RU2231603C1 - Method of building material and structure protection against moisture penetration - Google Patents

Abstract

FIELD: building industry, particularly for protection against moisture penetration, for drying and damp-proofing old building walls.

SUBSTANCE: method involves forming orifices in surface to be protected; installing electrodes in each second orifice, filling free orifices with mixture of hydrophobic liquid and 0.5 - 8% by weight of iron salt; applying potential in the range of 0.1 - 1.4 V with chequer-wise alternation of cathodes and electrodes over surface to be protected; drying building material or structure under the action of electric field which causes mass transfer of hydrophobic liquid particles and migration processes into hydrophobic liquid, wherein eletroosmosis process is intensified by adding iron salt to hydrophobic liquid due to generating iron hydroxide into alkaline medium of building materials, which muds material capillaries and porous for prolonged protection thereof against moisture penetration; applying magnetic field to protected surface so that with field lines of magnetic field are perpendicular to direction of migration flow in hydrophobic liquid. Optimal distance between electrodes is 20 - 50 sm.

EFFECT: increased intension, durability and quality of building material protection against moisture, improved impregnation uniformity and increased impregnation depth.

4 cl, 1 dwg

Description

The method relates to the field of construction, and more particularly to the water resistance of building structures and can be used to protect capillary-porous materials, products and structures from moisture, including for drying the walls of old buildings and protection from dampness.

Known methods of protecting building materials by naturally impregnating hydrophobic liquids with inorganic and organic compounds, for example, copyright certificate No. 1573016.

However, the disadvantage of this method is the low productivity and the inability to regulate the processing process. This is because the mass transfer of particles proceeds predominantly by the diffusion mechanism, and the quality of impregnation depends on the structural structure of the pore space, which is random in nature. Therefore, the directed movement of the hydrophobic protection particles is uncontrolled. Therefore, such methods do not provide high-quality protection against moisture.

Known methods of protecting building materials, products and structures from moisture using electrochemical methods (Express information, construction and architecture, consolidated volume, issue No. 3, M .: 2001, p. 22-23). To remove moisture and prevent the spread of dampness in the brick walls of operated buildings by a known method, techniques of electroosmosis are used. The essence of the method lies in the fact that a system of pins-electrodes is mounted in the wall, to which the potential is supplied from an electric current generator so that moisture mass transfer is carried out through the capillaries from top to bottom. Subsequently, excess liquid is captured and removed using special cartridges.

However, the disadvantage of this method is the possibility of only drying building materials, products or structures and the absence of their long-term protection against moisture when the electric current generator is turned off.

Closest to the claimed method, which is adopted as a prototype, is a method of isolating building structures from moisture exposure by ed. St. USSR No. 815193. This method includes making two rows of holes in the insulated wall of a building structure and installing electrodes in them, which are connected to a power source. After installing the electrodes in the holes, the same holes are filled with a hydrophobic liquid and at the same time they turn on the power supply (the top row - anodes, the bottom - cathodes). After the hydrophobic liquid reaches the electrodes of the lower row (cathodes), the power supply is turned off. To implement this method, hollow electrodes with holes in the walls for the passage of hydrophobic fluid are required. Under the influence of an electric field, the moisture in the capillaries and pores is drawn back, while at the same time drawing hydrophobic liquid into these capillaries and pores, thereby impregnating the treated area (insulated wall). The simultaneous use of electroosmosis and hydrophobic protection techniques improves, in comparison with previous analogues, the quality of isolation of processed structures from moisture.

However, the disadvantage of this method is the lack of additional long-term protection of products from moisture, the possibility of more volumetric impregnation of the product and insufficient intensification of the process over time.

The objective of the invention is to simultaneously provide intensive, long-term and high-quality protection of building materials, structures from moisture.

The problem is solved as follows.

By analogy with the operations of the known method on the treated area perform rows of holes in which the electrodes are installed. A hydrophobic liquid is used for impregnation; filled holes are filled with it. The potential is applied to the electrodes, creating a weak constant electric field. But according to the claimed method and in contrast to the well-known adopted for the prototype, in the hydrophobic liquid, before filling the holes with it, an iron salt (for example, iron nitrate) is additionally added in an amount of 0.5-8 wt.%, And the electrodes are installed through one hole at a distance 20-50 cm apart and when the potential is applied to the electrodes, the anodes and cathodes alternate in a checkerboard pattern on the treated area. As electrodes, elastic plates, for example, of foil, are used. A hydrophobic liquid is introduced into the missing holes between the electrodes. The difference is that in addition to the treated area is affected by a magnetic field. In this case, the lines of force are positioned so that they are perpendicular to the direction of the migration flow of hydrophobic fluid particles caused by the action of an electric field.

Thus, the claimed method differs from the prototype in that

- an iron salt in an amount of 0.5-8 wt.% is additionally introduced into the hydrophobic liquid;

- fill the holes between the electrodes with a hydrophobic liquid;

- the anodes and cathodes are staggered on the treated area;

- electrodes are placed at a distance from each other of 20-50 cm;

- elastic foil plates are used as electrodes;

- the treated area is exposed to a magnetic field;

- magnetic field lines are perpendicular to the direction of the migration flow of hydrophobic fluid particles.

The chemical addition of iron salt increases the conductivity of the hydrophobic liquid, and therefore contributes to the intensification of the process of electroosmosis. In addition, iron salts in an alkaline environment, which is characteristic of building materials, form iron (III) hydroxide that is practically insoluble in water (the solubility product of Fe (OH) ₃ is 10 ^-31 ), which leads to the clogging of the capillaries and pores of the material, and therefore , promotes long-term protection of the structure from moisture. The addition of iron salts in the range from 0.5 to 8 wt.%, Which enhances the protection of building materials and structures from moisture, was obtained experimentally.

