BG110093A - Waterproofing bentonite membrane - Google Patents

Abstract

The membrane can be used in construction for waterproofing of underground parts of buildings and underground facilities, such as tunnels etc., of landfills for industrial and domestic waste as an antifiltration screen, of basins and repositories for hazardous and toxic materials, and of tanks for petroleum products. It helps improve the waterproofing of construction sites and extend their lifetime. This is achieved by making a three-layer membrane consisting of two outer textile layers and an intermediate bentonite layer, the three layers being placed and reinforced in a dry state. The bentonite layer consists of a dry mixture of granular sodium bentonite cleansed of impurities and modified additives that improve the bentonite structure and decrease the filtration losses.

Description

WATERPROOFING bentonite MEMBRANE*

FIELD OF ENGINEERING

The present invention relates to a waterproofing bentonite membrane intended for use in the field of construction and in particular for waterproofing horizontal and vertical surfaces of buildings and various facilities, underground parts of buildings and underground facilities such as tunnels and others, landfills for industrial and household waste in order to protect the soil and the environment from pollution, i.e. as an anti-filtration screen, on pools and storages for harmful and toxic materials and on tanks for petroleum products.

PRIOR ART

A characteristic feature of waterproofing with the above purpose is that they are constantly exposed to water, which is why they are subject to high water resistance requirements. According to the literature [1], the content of water-soluble components in the materials used for waterproofing should not exceed 0.3%. Often, however, the waters are aggressive, such as mineralized soil waters, industrial waters and petroleum products, which limits the application of certain types of waterproofing, for example those based on polymer and bitumen.

The most promising for the above applications are waterproofing products based on bentonite.

Bentonite is a clay composed of the mineral smectite, which is a three-layered mineral ie composed of tetrahedral-octahedral-tetrahedral silicate layers. When smectite is composed of an octahedral aluminum layer sandwiched between two tetrahedral silicon layers, the mineral is montmorillonite. A particle of the order of 0.1 mm in size contains 100,000 planes oriented in different directions. The water that is included in the bentonite clay is between these plates.

Smectites exhibit exceptional cation exchange or substitution in the crystal lattice. The isomorphic replacement of one or more elements (silicon or aluminum) with others of lower ionic charge (potassium, magnesium, iron) in smectite leads to a negative charge in the crystal, which is balanced by other cations weakly held between the silicon layers. - the aluminum packages in the structure. These interlayer cations are readily exchangeable.

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The isomorphism can be in the tetrahedron. In both cases, the resulting negative charge is compensated by exchange cations, but the binding energy of the exchange cation to the surface is different. When substituted in the octahedral position, the exchange ions are very mobile. In an aqueous medium, the ions cause hydration of the surface, which leads to very good swelling.

The combination of two tetrahedral and one octahedral layer inserted between them is repeated many times and forms layered packages interconnected with the exchangeable ions Na+, Ca2+, Mg2+, K+ and water. In contact with water, sodium bentonite clay hydrates and greatly increases its volume, and when this process takes place in a closed space, tension arises in the structure of the gel that forms, which greatly reduces the water permeability of the material /filtration coefficient/.

Due to its hydroscopic properties, its ability to swell and form a dense layer, bentonite is widely used in waterproofing products.

Two types of waterproofing bentonite membranes are known:

- from granular bentonite with double-sided needle punched textile materials and/or foil; and

- from pre-hydrated and pressed bentonite with textile and/or foil materials glued on both sides.

The membrane according to the invention belongs to the first type of waterproofing bentonite membranes that use granular bentonite.

Granular bentonite waterproofing membranes typically include a flexible carrier layer, a bentonite interlayer, and a cover layer. The supporting layer is a pile material and the covering layer is a mesh. The bentonite interlayer and the cover layer are bonded by means of an adhesive.

A disadvantage of this type of waterproofing bentonite membranes is that the use of an adhesive hardens the individual layers and when bending the membrane, as a result of unevenness of the terrain on which it is laid, the bentonite intermediate layer cracks, making the membrane water-permeable.

Other bentonite waterproofing membranes are known which use liquid polymers for the carrier and cover layers and a pourable bentonite raw material for the intermediate layer. A disadvantage of these membranes is the complexity of the technological process for the manufacture of the membrane, which requires a drying process and a further processing process of the bentonite raw material.

