RU1795061C - Granary - Google Patents

Abstract

Usage: in the construction of agricultural facilities. The granary is in the form of a flexible shell resting on a frame. The shell is made with a cross-section with a variable height, having a large and a small axis of symmetry, which monotonously vary in length with a height of two mutually perpendicular planes, the small axis decreases with height, the frame includes two rods that are located symmetrically relative to the vertical inside the shell planes of the minor axis and touch their side surface on the inner side of the shell, between the rods inside the shell one or more spacers are inserted in the form of bars, the shells have the same cone clarity and oval in plan. A ballast layer, extracted from the soil, is poured into the lower shell to a level located above the floor level; a diaphragm with curved edges adjacent to the shell is installed on the ballast layer. The conicity of the casing is less than twice the coefficient of friction of grain sliding on the inner surface of the casing. The shells are made of polyethylene terephthalate film. 4 s.p. f-ly, 11 ill. ё

Description

The invention relates to the construction of agricultural facilities and can be used to store bulk materials, in particular grain, directly at the place of harvest.

A granary is known, including a wall of metal conical shells mounted on top of each other with equal taper, a frame and a bottom attached to the wall.

The aim of the invention is to simplify the installation and dismantling of a granary in the field.

This goal was achieved thanks to a new design that ensures the continuous transition of the wall to the roof, the use of soil as a means at hand and a high-strength film of lolizyleneterephthalate.

Figure 1 shows a granary, a General view in section; figure 2 is a section aa in figure 1; in Fig.Z - section bB in Fig.1; in Fig.4 is a view In Fig.Z; Fig. 5 is a diagram of a foundation construction; figure 6 - additional with; in Fig.7 is a view of G in Fig.6; Figures 8-10 show successive positions of the shell during the assembly of the wall; in FIG. 11 is a view D in FIG. 10.

The granary includes a wall 1, which is supported by a frame 2. The wall is made with a section o 3 of variable height and a section 3 having a large 4 and a small 5 axis of symmetry. With height, the major axis of symmetry increases in the vertical plane 6, and the minor axis of symmetry decreases in the vertical plane 7. The frame is made of two rods 8 and 9 placed symmetrically inside the wall

XI Yu SP O O

relatively small axis of symmetry. The lower ends of the 10.11 rods are fixed.

The lateral surface 12, 13 of the rods touches the inner side 14 of the wall. The rods are made of pipes and interconnected by one or more spacers 15,16,17, which can be installed or removed separately.

The wall is formed by conical shells stacked on top of each other.

18, 19, with the same taper. The shells are made of flexible material with the ability to take the shape of a circular truncated cone without folds. The taper of the shells is less than twice the coefficient of friction of the sliding of grain on the inner surface of the rim. Opposite sides 21, 22 of the upper shell 20 are connected by upper edges 23 in a region 24 which is bounded by an arc 25 of a circle. Arc 25 tightens an angle proportional to the conicity of the shell.

The lower shell 18 is filled with soil 26 of soil 27, extracted from the upper soil layer 28. The soil is filled with other level 29, located above the level 30 floor. Soil filling is performed without special tamping. On the ground 27, a bottom 31 is placed with bent edges 32 adjacent to the wall. The shells 18 and 19 completely overlap and form a composite lower shell 33, composed of two layers of 34.35 films. .. -; . . ..-.: ...: -. ..

The implementation of the lower part of the wall allows options (see figure 5, b, 7). The conical shell 36 can be freely mounted on the foundation 37, in which the soil layer 38 is bounded around the perimeter 39 by another conical shell 40. On the shell 18,

19, an additional jacket may be worn outside in the form of a band 41 including a series of rods 42, 43, 44 which are oriented along the generatrix of the jacket and are connected by flexible rings 45,46.

Under the bottom 31 there is a tee 47 oriented along the minor axis 5 with a piston 48 covering the bottom of the vertical pipe 49 inserted into the hole 50 of the central part 51 of the bottom with the possibility of moving the piston in the linear part 52 of the tee-a. The elastic ends 53, 54 of the tee are brought out from under the upwardly curved portion 55 of the lower edge 56 of the wall through the bulk ramp 57 and are closed with plugs 58, 59. The tee and piston are used to unload grain that is poured into the wall sheaths to level 60.

