RU2374386C1 - Method for creation of antifiltration screen with geomembrane from polymer material - Google Patents

Abstract

FIELD: construction, hydrotechnical construction.

SUBSTANCE: invention is related to the field of hydrotechnical construction and may be used to create antifiltration protection of waste accumulators bed and reservoirs of various purpose. Method for creation of antifilration screen with geomembrane from polymer material includes preparation of soil foundation, laying of water permeable membrane on it, which consists of polymer material webs tightly attached to each other, arrangement of compensators of geomembrane deformations with butt joint of webs in areas of compensators arrangement and closing of joints at the bottom and top with strips of material, which differs from material of geomembrane, arrangement of protective layer of screen. Prior to installation of polymer material webs onto prepared soil foundation, areas are defined for location of geomembrane deformations compensators, where then polymer material webs are laid in a butt joint without attachment of webs between each other. On surface of soil foundation under each butt joint they previously install protective-insulating pad from impermeable material, above it antifriction pad is laid from material, friction coefficient of which by geomembrane material is lower than coefficient of geomembrane material friction along foundation soil, then the same antifriction pad is laid above butt joint and is covered from top with protective-insulating pad of impermeable material.

EFFECT: invention makes it possible to provide for required mobility of compensator without damage of film antifiltration element (geomembrane) with preservation of its tightness.

8 cl, 3 dwg

Description

The invention relates to the field of hydraulic engineering and can be used to create antifiltration protection for the bed of waste accumulators and reservoirs for various purposes.

A known method of creating an anti-filter screen, including preparing a soil base, laying a waterproof geomembrane in the form of panels of polymeric materials, for example a plastic film, joining the panels by welding or gluing, the device of a protective layer of soil or other materials [1, Fig. 2d].

The disadvantage of this method is that when the screen is arranged over a large area due to the large coefficient of linear expansion of polymeric materials, the film element of the screen is subject to large temperature deformations. For example, a reduction in the linear dimensions of a polyethylene film during cooling by 50-60 ° C is more than 10 cm for every 100 m. With rigid fixing of the edges of the screen and the inability to deform it, significant tensile stresses develop in the film element, which under certain conditions lead to rupture of the film ( as a rule, in places where welds are installed) with a violation of the antifiltration properties of the screen [7]. Similar screen disturbances are possible with uneven precipitation and subsidence of the base.

To eliminate this drawback, a technical solution has been developed for the construction of a film screen with compensators for screen deformations (developing during temperature changes or subsidence), providing unloading of welds and screen panels from tensile stresses ([2], Section 3.21, Fig. 5).

The disadvantage of this solution is the device of the compensator in the form of a fold. In working condition, the fold of the plastic film is clamped under the pressure of the protective layer, its disclosure is almost impossible, since:

- the coefficient of friction of the film on the film is greater than the film on the ground ([1], Appendix 4);

- maximum tensile stresses, to compensate for which the opening of the fold is required, develop at temperatures below minus 30 ° C;

the geomembrane material to a large extent loses its elasticity, as a result of which any movement of the compressed fold can lead to destruction of the film in the compensator.

Other technical solutions have similar disadvantages, which are based on the idea of using folded-type compensators, for example [3].

The closest technical solution is the device of a film antifiltration screen equipped with expansion joints in the form of butt joints of the panels of the film screen with overlapping strips of material different from the geomembrane material [4].

The disadvantages of this solution:

- provides for the fastening of the panels between themselves by attaching to them a strip that overlaps the gap at the top at the junction of the panels; as a result, the ability to move the connected panels relative to each other is significantly limited to prevent the development of tensile stresses in them, the efficiency of the compensator decreases;

- it is assumed that the film element (geomembrane) glides over the surface of the strip that covers the gap at the junction of the panels from below, due to the coating of this strip with an antifriction compound, which at low temperatures, when it is necessary to slide one material over another, loses its antifriction properties due to solidification.

As a result, there may be a violation of the tightness of the compensator and the waterproofness of the screen.

The technical result of the invention is to provide the necessary mobility of the compensator without damaging the film impervious element (geomembrane) and while maintaining its tightness.

This is achieved by the fact that in the method of creating an anti-filter screen with a geomembrane from a polymeric material, including preparing a soil base, laying a waterproof geomembrane on it, which consists of hermetically connected panels of polymeric material, a device for compensating geomembrane deformations with a butt joint of panels in the places of expansion joints and overlapping joints at the bottom and top with strips of material different from the material of the geomembrane, the device of the protective layer of the screen, per units laying polymeric material panels on the prepared soil base determine the location of the geomembrane deformation expansion joints, in which they then lay the polymeric material panels butt without fastening the panels together, while on the surface of the soil base under each joint a protective-insulating cover made of impermeable material is pre-laid on top of it is laid with an antifriction gasket made of a material whose friction coefficient on the geomembrane material is lower than the coefficient The friction material of the geomembrane on a ground base, followed by the same anti-friction gasket is placed over the joint and its top is covered with a protective-insulating lining of impermeable material.

