SU844745A1 - Metal hopper for storage bulk materials - Google Patents

Description

(54) STORAGE FOR BULK MATERIALS

The invention relates to construction, in particular to storage structures for bulk materials.

Storage for granular materials is known, which includes segmented elements from pre-compressed concrete and hollow elements from ordinary concrete, which are connected by a pre-stressed reinforcement p3.

The strength of this storage is provided by the friction forces arising between adjacent full-bodied elements due to their reduction by vertical prestressed reinforcement and compression arising from the backflushing friction.

However, such storage does not provide sufficient strength, rigidity, durability and is applicable only for cylindrical layers, in addition, it is difficult to perform.

The closest to the invention to the technical essence is the storage for bulk materials, including silos, having rings connected in height by pre-tensioned power elements passing through the channels placed in them and attached to the supersilar and sub-slabs 12.

Such storage requires a significant consumption of materials for vertical power elements having a constant cross-section along the entire height of the structure, and is labor-intensive.

10 installation.

The aim of the invention is to reduce material consumption, simplify installation and increase storage rigidity.

This goal is achieved by

15 that in the storage for bulk materials, including silos, having rings connected in height by prestressed strength members passing through placed in them

The 20 channels and attached to the supersonic and subsurface slabs, the ends of the rings, are provided with niches that communicate with the channels made by paired, and

the rings are combined into groups, with the rings of the intermediate group being united by force elements located in one of the channels by a pair of pairs, among themselves, and by force elements located in the others; anal - with the upper and lower groups adjacent in height, the rings of the group adjacent to the sub-slab plate are connected by power elements located. in one of the channels of each pair, with this plate, and. the power elements located in other channels, the backing group, and the rings of the group adjoining the supersilon plate are connected by the power elements located in one of the channels to the sound of the pair, with it, and power elements located in other channels with the underlying group, while the channels in the rings are located on the outer surface of the storage.

FIG. 1 shows the proposed storage, section; in fig. 2 - the same, top view; FIG. 3 shows node 1 of FIG. 1; in fig. 4 is a section A-A of FIG. 3

 The storage is made of silos, having rings 1 in the walls of which along its perimeter are made in pairs through channels 2 and 3 in height, I inform Iiiies with niches 4.

Niches facing open part out. On the outer side of the ring in the planes of passage of the channels 2 and 3 there are holes 5 communicating with the channels.

The assembly of silos is carried out as follows.

After mounting the sub-sill plate 6, the first group of rings is mounted on it, the vertical force elements 7 are passed through all the channels 2, they are tensioned and then fixed using anchors 8. Then install the third ring so that Channels 2 and 3 of the adjacent rings coincide , and pass through the channels 3 the power elements 9, which are tensioned and attached by anchors 10 to the plate 6 and the third ring.

Next, set the next group, for example, of two rings, aligning the channels in the plane of the joint. The subsequent strength elements 11 are passed through the channels 2 of the third, fourth and fifth rings, the ends of which are fixed in the stitches of the second ring with the support on the bottom surface of the third ring, and from above - after the tension - in the niches of the fifth ring, resting on each niche of this ring.

Thus, the fifth, fourth, and third rings are connected into one rigid group by elements 11, and since the third ring is simultaneously formed by elements 9 of plate 6, a single rigid group of five rings is formed.

Further installation of the rings is carried out in a similar manner.

Moreover, to secure subsequent groups of rings, free channels 3 in the fourth and fifth rings and rings of subsequent groups are used.

The last group of rings is attached on one side to the underlying rings and the supersilite plate 12 on the other side. As a result, a single rigid silo structure is formed.

5 To improve the connection of adjacent rings

in height and sealing capacity

between the rings in the course of the erection, a layer 13 is made, for example from cement mortar, concrete

,, on fine aggregate, rubber and other materials. As a layer. 13 can also serve as a one-piece sealing gasket. In the latter case, the silo assembly process is significantly accelerated. In order to protect the vertical power elements from corrosion, to ensure their joint work with the walls of the rings, cement channels are injected into the channels 2 and 3 through the holes 5 and cement the niches 4 into the holes. Holes 5 in the rings are necessary so that the anchors of the vertical power elements can completely block

J channels on top and do not allow thereby to inject the solution.

The offset of channels 2 and 3. Closer to the outer surface of the ring wall, i.e. making them eccentric to the axis of the wall, when tensioning the power elements creates an additional moment across the entire height of the tank, preventing free transverse deformation of the structure, which greatly increases its rigidity, strength, crack resistance, and hence durability,

The sections of the power elements in each section of the tank are set in height in accordance with the diagram of the forces that penetrate the structure, thereby allowing the forces and movements to be controlled during the operation of the structure.

Claims (2)

Invention Formula 1, Storage for bulk materials, including silage, ring immersion, connected in height by preliminarily tensioned power elements passing through the channels placed in them and attached to the silo and sub-silos pin, tl and more that, in order to reduce material consumption, simplify installation and increase rigidity, the ends of the rings are provided with niches communicating with the channels made by paired, and the rings are combined into groups, the rings of the intermediate group being combined with power elements located in one and the channels of each pair together and force elements disposed in the other channels - with the upper and lower groups adjacent in height, the rings of the group adjoining the sub-axle plate are connected by power elements arranged in one of the channels of each pair, with this plate, and by power elements located in other channels by the overlying group, and the rings of the group adjacent to the above Q silo are connected by power elements located in one of the channels of each pair, with it, and by power elements located in the other channels - with the underlying 5 group. 2. The repository of claim 1, characterized in that the channels in the rings are located at its outer surface, 0 Information sources, taken into account in the examination 1. Lipnitskny ME, et al. Reinforced concrete silos and silos, L., 1967, 5 s. 182-183. 2. USSR author's certificate in con. No. 2493278 / 29-33, cl. E 04 H 7/22, 1977.