When assembling the granary, tee 47, rods 8, 9 with spacers 15. 16, .17, are installed on the field, then the lower shell 18 or 40, which is fixed from the inside with soil prepared in advance or filled up from above, form a soil layer, lay the bottom 31 on it; Other wall shells are sequentially worn on the installed shell. To do this, pre-flatten the shell to obtain a linear dimension that exceeds the dimension of the pair of rods 8, 9 in their upper

0 parts. Grain filling can be done simultaneously with the assembly, up to the level of the upper edge of the clad shells. The latter, after the filling of the grain is finished, put on the upper shell 20, which performs the function of the roof. The lower shell 18 can be replaced by a series of clad and shorter intermediate shells, successively covered with grain, which reduces the complexity of filling the grain, so

0 as filling lower posts requires lifting the load to a lower height.

The method of dressing the shell 61 on the lower part of the wall 62, obtained by deformation of the truncated cone 63, is illustrated

5 by a circuit (see FIGS. 8-11). The arrows indicate the movement of the shell and the movement of the points 64, 65, 67.69 of the cone to the points 66.68.70 of the wall. To unload the grain, the elastic ends 53, 54 of the linear part 52 are bent downward

0 of the tee, the plugs 58, 59 are removed, the piston 48 is withdrawn from under the nozzle 49 to one of the ends 53.54, after which the grain, under the pressure of its own weight, is poured from the other, open end into the supplied container. For

5 piston movements can be used rod inserted into the tee through one

ends 53, 54, or a cable missed

along the axis of the piston and permanently bonded with

him (not shown). If necessary, for example, with the formation of lumps of grain,

a piston can be used to push grain. Tee also allows

apply grain suction or impact on

a grain of compressed air, for example for sushi.

5 ki of grain or unloading.

The shells 18.19, 20 are made of a polymer film - polyethylene terephthalate (lavsan) 0.2-0.3 mm thick and 1-3 m wide. Sleeve-shaped shells can be obtained during the manufacturing process of the film or by gluing a strip of film. The required taper of the shell can be provided by rounding the strip or by docking it. CC at an angle. A taper of 0.2 and

5 less at the coefficient of friction of the grain – film pair 0.15–0.3 in the static mode, i.e. when extrapolating to zero relative speed. The diameter of the granary in the base is 2-3 m, the total height is 3-5 m, the mass of stored grain is 5-10 tons, the film consumption is less than 2 kg per ton of grain with more than two times the margin of safety.

The closure region 24 of the sheath 20 is obtained by joining the edges by contact welding or waterproof adhesive. Hollow rods 8, 9, spacers 15, 16, 17, piston 48 are made of polymer or aluminum alloy. Bottom 31, tee 47, plugs 58, 59 are made of rubber type elastomer,

The bottom 31 may be duplicated by a litter of a polyethylene terephthalate film for better protection against rodents, which, as experience has shown, are not able to damage this film. To simplify transportation, the rods and spacers may be composed of shorter tubes. Additional means may be used to unload the grain - raising the shell to form a gap between adjacent shells or cutting a hole in one of the shells.

The relationship between the conicity of the casing and the friction coefficient is due to the fact that the resultant grain pressure on the casing obtained by deformation of the cone (see Fig. 8, 10) is directed upward. It facilitates the lifting of the casing when it is separated from the rest of the wall, and when tapering , greater than twice the coefficient of friction, is capable of causing such a separation itself. In the latter case, the shells must be bonded to each other and to the ground, for example, using slings that allow for quick dismantling of the granary.

When installing the granary, there is no need to build a roof, a special foundation, or a platform for placing grain above the floor level. The role of the roof is performed by the upper shell, which, like the rest of the shells, is rolled up, and the foundation is the bulk soil, which is kept from creeping by the lower shell. Conical geometry simplifies wall mounting from separate shells and reduces the complexity of loading the granary.

The manufacture of shells from a film of polyethylene terephthalate (lavsan) significantly - several times - reduces the weight and cost of the granary in comparison with, for example, aluminum and, in addition, creates qualitatively new advantages: it has tensile strength (120-140 MPa) close to strength aluminum, and the elastic modulus (3520 MPa), 20 times smaller than that of aluminum, the lavsan film with a double margin of safety allows elastic elongation of 2.%, which ensures uniform load distribution between two or more layers of the shell, obtained th overlay of single-layer sleeves. The flattening of the cross section of the granary with height is compensated by the decrease in the pressure of the grain on the wall.