The distance between the electrodes depends on the degree of flooding of the structure array, the concentration of ions in the solution, and the conductivity of the hydrophobic liquid.

As a result of the experiments, it was found that, on average, this distance is 20-50 cm. It is sufficient for intensive migration processes to occur under the influence of an electric current.

This arrangement of the electrodes (in a checkerboard pattern) on the treated area and the fact that the holes between the electrodes are filled with hydrophobic liquid contributes to the uniform flow of migration processes over the entire area of the building material or structure and better water protection.

The use of elastic plates increases the contact of the surface of the hole and the electrode, which increases the efficiency of the particle transfer process and reduces the amount of electricity consumption.

The use of a magnetic field, the lines of force of which are directed perpendicular to the direction of the migration flow of particles of a hydrophobic liquid, promotes the movement of particles different from the migration flow of ions, i.e. not only along the electric current line, but also to the volume of the structure being processed, and, therefore, to more fully filling it with a hydrophobic liquid.

Applicants and authors are not aware of electrochemical water protection methods by which the anodes and cathodes are staggered on the treated area. Methods of hydrophobic water protection with the addition of an iron salt in a hydrophobic liquid are also not known, moreover, within certain limits (0.5-8 wt.%), Which are established experimentally.

The unknown of these distinguishing features allows us to conclude that there is an inventive step in the proposed method.

In addition, the total technical result (drying, impregnation, pore clogging during the electrochemical process) is not due to a simple sum of the results of each individually distinguishing feature due to their inherent properties. Signs affect each other, interconnected. The addition of an iron salt to a hydrophobic liquid not only promotes pore colmatization, but also generally intensifies, enhances the electrochemical process, improving the conductivity of the hydrophobic liquid due to the presence of iron ions.

The method is illustrated in the drawing, which shows the arrangement of electrodes and holes for hydrophobic liquid on the treated area.

The method is as follows. On the treated area 1 of the building structure, holes 2, 3, 4 are made. Electrodes are placed in the prepared holes 2, 3. They can be made cylindrical in the form of pins. But the best option is to use electrodes made of elastic foil of an electrically conductive anticorrosive metal (copper, steel), since elasticity promotes better contact of the electrodes with the holes. The electrodes installed in the holes 2 are connected to the positive pole of the power source, and the electrodes installed in the holes 3 are connected to the negative pole of the power source. Thus, the anodes alternate with the cathodes in a checkerboard pattern. A solution of a hydrophobic liquid is placed in the remaining part of the holes 4 between the electrodes, and a potential is supplied to the electrodes that does not cause intense electrolysis processes (in the range of 0.1-1.4 V), i.e. create a weak electric field. As a result of the process of electroosmosis, an array of the treated area of building material is flooded and mass transfer of particles of hydrophobic liquid occurs due to the creation of artificial potential gradients and solution concentrations, as well as due to migration processes under the action of a rectified electric current. As a solution, any hydrophobic water-soluble liquid of an organic or inorganic nature is taken and an iron salt is added at a rate of 0.5-8% by weight.

To ensure uniform distribution of hydrophobic protection fluid over the volume of the structural material, a permanent magnetic field 5 is applied to its surface 5 (drawing) so that its lines of force are directed perpendicular to the direction of the diffusion or migration particle flux, which is known to be directed from anode to cathode. For this, the magnets 5 are placed parallel to the treated area between the pairs of the anode-cathode. The resulting Lorentz force is directed in this case perpendicular to the movement of charged particles, which causes their migration not only along the line of electric current, but also into the volume of the product. The latter significantly improves the quality of material processing, which can be seen from the data given below in table. 2.

Tables 1 and 2 show the results of water absorption of some building materials.

Laboratory tests of the proposed method were carried out on building materials: brick and concrete. For comparison, tests of the method and the prototype were carried out.

As a hydrophobic liquid, a silicon-organic liquid was used (aquasil diluted with an aqueous solution in a ratio of 1:10), to which nitric acid was added. The results are summarized in table. 1. From the table. 1 shows that the best water protection is achieved by adding an iron salt in the range of 2-8 wt.%. The data table. 1 also indicate that the water absorption of building materials processed by the claimed method is lower than that of the prototype.

The effect of a constant magnetic field was also tested. The data are summarized in table. 2 (for an iron salt concentration of 6%).

It was also established that the impregnation time, depending on the building material of the applied electric field, was 20 to 30 hours for brick, 24 to 32 hours for concrete, and the distance between the electrodes was 50 cm.

Claims (4)

1. A method of protecting building materials and structures from moisture, according to which rows of holes are made on the treated area, electrodes are installed in the holes, the holes are filled with a hydrophobic liquid and potential is applied to the electrodes, creating a weak electric field, characterized in that it is filled into the hydrophobic liquid before filling it additionally introduces an iron salt, for example, iron nitrate, in an amount of 0.5-8 wt.%, moreover, when installing electrodes, openings are left between them, and feeding to x potential is alternated anodes and cathodes on the cultivated area in a staggered manner, with the hydrophobic liquid is filled into the openings between the electrodes. 2. The method according to claim 1, characterized in that the holes for the electrodes are performed at a distance of 20-50 cm from each other. 3. The method according to claim 1 or 2, characterized in that the elastic electrodes are used as electrodes. 4. The method according to any one of claims 1 to 3, characterized in that it additionally acts on the treated area with a constant magnetic field, placing its lines of force perpendicular to the direction of the migration flow of hydrophobic fluid particles caused by the action of an applied electric field.