• ·· · · · ·« _is

The task of the invention is to remove *rtoCQ4 ^e 4 ^Ha J drawback «to create a waterproofing bentonite membrane with guaranteed water permeability and a simplified technology for its production.

TECHNICAL ESSENCE OF THE INVENTION

The task was solved by a waterproofing bentonite membrane consisting of an outer supporting layer, an intermediate bentonite layer and an outer covering layer connected by reinforcement, which is characterized by the fact that the three layers are in a dry state during the production process of the membrane.

The membrane is also characterized by the fact that the outer supporting layer is composed of a dry woven polypropylene geotextile with a mass per unit area min 100 g/m, the outer covering layer is composed of a dry non-woven polypropylene or polyester geotextile with a mass per unit area min 200 g/ m ² and the intermediate bentonite layer is composed of a dry mixture between granulated and purified sodium bentonite and modifying additives improving the structure of the bentonite and reducing filtration losses, the dry mixture and the outer supporting layer of woven textile being stitched with threads of the outer covering layer of non-woven fabric so that they protrude beyond the outer support layer.

The membrane is also characterized by the fact that the sodium bentonite has a low content of impurities of quartz, calcite and aragonite, mica and feldspars, with min 85% content of montmorillonite, with a high content of exchangeable sodium, with min 300 mg/g sorption of metallic blau, with max 18ml filtration losses and min 20ml/2g degree of swelling.

The sodium bentonite has a grain size of 2.0 to 0.20 mm, the geotextiles have a constant mass per unit area and a constant width, preferably 118 cm, and the sodium bentonite content is preferably 4.50 kg/m .

The sodium bentonite and modifiers are mixed in a dry mix mixer, the content being metered just prior to placing the dry interlayer.

An advantage of the waterproofing bentonite membrane is its low water permeability, the possibility of laying in all weather conditions, simple and easy installation without gluing and welding, the ability to self-repair in case of injury due to the constant pressure during swelling, which in turn favors the use of grooves and pegs and placing reinforcement directly on the membrane, • ·· · · · · f durability of an unlimited number of cycles _is ii! Bleeding and swelling, hydration and dehydration, does not wear out even under normal operating conditions of the construction site, the service life of the membrane is commensurate with that of the construction site itself.

EXAMPLES OF IMPLEMENTATION OF THE INVENTION

The waterproofing bentonite membrane, according to the invention, consists of dry granular bentonite clay, located between two layers of geotextile woven polypropylene and non-woven polypropylene or polyester textile. During the production of the membrane, a certain amount of threads from the non-woven textile are pushed through the bentonite layer and exit through the woven textile, which on the one hand reinforces the materials, and on the other, provides good adhesion to the concrete. Stitching or so-called "needling" provides an even distribution of the bentonite granules between the two textile layers, which provide the mechanical strength of the waterproofing membrane and guarantee the retention of the bentonite.

Sodium bentonite is the main component of the waterproofing bentonite membrane according to the invention. As its swelling effect is affected by the type of liquid with which the membrane comes into contact during its use, various additives are applied to sodium bentonite to ensure good filtration and for liquids that reduce the swelling effect.

The waterproofing bentonite membrane, according to the invention, is a ready-to-install dry flexible, cross-stitched membrane consisting of three layers: a middle layer, an outer supporting layer and an outer covering layer.

The middle layer is a dry mixture of granulated and purified sodium bentonite with a grain size of 2.0 to 0.20 mm and modifying additives to improve its structure and reduce filtration losses. The sodium bentonite used is of high purity and low in impurities of quartz, calcite and aragonite, micas and feldspars, high in montmorillonite, high in exchangeable sodium and meets the following requirements:

- sorption of metal blue min 300mg/g or

- montmorillonite content min 85%

- filtration losses max 18ml degree of swelling min 20 ml/2g

The bentonite and various additives are mixed in a dry mix mixer.

-5 The outer carrier layer is a polypropylene textile and preferably a woven polypropylene textile with a weight per unit weight min 100 g/m preferably of Trace Plastics CO, Greece.