Distances between strain compensators are prescribed from the condition L≤50 · δ ^0.5 , m; where δ is the thickness of the geomembrane of polymeric materials, mm The lower and upper protective insulating pads are performed without attaching to the geomembrane panels. The width of the lower and upper antifriction gaskets in the direction perpendicular to the joint is taken at least B = 3 · b, mm; where b is the maximum width of the joint, mm

The width of the lower and upper protective insulating pads in the direction perpendicular to the joint is determined by the calculation according to the formula A = B + 2 · a, mm; where a is the optimal amount of overlap on the geomembrane, mm. The optimal inflow of the lower and upper protective-insulating plates on the geomembrane is calculated by the formula α = 100 · δ, mm

Antifriction pads are made of non-woven geosynthetic materials - geotextiles, or from rolled geosynthetic antifiltration materials based on bentonite clays with a frame of woven and non-woven geosynthetic materials - geotextiles.

The proposed method of creating an anti-filter screen is illustrated by drawings, where Fig. 1 shows a fragment of a plan of an anti-filter screen; figure 2 is a sectional view of the screen at the installation site of the compensator (the initial position at the end of installation); figure 3 is a cross section of the compensator in the working position during deformation of the geomembrane.

The numbers in the drawings indicate: 1 - panels of geomembrane made of polymeric material; 2 - connection of panels with fastening edges by welding or gluing; 3 - compensators for deformations of the geomembrane; 4, 5 - lower and upper anti-friction pads; 6, 7 - lower and upper protective insulating pads; 8 - prepared soil base (underlying layer) of the screen; 9 - a protective layer of the screen from soil or other materials; 10 - waste or effluent; 11 - a gap at the junction of the panels corresponding to the deformation of the geomembrane; 12 - gaps between the geomembrane and protective insulating pads; 13 - filling the gaps when used for anti-friction laying of roll anti-filtration materials based on bentonite clay.

Letter designations: L - distance between compensators; F - tensile force in the geomembrane in the absence of a compensator; δ is the thickness of the geomembrane; b - opening of the joint (gap) of adjacent panels of the geomembrane corresponding to the maximum design strain of the geomembrane; A is the width of the protective insulating lining; B is the width of the anti-friction pad; and - the broadening (in one direction) of the protective insulating lining relative to the antifriction gasket.

The anti-filter screen is created as follows.

On the prepared soil base (underlying layer) 8 lay the panels 1 of the geomembrane of a polymeric material, such as a plastic film. The geomembrane sheets are interconnected to ensure the tightness of the joints 2, for example, by welding or gluing the edges of the panels, then they are covered with a protective layer 9 of soil or other materials that protect the geomembrane from damage by building mechanisms (during construction) or by substances contained in those placed above the screen in the operation of waste or effluent 10.

Some of the connections of the geomembrane panels are made in the form of compensators 3, which provide the ability to move the edges of the panels relative to each other by the value of the expected deformations of the geomembrane to prevent excessive tensile stresses in it from the effects of adverse factors, for example, a significant decrease in temperature. In this case, the laying of adjacent panels of the polymeric material of the geomembrane in the place of the compensator is performed end-to-end without fastening the panels together.

Preliminarily, on the surface of the prepared soil base 8, a protective insulating pad 6 made of impermeable (for example, polymer) material is laid under the joint, on top of which an antifriction gasket 4 of material is laid, the coefficient of friction of which on the material of geomembrane 1 is lower than the coefficient of friction of the material of the geomembrane on the soil of the base 8, then the same anti-friction gasket 5 is laid over the joint and covered with a protective-insulating lining 7 of impermeable material from above, for example, similar material of the lower protective insulating lining 6.

According to the results of the analysis of the damage to film screens under the influence of temperature stresses with a decrease in the operating temperature relative to the mounting temperature of the screen by 60-70 ° [7], it was found that the distance between the expansion joints L (m) should not exceed L = 50 · δ ^0.5 , where δ is the thickness of the geomembrane of polymeric materials, mm

The design of the compensator should provide good mobility of adjacent panels of the geomembrane relative to each other and at the same time, the tightness of the joint between the panels, including in the case of opening the joint with the formation of a gap during the development of temperature deformations or subsidence of the base.

