentation in silage. Typical are high silos and silos. The latter usually have a bottom plate and sidewalls delimiting a silo space bounded downwardly by the bottom plate and typically on three sides by the sidewalls. The side walls are usually composed of precast concrete elements.

The conversion of the introduced into the silo plant raw materials in silage is associated with the emergence of a so-called silage seepage, which may have a low pH, for example, a pH of 4 and less, up to 2. If this silage seepage juice comes in contact with the bottom plate and the side walls of conventional silos, it attacks the concrete of these components, whereby the silage seepage juice can escape from the silo. In practice reinforced concrete silos are manufactured with acid-resistant concrete of exposure class XA4. However, according to the valid concrete standards, this does not cover pH values below 3 of the silage seepage juice; H. there is no concrete that, untreated, withstands the chemical attack of silage seepage juice. For this reason, an acid-resistant coating of the reinforced concrete silo components is indispensable.

The DE 20 2013 102 699 U1 proposes to solve this problem before a silo, which has a multi-sloped bottom plate with a slope to the side walls. The side walls of the silo have a surface of an acid resistant, corrosion resistant material. In addition, perforations should be formed, which should allow the outflow of silage seepage juice from the silo. The sidewalls, which have a surface made of an acid-resistant, corrosion-resistant material, should either consist of an inert plastic or of concrete which is coated with an inert plastic.

The DE 20 2013 102 699 U1 provides that the components of the sidewall are sealed neither to each other nor to the bottom plate via a binder or jointing material. Columns, gaps or joints between the components of the side wall and between the components and the bottom plate to allow the escape of silage seepage formed in the storage area.

However, it has been found that the durability of such sidewalls hardly exceeds the widely used bitumen coating. For this reason, those in the DE 20 2013 102 699 U1 required as a significant gradient in the bottom plate required. Acid-resistant coatings are damaged by the mechanical stress in a silo. For cost reasons, the coatings are usually at most 1 mm thick. To ensure permanent protection, an annual coating of the entire interior wall surface of the silo is therefore necessary. Because the cost of the coatings is from 3.00 to 26.00 EUR / m ² , the seemingly cheap bitumen coating is still preferred in practice.

The object of the invention is to provide a silo with wall elements, in which damage to the wall elements of the Siloseitenwände over a period of several years by silage seepage juice is prevented even under mechanical stress.

This object is solved by the features of claim 1. Advantageous embodiments of the invention will become apparent from the features of the dependent claims.

According to the invention a silo is provided which has a bottom plate and side walls formed from wall elements, the wall elements each having a base body made of concrete, wherein on one surface side of a wall element one or more sheets of polymer concrete are applied or poured, wherein the wall elements so arranged that the sheets of polymer concrete are on the inner sides of the side walls, wherein the joints between the wall elements are sealed with an acid-resistant joint material, and joints between the wall elements and / or joints between adjacent sheets of polymer concrete are sealed with an acid-resistant joint material.

Polymer concrete is understood to mean a material made of concrete in which the hydraulic binder is completely or partially replaced by concrete additives based on synthetic resins, in particular reaction resins, in order to improve the processing and / or use properties. Preferably, the polymer concrete is a concrete that does not contain cement. The synthetic resin may be, for example, an epoxy resin. A polymer concrete containing no cement, but an epoxy resin as a binder, is acid-proof, so that the polymer concrete can not be attacked by silage seepage juice. The basic body is preferably made of steel concrete, for example made of reinforced concrete of exposure class XA4.

The wall elements are arranged for the production of sidewalls of a traveling silo according to the invention so that the sheets of polymer concrete are located on the inner sides of the wall elements, ie the sides of the wall elements which face the silo space.

Due to the use of a plate of polymer concrete can be dispensed with a coating of the wall element. The wall element therefore has no coating. The wall element has a life span of 20 years and more, even if the inner side coated with the polymer concrete panel is permanently exposed to seepage. An annual renewal of a coating or even the polymer concrete slab is not required.

The polymer concrete plate preferably has a thickness of between 5 and 20 mm. As a result, the polymer concrete slab withstands mechanical attacks, even if they occur repeatedly. More preferably, the polymer concrete plate has a thickness of between 10 and 15 mm. More preferably, the polymer concrete plate has a thickness of 12 mm. It has been found that a thickness of 12 mm is particularly suitable to prevent mechanical attacks. Should damage nevertheless occur, they can be easily repaired with a suitable synthetic resin spatula. If the polymer concrete slab has an epoxy resin as binder, the synthetic resin filler is expediently a spatula made of epoxy resin.