The outer covering layer is a non-woven polyester textile with a mass per unit area min 200 g/m ² , such as ISOTEX ECO 18, Geomat 200T and Geofilts. Preferably, as a non-woven geotextile, the polyester textile "Geomat 200T" with a width of 118 cm, produced by the company "Nove Tex" AD Sofia and "Izotex Eno" produced by the company "Arbanasi" AD, V. Tarnovo, is used.

The main requirements for geotextiles are constant mass per unit area and constant width.

In appearance, bentonite waterproofing membrane is a roll-wound flexible three-layer cross-stitched membrane with a dark gray to black color on the woven textile side and a light gray to white color on the nonwoven textile side. Preferably the rolls have a length of the order of 5 ± 0.05 t, a width of the order of 1.15 ± 0.05 t, a thickness (on dry product) of 6 ± 1 mm at 2 kPa, an average weight per roll of 27.00 kg and bentonite content 4.50 kg/m .

The physical properties of the waterproofing membrane according to the invention are as follows:

- mass /weight/ per unit area < 5000 g/m;

- bentonite content <4500 g/m ² /Example 2/;

- resistance to hydrostatic pressure >500 mm, maximum 70 m P atm/;

- adhesion to a fresh concrete surface > 1.20 - 2.6 kN/m /Example 1/;

- tensile strength: longitudinal > 6000 N/m and transverse > 4800 N/m;

- limit strain at break: longitudinal > 90% and transverse > 80%;

- tensile strength > 450 - 570N;

- static puncture resistance > 3000 N;

- dynamic puncture resistance < 25;

- bendability around a mandrel with and 30 mm at low temperatures of the order of -25 30°C without cracks; and

- filtration coefficient /water permeability/ <5x10' m/s, maximum 1x10' ^H m/s.

Example 1. Determination of the adhesion of the waterproofing bentonite membrane, according to the invention, to a fresh concrete surface.

From randomly selected rolls, 5 test pieces were cut at a distance of 100 cm

- 6 from the transverse end of the roll and 15 cm from _> the top of the jcpaiL Professional bodies were of transverse dimensions 40/160 mm. 5 metal formwork forms with a prismatic shape were also prepared for the preparation of prismatic trial forms from a cement-sand solution with a mass ratio of cement/sand equal to 1/2 and a water-cement water/cement ratio equal to 0.50.

To carry out the tests, portlancement SEMP with compressive strength class 42.5 and standard trifraction normal sand is used.

A test body cut from the waterproofing bentovite membrane was placed on the bottom of each mold so that the woven textile was in contact with the cement-sand solution. On the test body, at one end of the mold, a sheet of polyethylene film with transverse dimensions of 40/100 mm was placed, so as to prevent the cement-sand solution from sticking to part of the membrane.

The ready-made cement-sand solution was laid on the thus prepared form of the layer. Each layer was compacted on a vibrating table with 60 shakes for 60 seconds. The finished specimens were aged in the molds for 24 hours, after which the molds were disassembled and the specimens were stored at a relative air humidity of 65±5% and an air temperature of 20±2°C for 6 days.

Before starting the test, the free end of the membrane bordering the polyethylene film was turned 180° by gripping jaws, and a metal tip was glued to the opposite end of the prismatic specimen to perform the tensile test. The metal tip is bonded with epoxy resin.

The test was carried out with a loading speed of 50 mm/min, and the loading continued until the membrane was completely separated from the base /hardened solution/.

As a result of the test, the maximum value of the tensile force F per unit width of (40mm) of the specimen (N/40mm) is registered. The final result is the arithmetic mean value of the test of the five test specimens Fm. The obtained result was translated for a length of 1 meter of the membrane according to the formula Fs=Fm/0.04, kN/m.

Example 2. Determination of the content of bentonite in the waterproofing membrane, according to the invention

The test was carried out with 5 test bodies from the waterproofing bentonite

-7 • · >

membrane with dimensions 100 x 100 x 6 mm. In parallel, 5 identical samples of the woven and non-woven textiles were prepared, with dimensions of 100 x 100 mm. The test bodies and identical textile samples were placed in a humid chamber at a temperature of 23±2°C and a constant humidity of 65±5%, where they remained for 24 hours.

