CS258351B1 - Sealing underground wall of self-curing suspension and vertical insulation layers and process of its production - Google Patents

Abstract

The purpose of the invention is to reduce the permeability and extend the functionality of the sealing underground wall regardless of the type and degree of chemical pollution of the groundwater. The walls also provide protection against the penetration of gaseous substances. A high sealing effect is achieved by creating an underground wall from a self-hardening suspension without working joints and by inserting continuous insulating layers of foils and a thin-walled metal core provided with insulating coatings.

Description

The invention relates to the construction of a sealing underground wall consisting of a self-curing suspension, vertical insulating layers and a process for its production. The construction and production process of the sealing underground wall falls within the field of foundation engineering.

The sealing underground wall of the self-curing suspension and the vertical insulating layers is composed of continuous layers of foil, a continuous thin-walled metal core with insulating coatings and of the cured self-curing suspension. The cured self-curing suspension is located between the continuous insulation layers and the groove walls. Individual foil strips and waterproof metal blocks are connected to continuous insulating layers by overlapping or continuous end caps - locks.

The sealing underground wall may also consist only of a continuous thin-walled core with insulating coatings surrounded by a cured self-hardening suspension. Thin-walled metal core with insulating coatings can be replaced by several continuous foil layers. The overlaps and end caps of adjacent vertical insulation layers are offset from one another.

The grooves are cut in a continuous manner under protection of the self-curing suspension. Before the self-setting suspension begins to solidify, the individual foil pieces and the waterproof steel core blocks are successively embossed to the already built-in parts of the insulating layers so that they partially overlap or the closing portions of the vertical continuous shutters of the insulating layers are inserted into the projections of the already built-in parts. The closures can also be made by inserting the projections into the closing portions. The sealing portions are filled with sealing compound prior to installation in the groove.

Known are constructions of sealing underground walls where the sealant is clay soil, clay with added sand, rotten lump clay in suspension, concrete cement, another mixture of sand, and asbestos fibers and cement. Also known are mixtures of sand, limestone powder - fifiler and asphalt. Known include a cured, self-curing suspension consisting of bentonite, hydraulic masses, stabilizers, plasticizing retardants and water. The sealant may also be a self-hardening suspension with gravel and optionally sand.

Membrane sealing walls are known to be formed from an injectable composition composed of cement, flu and water. Thin-walled underground walls are also known, where bitumens are the principal component of the mixture.

Known processes include the production of sealing underground walls in an unveneered groove or sheeting by means of depositing and compacting in layers of treated or untreated soils.

The compacted underground wall of compacted lump clay is produced by laying the lump clay in layers in a groove filled with a clay slurry. Homogenization of each layer is carried out with a kneading device.

Sealants in liquid or plastic state e.g. a mixture of clay, cement, gravel, water and plasticizing-retarding agents, another mixture of water glass with other substances are laid in a groove with a clay suspension by means of an inlet pipe alternately on slats - short sections. Before placing the sealant, steel casings are placed in the ends of the odd blades, which are removed after the sealant has partially cured. Even planks are built after removal of adjacent casing. Steel casing can be replaced by prefabricated elements which are not removed from the groove.

Sealing underground walls of the cured self-curing suspension are made by casting the self-curing suspension into a groove that deepens and elongates usually by a continuous process.

The diaphragm sealing underground walls are produced by injecting sealing injection materials into the soil through an injection tube mounted on a steel profile while pulling it out.

The permeability of the sealing walls is a function not only of the properties of the sealant but also of the way in which they are incorporated. The horizontal and vertical gaps resulting from these workflows are potentially places of increased leakage.

Chemically contaminated waters may have a particularly negative effect on the long-term sealing function of sealing underground walls.

These drawbacks are overcome by the construction and manufacturing process of the sealing wall according to the invention in that the hardened self-hardening suspension has no working joints, the wall as a whole has less permeability and has an extended sealing function even in chemically contaminated environments due to the installation of vertical insulating layers.

The higher effect of the wall is not only in reducing the permeability and prolonging the functionality, but also in its simplicity of execution. This implies an economic benefit and an increase in the long-term quality of the wall as a whole. The economic benefits are manifested in the reduction of costs, in the shortening of the retirement time and in the prolongation of the service life also in the chemically polluted environment.

Examples of constructions and processes for the production of sealing underground walls from a self-curing suspension and vertical insulating layers are schematically shown in the accompanying drawings.

Fig. 1 shows a plan view of a part of a sealing underground wall consisting of two continuous layers of foils, a continuous thin-walled metal core with double-sided insulating coatings and a cured self-curing suspension. The continuous layers of foils are located at both edges of the wall. Individual foil strips are connected by vertical end caps - locks. The metal core is made of sheet piles connected into blocks. The self-curing suspension surrounds the individual insulation layers.

Fig. 2 shows a plan view of a sealing wall. The continuity of the film layers is ensured by vertical end caps which are attached to the individual film strips. The metal core is formed of blocks consisting of corrugated sheet welded to sheet piling.

Fig. 3 is a sectional plan view of a wall. The wall construction difference in FIG.

opposite to the wall shown in FIG. 1 is in a metal core construction which is made of corrugated sheet bonded in a groove by vertical locks of rolled profiles.