Sealing the butt joint is performed according to the principle of labyrinth sealing. To this end:

- the width of the anti-friction linings in the direction perpendicular to the joint is assigned B≥3 · b from the condition of guaranteed overlap of the joint at its maximum opening (for example, for polyethylene sheets with a thickness of d = 2 mm, the step of installing compensators should be L≤71 m, while the maximum opening of the joint may make b = 0.11 m);

- protective insulating pads are made of impermeable material with a width of A = B + 2 · a, where a is the broadening (in one direction) of the protective insulating pads relative to the antifriction gasket. Filling the edge of the patch on the geomembrane material in the presence of significant vertical pressure ensures their tight contact and contributes to better waterproofing of the joint, but at the same time creates the effect of pinching the geomembrane and limits the mobility of the compensator. The optimal amount of inlet is calculated by the formula a = 100 · δ, obtained from the condition that the sum of the friction forces from the inlets of the upper and lower plates does not exceed 30% of the destructive force for the geomembrane material at a design temperature below minus 30 ° C.

For anti-friction linings, non-woven geosynthetics (geotextiles) are used, having a friction angle on the geomembrane material (for example, polyethylene with a smooth surface) of 6-12 ° [6], a friction coefficient of 0.1-0.2, while the angle of friction of soils on the material the membrane is 18 ° [6], the coefficient of friction is 0.3 [5].

If a particularly high tightness of the joint is required, a strip of rolled geosynthetic antifiltration material based on bentonite clay (Bentomat, Bentofix, etc.) in the form of powder or granules placed in a frame between two layers of geotextile is used as an antifriction gasket. When the bentonite aggregate is soaked, it is extruded through the open edges of the gasket into the gap 12 between the protective-insulating pad and the geomembrane, creating practically impermeable seals 13.

The use of strain compensators for geomembranes made of polymer materials provides:

- the ability to create impervious screens with geomembranes from polymeric materials of any size;

- compensation of the maximum possible deformation of the geomembrane from adverse effects, such as temperature fluctuations, without the risk of destruction of the geomembrane by excessive tensile stresses and without violating the tightness of the screen.

These advantages allow you to significantly expand the scope of impervious screens with geomembranes made of polymer materials.

Information sources

1. SP 551-82. Instructions for the design and construction of anti-filtration devices made of plastic film for artificial ponds. M .: Stroyizdat, 1983. (Analog 1).

2. Guidelines for the use of soil-film screens in earthworks of irrigation systems. USSR Ministry of Agriculture and Water Resources, Moscow: 1979. (Clause 3.21, Fig. 5 - Analog 2).

3. AC No. 1518439 SU. A method of creating a screen on subsidence soils (Analog 3).

4. AC No. 810877 SU. Butt joint (Prototype).

5. Film antifiltration devices of hydraulic structures. Ed. I.E. Krichevsky. M .: Energy, 1976.

6. Landfill Engineering. Information materials of NAUE FASERTECHNIK, Germany, 2001.

7. Vostretsov S.P. Damage assessment of film screens. Collection of scientific articles, pp. 232-242. OJSC Galurgia, Perm, 2002.

Claims (8)

1. A method of creating an anti-filter screen with a geomembrane made of a polymeric material, including preparing a soil base, laying a waterproof geomembrane on it, consisting of seams of polymeric material hermetically connected to each other, a device for expansion joints of geomembrane deformations with a butt joint of the panels in the places of expansion joints and overlapping joints from below and on top of the stripes of material different from the material of the geomembrane, the device of the protective layer of the screen, characterized in that before by laying the panels of polymeric materials on the prepared soil base, determine the location of the geomembrane deformation expansion joints, in which they then lay the panels of polymer materials end-to-end without fastening the panels together, while on the surface of the soil base under each joint a protective-insulating cover made of impermeable material is pre-laid on top of it stack an antifriction gasket made of a material whose friction coefficient on the geomembrane material is lower than the coefficient t eniya geomembrane material on a ground base, followed by the same anti-friction gasket is placed over the joint and its top is covered with a protective-insulating lining of impermeable material. 2. The method according to claim 1, characterized in that the distance between the expansion joints strain is prescribed from the condition
L≤50 · δ ^0.5 , m,
where δ is the thickness of the geomembrane of polymeric materials, mm 3. The method according to claim 1, characterized in that the lower and upper protective insulating pads are performed without attaching to the panels of the geomembrane. 4. The method according to claim 1, characterized in that the width of the lower and upper anti-friction linings in the direction perpendicular to the joint is taken at least
B = 3 · b, mm
where b is the maximum width of the joint, mm 5. The method according to claim 1, characterized in that the width of the lower and upper protective insulating pads in the direction perpendicular to the joint is determined by the calculation according to the formula
A = B + 2 · a, mm,
where a is the optimal amount of overlap on the geomembrane, mm. 6. The method according to claim 1, characterized in that the optimal amount of inflow of the lower and upper protective insulating pads on the geomembrane is calculated by the formula
a = 100 · δ, mm. 7. The method according to claim 1, characterized in that the antifriction pads are made of non-woven geosynthetic materials - geotextiles. 8. The method according to claim 1, characterized in that the antifriction pads are made of roll geosynthetic antifiltration materials based on bentonite clays with a frame of woven and non-woven geosynthetic materials - geotextiles.

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