To attach the polymer concrete slab to the base member, a back anchor may be provided to permanently secure the back of the polymer concrete slab to the surface side of the base member to which the panel is to be applied. The anchoring may be one or more anchoring elements, for example stainless steel anchors cast in the polymer concrete slab. In addition or as an alternative to the fastening by means of back anchoring, provision may be made for the polymer concrete slab to be enclosed by the basic body. This can be achieved by pouring the polymer concrete slab into the surface of the panel to which the panel is to be applied. After pouring, the polymer concrete slab is exposed on the surface side facing away from the base element.

It can be provided that in a base body, a recess is formed, in which the plate made of polymer concrete inserted or, as described above, poured. The recess of the base body may be bounded by an edge which is formed on the longitudinal edges and on the lower edge of the base body. At the top edge, the recess may be open or closed. Instead of the lower edge, the edge of the recess can also adjoin a region which is formed on the lower edge. The main body may also be plate-shaped, wherein the recess is introduced in one of its surface sides.

It may further be provided that on the surface side of the base body, on which the polymer concrete slab is applied, an area is formed, which is not covered by the polymer concrete slab. This area expediently adjoins the lower edge of the main body. As a result, not the entire surface side carrying the polymer concrete slab is occupied by the polymer concrete slab. However, it is preferred that the polymer concrete slab extends to the upper edge of the main body and thus forms part of the upper edge of the wall element. If such a region is provided, then the edge of the recess can adjoin this region-and not the lower edge.

In the adjoining the lower edge region of the base body may be formed openings for receiving reinforcements. In this case, the openings, starting from the outer surface sides of the wall element, extend over the entire thickness of the wall element. The openings make it possible to insert reinforcing elements, typically reinforcing bars, into the openings for mounting a wall from the wall elements. For this purpose, the wall elements are placed on the construction site with its lower edge in the installation level and aligned vertically. Subsequently, the reinforcement elements for the connection of the reinforcement to the base plate to be produced are guided through the openings of the wall elements and finally poured the bottom plate, whereby the wall elements are clamped in the bottom plate. In this way, the wall elements obtained after curing of the bottom plate high stability and are statically stable, without stiffening supports, ring anchors, additional foundations or other support or securing elements are required. The wall elements allow quick installation, because in contrast to the prior art, a clamping in the bottom plate is achieved.

Preferably, the wall element has a trapezoidal cross-section, wherein the wall element wider at its lower edge than at its Top edge is. In other words, that means that the wall element tapers from the lower edge to the upper edge, wherein the distance of the outer surface sides of the wall element from one another decreases from the lower edge to the upper edge. However, the thickness of the polymer concrete slab preferably remains constant. Also, the distance between the longitudinal edges of the wall element is preferably constant over its entire extent in the height direction. The polymer concrete slab may be up to 4000 mm in height direction z. The polymer concrete slab may have an extension of up to 2000 mm in the length direction x. Thus, the polymer concrete plate can have a maximum plate size of 2 x 4 m. If the surface side of the main body has a larger area, then a plurality of sheets of polymer concrete can be applied to the surface side of the base body in such a way that they adjoin one another at their edges. Joints between adjacent sheets of polymer concrete can then use a suitable acid-resistant material, for example an acid-resistant joint material as SIKAFLEX ^® Plus TS Sika or Silresist ^® from Denso, are closed. This can be done, for example, by filling.

In the length direction x, the wall element can have an extension of up to 2400 mm. The trapezoidal cross-section preferably corresponds to an isosceles trapezoid.

Preferably, the wall element has a thickness which is between 80 and 300 mm. Preferably, the thickness of the polymer concrete slab is between 5 and 20%, more preferably between 8 and 15% of the thickness of the wall element. If the wall element has a trapezoidal cross section, then this information relates to the thickness of the wall element at the upper edge of the wall element.

If the wall element has a trapezoidal cross-section, then it can be provided that its thickness at the lower edge is 260 mm, at its upper edge 140 mm.

The side walls of the silos may be anchored in the bottom plate via reinforcing elements, which are guided through openings in the wall elements. The wall elements may be arranged to the bottom plate so that the portions of the side walls, which form the inner sides of the silo and are located above the top of the bottom plate, extending from the top of the bottom plate to the top of the wall element. The adjacent to the lower edge of the wall elements area in which the openings are located below the top of the bottom plate and therefore need not be protected by means of the sheets of polymer concrete from silage seepage juice.

• 1 eine Draufsicht einer Ausführungsform des Wandelementes eines erfindungsgemäßen Fahrsilos;
• 2 eine Schnittdarstellung der in 1 gezeigten Ausführungsform des Wandelementes entlang Linie A-A von 1; und
• 3 eine perspektivische Darstellung der in 1 und 2 gezeigten Ausführungsform des Wandelementes.