After removal from the wet chamber, the average value of the mass of the membrane and the textile was determined according to formulas (1) and (2), in which Mi,k and Mi,sk are the unit results, as well as the areal mass of the samples according to formulas (3) and (4), where A is the area of the test specimens [t ² ]:

M _K =EM _i>k /5,[g](1)

M _S , _K =Z Mi. _sk /5, [g](2)

Mk = Mk / A [g/m2](3)

Ms,k - Ms,k / A [g/m2](4)

The test bodies were dried at a temperature of 105 ± 5°C for 2 hours ± 10 min and after cooling were weighed:

© M _o =Σ Mj, ₀ /5,[g](5)

M _Sj0 ~X Mi _iS0 /5, [g](6)

The surface masses after drying of the membrane and the textile were also calculated according to formulas (7) (8):

m ₀ =M ₀ / A [g/m ² ](7) m _S;0 -M _s , ₀ /A [g/m ² ](8) where M _o and M _s , ₀ are the average values from equation ( 5) and (6), and A is the average value of the area of the samples.

-8- .,

The bentonite content is determined by the values (9J and a/ after 24 hours of conditioning at 23±2°C and 65±5% relative humidity:

т _b ,k = ш _k - m _s , _k , [g/m ² ] (9) b/ after drying:

sht b,o = Sho - m _s .o, [g/m ² ] (10) where: Shk and m _s ,k are the values from formulas (3) and (4), and t ₀ and m _s>0 respectively from formulas (7) and (8).

Final results were rounded to the nearest whole number.

The waterproofing bentonite membranes, according to the invention, are combustible, but not explosive and do not require special additional measures for fire safety during installation. In the process of installation and during the operation of the waterproofing bentonite membranes, no substances harmful to the environment and hazardous to health are released.

In the structure of the general construction system of the buildings and facilities, the membranes are usually placed under the foundations and on the outside of the enclosing walls of the underground parts without direct access to the open spaces and rooms.

The waterproofing bentonite membrane is produced on a technological line ensuring the following automated operations are carried out sequentially:

- dosage of the components;

- dry mixing of bentonite with additives;

- centering the textiles;

- transportation and laying of the dry bentonite mixture;

- needlework /quilting/;

- measuring, winding, weighing and labeling the roll;

- arranging the roll in pallets and banding and foiling the pallets.

The bentonite handling area is equipped with a local suction system.

The foiled pallets are stored in closed rooms, protected from moisture, at a temperature of up to 40°C. If the hermeticity of the package is broken or if individual rolls or parts of a roll are partially used, the remainder is moisture-insulated again. The transportation of the foiled pallets is carried out with closed means of transport, taking precautions against mechanical damage during loading and unloading, as well as for safe transportation.

-9 USE OF THE WATERPROOFING ^[EMBCANA

A. When waterproofing underground horizontal surfaces

In the case of the presence of underground water at the site of the construction site, first of all, the trench /pit/ with stable and reinforced walls is drained, after which the ground is leveled and compacted. Sheets of waterproofing bentonite membrane are laid on a dry earth base, or on a concrete pad or concrete slab. When laying, the membrane sheets are stretched so that no folds are formed and tight adhesion to the base surface is achieved. The woven textile of the membrane remains on the upper side, for example on the side of a freshly laid concrete.

The sheets of waterproofing bentonite membrane are laid with an overlap of at least 15-20 cm, and the places where they are joined are covered with a binding material, such as "Isofix", which ensures the waterproofness of the connection. Directly on the waterproofing bentonite membrane, according to the invention, reinforcement is applied using pads, limiters, fasteners, etc., but in all cases direct contact of sharp metal parts with the membrane sheets is avoided.

In the case of areas damaged during installation, they are sealed by sprinkling a bonding material in the place of the tear, covered with a piece of the membrane with a size equal to twice the area of the damaged area.

B and C pipes and electrical installations are waterproofed by banding with an insulating material, for example "Balkanit", in the area of the concrete slab, and/or by a secondary collar /ring/ of the membrane covering the outlet of the pipe, under which the bonding material is sprinkled .

The waterproofing bentonite membrane, according to the invention, is laid so that it protrudes beyond the outline of the main plane for connection with the vertical waterproofing of the external walls, of the order of min 40-50 cm.