Creating a margin of safety at a large granary requires a thickening of the wall - up to 0.6 mm for 20 tons of grain. In this design, this is achieved by joining two shells with a film thickness of 0.3 mm. A monolithic film with a thickness of 0.6 mm or more would be unacceptable due to the loss of flexibility, which complicates its transportation, installation and dismantling of the granary. Moreover, an increase in film thickness is accompanied by a decrease in its specific strength.

A reserve for further reduction in the dead weight of the granary is in this design the possibility of reinforcing the shells with fibers oriented along the perimeter, for example, by winding at the stage of manufacture of the sleeve. Rigid aramid fibers with a tensile strength of 2.8 GPa and an elastic modulus of 83 GPa can be used, which makes it possible to increase the tensile strength of the sheath by more than 10 times. In this case, the initial conical shape of the shells, which ensures their tight fit against each other during a loose fit, reduces the requirements for the accuracy of the manufacture of shells. Such an effect cannot be obtained in the case of cylindrical shells, since the contribution of elastic deformation to the compensation of inaccuracies is small due to the high elastic modulus of the fibers. A variant of the granary is possible in which the reinforced shell covers the outside of unreinforced, capable of significant elastic deformation during loading of grain.

The adherence density of the bulk soil to the inner surface of the lower shell is ensured automatically, due to the gradual shrinkage of the soil under grain pressure. The soil layer 26 can be made with a core of a denser and more viscous material, for example clay, and a periphery of a more loose material, for example sand or a dried topsoil, which makes it easier to give the lower shell 40 a symmetrical shape. To simplify such a construction of the foundation 37, the core can be enclosed in a lavsan film band located inside the lower shell and separated from it by a gap that is filled with bulk material.

Lavsan shells are chemically inert with respect to grain and, unlike aluminum, are not subject to corrosion in contact with the ground. With increased requirements to

the storage of other bulk materials mylar shells can be made with a polyethylene coating. The granary is resistant to frost up to -50 ° С. Rodents and birds cannot damage it due to the durability of the dacron shells and litter, as well as due to the shape of the shell that is smooth and streamlined from top to bottom.

In the idle state, the lavsan shells are rolled up, where, in order to avoid creases, the components of the collapsible rods and frame struts are inserted.

Unlike the well-known granary described several times easier and cheaper, it is easy to assemble anywhere on the floor for an hour, disassemble and transfer.

SUMMARY OF THE INVENTION 1. A granary comprising a wall of conical shells mounted on top of each other with the same taper, a frame and a bottom attached to the wall, characterized in that, in order to simplify installation and dismantling, the wall is made with an oval cross-section, the length of the major axis of symmetry which increases, and the length of the minor axis of symmetry decreases along the height of the wall, the frame is made of two rods placed inside the wall symmetrically with respect to the minor axis of symmetry and interconnected by one or several kimi spacers and the shell - of a flexible material, the upper edge of the upper shell soedine12

Claims (5)

1 8 34 t in 5 0 5 They are interconnected, and the lower shell is covered with soil on which the bottom is located. 2. Granary pop. 1, characterized in that the conicity of each shell is less than twice the coefficient of friction of grain sliding on the inner surface of the shell. 3. The granary according to claim 1, with the fact that the shells are made of a film of polyethylene terephthalate. 4. Granary storehouse according to claim 1, characterized in that the lower shell consists of several layers. 5. The granary according to claim 1, with a rout e so that it is provided with an additional shell with rods placed along its generatrix, interconnected by flexible rings. / 3-18 sixteen / 7 HJ / Si 4728 27 1L1 thirty Figure 1  ,:. ; ---: - -; --- vV: ..; {. ;; ..:.;: .. .- ....:. ..-.; .,. h -,: -.;. . : -. .. -. .....:. ,. - ..   .,.: .-. .-.-....----. - ::,;. --H, - - -. . . /.,. . ; ... .. -: -:..; -: -y -;:; .-;.; ..; - -v. .-; -: - :::; F%; ..-.-.; :: -X; -: -%: v. V .... .....   . v .., (.) y. ----- -; --.-...-.:,:.: .-. -.-- 4V-. ----- .g .- -: - :::; F Phi No. VidL