Fig. 4 shows a plan view of a sealing underground wall formed from two continuous insulation layers of films and a cured self-curing suspension. The connection of the individual foil strips is similar to that of FIG. Second

Fig. 5 shows a plan view of a sealing underground wall made of 3 continuous layers of foils and a cured self-curing suspension. Individual foil strips are connected by vertical locks. The locks of adjacent foil strips are offset from one another.

Fig. 6 shows a plan view of a sealing underground wall that differs from the wall shown in FIG. 5 by having up to 4 continuous layers of films.

Fig. 7 is a plan view of a section of a sealing underground wall made of a self-curing suspension and two foil insulating layers. The continuity of the individual layers of films is ensured by overlapping which is displaced between adjacent layers.

Fig. 8 shows a plan view of a wall formed from 2 continuous sheet insulation layers, a thin-walled metal core with double-sided insulating coatings, and a self-curing suspension. The continuity of the film layers is formed by overlapping the film strips and the metal core by overlapping the individual metal blocks.

Fig. 9 shows a number of cross-sections through foil strips having different longitudinal closure shapes on both sides. The closures are additionally attached to the foil strips or are made simultaneously with the foil.

Fig. 10 shows several examples of cross-sections through waterproof metal blocks.

The blocks are formed from rolled or pressed metal profiles. After welding the individual parts, the metal blocks are provided with double-sided insulating coatings.

In FIG. 11 is an example of using a sealing underground wall to insulate an industrial waste dump. The figure shows a cross-section of the landfill edge. The bottom wall sealing wall is embedded in an impermeable clay subsoil. Double-sided layers of foils extend through the bottom edges into the groove, the thin-walled metal core is partially embedded under the bottom. The metal core with insulating coatings and foil layers are concreted into the outside of the terrain. Reinforced or non-reinforced bricks form the above-ground support structure of the stored waste and the upper sloping insulation layers.

In FIG. 12 shows a process for manufacturing a sealing underground wall from a self-curing suspension and vertical insulating layers in plan sections. Fig. and shows a groove section filled with a self-curing suspension; Fig. b insertion of two foil strips using an auxiliary construction and a new engagement (part of the groove) filled with a self-curing suspension. In FIG. c shows removing the auxiliary structure from the first pair of foil strips, inserting the first metal block and another pair of foil strips; Fig. d, e shows further removal of the auxiliary structure, insertion of metal blocks, foil strips and trench depression under protection of the self-curing suspension. The continuity of the insulation layers was formed by overlapping foil strips and metal blocks. The insertion of the foil strips, metal blocks and removal of the substructure is done before the solidification of the self-setting suspension begins to solidify.

In FIG. 13 shows another process for manufacturing a sealing underground wall from a self-curing suspension and vertical insulating layers in plan views. The difference in the process shown in FIG. 13 as opposed to FIG. 12 is that the individual foil strips are stacked side by side so that the portions of the closures are inserted into the portions of the closures already installed. After joining adjacent foil strips with a closure, the auxiliary structure is removed only from the foil strips built in.

The sealing underground wall of the self-hardening suspension and the vertical insulating layers consists of continuous layers of films 1, a continuous thin-walled metal core 2 with insulating coatings 3, of a cured self-hardening suspension j) which is located in the space between the continuous layers of 2 and the walls of the groove 5. Insulation layers can also consist only of film layers 1 or only thin-walled metal core 2 with insulating coatings 2. The individual foil strips Jj of continuous film layers 1 and waterproof metal blocks T of continuous thin-walled metal core 2 are connected by overlap 8 or The overlap j) or the closures 9 of adjacent insulating layers 2 are offset from one another.

In the production of the sealing underground wall, the groove is excavated in a continuous manner under the protection of the self-curing suspension 4 and, prior to the start of solidification, the individual foil strips 6 and the watertight metal blocks 7 are successively deposited into the groove 5. are connected by inserting one part of the closure j) into the other.

The placement of the individual film strips 6 is carried out using an auxiliary structure 11, which can be removed from the trench 5 after it has been overlapped with it or by a closure 9 from the film layers 11.

The invention can be used for the design and manufacture of sealing underground walls with long-term sealing function, regardless of the type and degree of chemical contamination of underground conduits as well as against the spread of gaseous substances.

Claims (4)

5 258351 SUBJECT OF THE INVENTION Sealing underground wall of self-curing suspension and vertical insulating layers characterized in that it consists of continuous layers of foils (1) and / or continuous thin-walled core (2) with insulating coatings (3) and cured self-curing suspension (4) in the space between continuous layers a sheet (1), a continuous steel core (2) and a sheet (5). Sealing underground wall according to claim 1, characterized in that the individual foil strips (6) of continuous layers of foils (1) and the watertight metal blocks (7) of the continuous thin-walled metal core (2) are connected by an overlap (8) and / or vertical end seals (9) with sealant (10), wherein the overlaps 18) and / or the closures (9) of adjacent insulating layers (1/2) are offset from one another. 3. A method of sealing a subterranean wall according to claim 1, characterized in that the individual foil strips and waterproof metal blocks are inserted into the groove in a continuous manner under the protection of the self-curing suspension and prior to its solidification, so as to partially overlap and / or overlap. or connect by inserting one portion of the closure into the other. 4. Production process according to claim 3, characterized in that the deposition of individual foil strips is carried out using an auxiliary structure. 8 drawings