The invention will be explained below with reference to an embodiment which is not intended to limit the invention, with reference to the drawings. Show

• 1 a plan view of an embodiment of the wall element of a traveling silo according to the invention;
• 2 a sectional view of in 1 shown embodiment of the wall element along line AA of 1 ; and
• 3 a perspective view of in 1 and 2 shown embodiment of the wall element.

The in the 1 to 3 shown embodiment of a wall element 1 the driving silo according to the invention has a basic body 2 and a plate 3 made of polymer concrete. The plate 3 made of polymer concrete is on a surface side of the body 2 applied and is the part of the first surface side of the wall element 1 that the inside 4 of the wall element 1 forms when the wall element is part of the side wall of a moving silo. The inside 4 the wall element is facing the silo of the silo. The second surface side of the wall element 1 which faces the first surface side thereof forms the outside 5 of the wall element, if it is part of the sidewall of the silo. The first surface side is therefore as inside 4 , the second surface side as outside 5 denotes, even if the wall element 1 not shown as part of a sidewall of a silo.

At the bottom edge 8th of the wall element 1 borders an area 10 on, not from the plate 3 is covered and the equally spaced openings 11 has, through the reinforcing elements for anchoring the wall element 1 in a floor plate 12 can be performed. The bottom plate 12 is in 2 indicated by a dashed contour. The top 13 the bottom plate 12 is located above the area 10 so that the section of the inside 4 of the wall element 1 which is above the top 13 the bottom plate 12 lies, from the plate 3 is formed. In this way, the wall element 1 wherever it can come into contact with silage seepage juice, against its effects through the plate 3 protected. Joints between the wall elements 1 and / or joints between adjacent panels 3 Polymer concrete is with an acid-resistant jointing material, for example SIKAFLEX ^® Plus TS Sika or Silresist ^® Denso sealed.

It is in 1 to recognize that the plate 3 made of polymer concrete in a recess in the body 2 is poured. The recess is from a rim 6 limited to the longitudinal edges 7 and at the area 10 of the basic body 2 is trained. At the top 9 of the wall element 1 no edge is formed.

The wall element 1 has a trapezoidal cross-section and tapers from the bottom edge 8th to the top edge 9 , At the top 9 it has a thickness of 140 mm, at the bottom edge 8th of 260 mm. The plate 3 has a constant thickness of 12 mm, an extension in the height direction z of 4000 mm and an extension in the length direction x of 2000 mm. The extent of the wall element 1 in the height direction z is in the example shown 4250 mm and results from the extension of the plate 3 and the area 10 in the height direction z. In the length direction x has the wall element 1 an extension of 2400 mm.

At the longitudinal edges 7 of the wall element 1 can grooves 14 be formed, extending from the lower edge 8th to the top edge 9 of the wall element 1 extend and the mounting of a side wall of wall elements 1 to facilitate.

LIST OF REFERENCE NUMBERS

1

wall element

2

body

3

Plate made of polymer concrete

4

inside

5

outside

6

edge

7

longitudinal edge

8th

lower edge

9

top edge

10

Area

11

opening

12

baseplate

13

Top of the bottom plate

14

groove

Claims (8)

Travel silo, comprising a base plate (12) and side walls formed from wall elements (1), the wall elements (1) each having a base body (2) made of concrete, characterized in that on one surface side of a wall element (1) one or more plates ( 3) of polymer concrete are applied or cast, wherein the wall elements (1) are arranged so that the plates (3) made of polymer concrete on the inner sides (4) of the side walls, wherein the joints between the wall elements (1) with an acid-resistant Joint material are sealed and wherein joints between the wall elements (1) and / or joints between adjacent plates (3) made of polymer concrete are sealed with an acid-resistant joint material. Silo after Claim 1 , characterized in that the plate (3) made of polymer concrete is anchored to the base body (2) by means of an anchoring element. Silo after Claim 1 or Claim 2 , characterized in that the plate (3) made of polymer concrete from the base body (2) is enclosed. Silo after Claim 3 , characterized in that the base body (2) has a recess into which the plate (3) made of polymer concrete is inserted. Silo after Claim 4 , characterized in that the recess of the base body (2) by an edge (6) is limited, which is formed on the longitudinal edges (7) and on the lower edge (8) of the base body (2). Travel silo according to one of the preceding claims, characterized in that on the surface side of the base body (2) on which the polymer concrete slab (3) is applied, a region (10) is formed which does not project from the polymer concrete slab (3) is covered, wherein the top (13) of the bottom plate (12) is located above the region (10). Travel silo according to one of the preceding claims, characterized in that the polymer concrete slab (3) has a thickness of between 5 and 20 mm. Travel silo according to one of the preceding claims, characterized in that the wall elements (1) have a trapezoidal cross-section.

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