SU1520186A1 - Drainage arrangement - Google Patents

Abstract

The invention relates to the field of construction and mining, in particular to drainage devices for draining loose and unconsolidated soils and is aimed at improving the efficiency of draining loose soils. This is achieved by the fact that the frame is made in the form of adhesively connected transverse and longitudinal fibers of polyethylene. The distance between the longitudinal fibers increases towards the middle of the cross section of the framework. The strength of the framework is assumed to exceed at least 1.2 times the calculated value of the highest rock pressure. 2 Il.

Description

The invention relates to construction and mining, in particular to drainage devices for draining loose and unconsolidated soils.

The purpose of the invention is to increase the efficiency of drainage of loose soils.

Figure 1 shows the device, a general view; figure 2 is a comparative graph of the performance of the devices of the proposed and known designs.

The drainage device comprises a skeleton 1 and a water-permeable shell 2 enclosing it. The skeleton 1 consists of intersecting polyethylene fibers 3, adhesively bonded to each other in the transverse and longitudinal directions, which form a strong skeleton 1 with pores 4. The strength characteristics of the skeleton 1 can be changed by use of polyethylene fibers of different density, frequency of their application and fiber diameter. The greater the frequency of overlap and the diameter of the filaments, the greater the resistance of the framework to compression. Experiments have shown that the compressive strength of frame 1 should be at least 1.2 times greater than the value of the highest rock pressure. The permeable shell 2 is placed around the perimeter of the frame 1 and is bonded at the junction 5 with an adhesive, for example, waterproof glue. Shell 2 is made of a material with a pore size close to

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to the pore size of the soil being drained. As a material, you can use paper impregnated with formulations to increase resistance to defrosting.

Drainage device operates as follows.

The drainage device is introduced into unconsolidated loose low-permeable water-rich ground to a predetermined depth. After that, a static or dynamic load is applied to the surface of the soil, under the influence of which, as well as under the action of capillary forces, the water from the soil is pressed into the device. The water passes through the permeable casing 2 and enters the fibrous frame .1 and through it is unobstructedly diverted beyond the limits of the drained part of the soil. The smooth surface of the frame 1 ensures reliable interaction with the water-permeable shell 2 without creating a concentration of stresses leading to rupture or unacceptable deformation of the shell 2 material. The elastic properties of the frame 1 prevent it from being compressed under the influence of pressure from the dried soil. Stable contact of the frame with the shell and high porosity of the frame in the center increase the efficiency of water drainage.

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The proposed drainage device was tested together with a device of known design, the test results are shown in the graph (figure 2), according to which the proposed device has a capacity 1.5 times higher.

This embodiment of the drainage device increases the reliability of its operation during operation and improves the conditions for draining water from the drained array of loose soils. Its use is most effective when draining loose soils with an increased specific weight, for example, of iron waste.

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Claims (1)

Formula of gain Drainage device, including a polyethylene frame and covering its permeable shell, about t -. Characterized by the fact that, in order to improve the efficiency of draining loose soils, the framework is made in the form of adhesively connected transverse and longitudinal fibers, and the distance between the longitudinal fibers is increased to the middle of the cross section of the framework, and the compressive strength of the latter is greater than at least 1, 2 is the estimated value of the highest rock pressure. Phi2.1 50 120 180 2QO 360 20 W BpPMfl, min FIG. 2