B. In case of waterproofing of underground external walls of buildings a/ In the process of building the walls

The exterior wall formwork is installed, centered and braced in place in preparation for concreting the base slab. A first row of membrane sheets is attached to it, reaching the main plane, overlapping at the places of the outer corners by about 15 to 20 cm. The parts of the membrane sheets that protrude beyond the outline of the bases are turned up and firmly attached to the lower part

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on the vertically laid sheets of membrane, *6; the upper _layer of the first row, the membrane sheets remain free, i.e. not attached to the formwork, 15 to 20 cm for overlap with the next row of membrane sheets. In the second and each subsequent row, the lower part /15 to 20 cm/ of the membrane sheets overlaps from the outside the upper /free/ part of the membrane sheets of the previous row, ensuring tight attachment to the formwork and in the place of joining of the two membrane sheets .

During concreting, as well as during the subsequent laying of the reverse embankment on the outside, the joints of the membrane sheets must not be contaminated.

b/ Laying the membrane sheets on old walls and surfaces

Laying is carried out on naturally dry, aligned and dust-free vertical walls, in close contact with the concrete surface. The membranes are stretched well, and the non-woven geotextile is placed on the side of the water head.

The membrane sheets are fixed to the concrete wall by nailing with nails, through wooden slats, metal or plastic rails, or suitable washers, and the height of the waterproofing surface is min 50 cm. above the upper level of the soil water, or to the ground level. The overlapping of individual sheets of waterproofing membrane in horizontal and vertical direction is min 15-20 cm.

The reverse embankment /soil covering of the external surfaces/ is performed after removing the external formwork and visually checking the fastening of the waterproofing membrane sheets to the concrete surface, as well as the tightness of the joints. If necessary, additional overlap is applied. Ensure that the soil cover does not contain sharp stones, glass pieces, etc. hard materials that would damage the membrane sheets installed in this way, and not to contaminate the splices.

The sheets of waterproofing membrane are covered no later than one day after removing the formwork and processing the joints.

C. When building landfills for industrial and/or domestic waste

The basic rules for laying the sheets of waterproofing membrane, referring to the preparation of the ground base, overlap of the sheets, sealing of the joints, fastening of local breaks, etc. are also valid for this type of use. The main requirement for this type of use is to provide the necessary limiting conditions for hydration of the bentonite layer in

-11-,.. , _e · · · · · · * ·· · the presence of water environment. · · * * ·. ; · * ··*'.

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REFERENCES

[1 ] Elena Demireva "UNDERGROUND WATER ISOLATION", Yearbook of the Ministry of Geology "St. Ivan Rilski", Volume 49, Vol. P, Extraction and Processing of Mineral Raw Materials, 2008

Claims (7)

1. A waterproofing bentonite membrane consisting of an outer bearing layer, an intermediate bentonite layer and an outer covering layer connected by reinforcement, characterized in that in the production process of the membrane the three layers are in a dry state. 2. Membrane according to claim 1, characterized in that the outer supporting layer is composed of a dry woven polypropylene geotextile with a mass per unit area η min 100 g/m , the outer covering layer is composed of a dry non-woven polypropylene or polyester geotextile with a mass per unit area min 200 g/m and the intermediate bentonite layer is composed of a dry mixture between dry granulated and decontaminated sodium bentonite and dry, improving the bentonite structure and reducing filtration loss modifying additives, such as the dry mixture and the outer supporting layer of woven textile are stitched with threads from the outer cover layer of non-woven fabric so that they protrude beyond the outer support layer. 3. Membrane according to claim 2, characterized in that the sodium bentonite is low in impurities of quartz, calcite and aragonite, mica and feldspars, with a min 85% content of montmorillonite, with a high content of exchangeable sodium, with a min 300 mg/g sorption of methylene blue, with max 18ml filtration losses and min 20ml/2g degree of swelling. 4. Membrane according to claims 1 to 3, characterized in that the sodium bentonite has a grain size of 2.0 to 0.20 mm. 5. A membrane according to claim 2, characterized in that the geotextiles have a constant mass per unit area and a constant width, preferably 118 cm. 6. Membrane according to claims 1 to 5, characterized in that the content of sodium bentonite is preferably 4.50 kg/m . 7. Membrane according to claims 1 to 6, characterized in that the mixing of the sodium bentonite and the modifying additives takes place in a mixer for dry mixing immediately before laying the dry intermediate layer.