PL165879B1 - Method of upgrading porous materials and products or articles made of them, in particular electrically insulating ones - Google Patents

Abstract

Method of processing porous materials and products or objects made of them, especially electrically non-conductive, by means of a conditioner and electric current, characterized in that at least one positive and negative electrodes are applied or attaches to the surface of the material or recesses and attaches to the source direct current and the current flow is checked, and in its absence, saturation is performed saturating agent until a moisture content of about 2% has occurred, after current flow has occurred the material is saturated with a surface or deep enriching agent, capable of conducting current and distributing directionally in the produced field electrically, preferably in the type of silicone resins or mixtures thereof, dissolved or diluted in solvents or diluents, and then the electrodes are removed.

Description

The subject of the invention is a method of refining porous materials and products or objects made of them, in particular electrically non-conductive, by means of a refining agent and electric current.

It is known to refine some electrically conductive porous materials or products made of them, for example coating of materials or metal products with a more noble material by means of electrolysis.

It is known to improve non-conductive porous construction materials by introducing into their interior, without damaging their structure, by injecting, for example, hydrophobic agents that reduce water absorption or make them resistant to water absorption, in the form of methyl silicone resins dissolved in hydrocarbon solvents or other silicone resins.

The object of the invention is to provide a refining method which is equally suitable for various types of porous materials, in particular electrically non-conductive materials, and which materials or products or objects made of them could obtain at least partially new properties, and in principle for the most part, or regain lost properties, for example resistance to surface and deep water absorption, resistance to chemicals, weather conditions, aging processes, ultraviolet rays, corrosive processes, preventing or eliminating microorganisms, development of bacteria and building fungi, improving or giving electrical insulation, fire resistance , improving aesthetics, strength and other properties.

Surprisingly, it has been found that this task can be solved simultaneously with many porous materials, especially electrically non-conductive materials, if measures are used as a conditioner which simultaneously exhibit the following properties: conductivity of electric current, ability to move in the direction of flow current, strong penetrating properties of the capillaries in the electric field, and preferably the ability to harden or bind to the material to be processed after removing the current flow.

This task has been solved due to the fact that at least one positive and negative electrode is placed or attached to the surface of the material or plunged into the material and connected to a direct current source and the current flow is checked, and in its absence, saturation is carried out with a saturating agent up to to obtain a moisture content of about 2%, after the occurrence of current flow, the material is impregnated with a surface or deep enriching agent capable of conducting the current and directionally distributing it in the generated electric field, preferably in the form of silicone resins or their mixtures dissolved or diluted in solvents or diluents, and then electrodes are removed.

Preferably the processing is carried out with a polyalkyloxy siloxane resin dissolved in aliphatic alcohol solvents, especially ethyl butyl or isobutyl alcohol, or other organic solvents or mixtures thereof.

In a preferred development of the method, the electric current flows intermittently, after which the polarity of the electrodes changes at least partially to the reverse.

In the preferred operation of the process, the conditioner itself, water or aliphatic alcohols are used as the wetting agent.

The advantage of the method according to the invention is the possibility of upgrading various porous materials, in particular electrically non-conductive ones, in order to give them new properties, or to raise the existing properties to optimal limits. This is especially true of building materials. Most often, building materials, such as wood, concrete products made of cement, have a moisture content above 2%. Walls made of solid brick, plastered, in dry rooms, have a humidity of 2-5%. Concrete, defined as dry, has a moisture content above 5%. When refining these materials, it is enough to apply or attach the electrodes and connect them to a DC source to saturate with the refining agent itself. The same materials dried to below 2% humidity require pre-wetting with a moisturizer. Depending on the place where the electrodes are applied or mounted, that is to say in which mutual planes they are located, an essentially horizontal, vertical or oblique finishing layer can be obtained.

As already mentioned, a special role as an enriching agent is played by the polyalkyloxysiloxane resin, whose properties such as the lack of gelling ability under the influence of electric current flow, the ability to gel instantly under the influence of moisture, strong penetrating properties of capillaries in an electric field, on the one hand, and very strong after gelling. the ability to repel liquids, resistance to chemicals, aging processes, ultraviolet rays, fire resistance up to 300 ° C, antistatic, ability to neutralize salt, microorganisms, development of building fungi, no electrical conductivity, etc. on the other hand, allow for refinement materials, since the materials essentially all adopt said properties of the resin. In the case of refining silicon-containing materials, the components of the resin bind to it and increase or maintain their strength.

EXAMPLE 1 Solid ceramic brick was almost completely dried at the elevated temperature and then immersed in water. The brick increased its weight by 25%, so the capillary capacity was 25% of its volume. The brick was dried again at an elevated temperature, and then the + electrode and the - electrode were applied to the surface of the brick and connected to a constant current source with a voltage of 22V. At the same time, the brick was moistened with a polyalkoxysiloxane resin dissolved in ethyl alcohol. After 15 minutes, an electric current was found to flow and the resin impregnation was continued until the capillaries were full. After saturation, the electrodes were immediately disconnected. Then the brick was cut and submerged in water. The sections of the brick did not show a dark color, so the brick became non-absorbent. The hydrophobized layer of brick was characterized by a strong ability to repel water, the drops of which on the surface of the brick were like mercury drops on glass, as well as resistance to acids, including royal water,

165 879 as well as with a reinforced structure due to the deposition of silicon from the conditioner on the walls of the capillaries.

Example II. The + and - electrode was placed on the surface of the solid ceramic brick, and then connected to a 22V DC source and painted with the resin from Example 1. It was found on the surface of the brick to which the electrode was applied - high absorption of the agent, which was insignificant at the + electrode. The brick was cut and submerged in water. The surface to which the electrode was attached was hydrophobic to a thickness of 2-2.5 cm. On the other hand, on the surface to which the electrode was attached + the layer was 1.5 cm. It also turned out that the cross-sectional area of the brick was partially hydrophobized. The brick received properties similar to the brick from Example 1.

Example III. Proceeding as in example 1, wood, concrete, gypsum and porous stone were treated. In these materials, after applying the electrodes, no current flow occurred, therefore the surfaces were saturated with the agent from Example I and as the center penetrated deep into the material, a current flow occurred, with the penetration of the agent into the materials increasing as the current flow increased, until it was completely saturated, then the electrodes were disconnected. After 70 hours, complete gelation of the agent and formation of a hydrophobized layer was found. These materials had the properties as in example 1.

Example IV. After applying the + and - electrodes, wood, brick and concrete were painted on one side from the electrode side + with the agent, in the form of a polyalkyloxysiloxane resin dissolved in a mixture of ethyl and butyl alcohol. Painting was completed within 36 hours, and the agent consumption was twice the capillary capacity of these materials due to the rapid evaporation of alcohol. Carbonation was discontinued and the electrodes were disconnected. It was found computationally that filling the capillaries with the dry mass of the agent was, after alcohol evaporation, over 40% of the capillary volume. Properties as in example I.

EXAMPLE 5 Proceeding as in Example 1 with brick and concrete, impregnation was carried out for 7 days and the total consumption of agent was more than four times greater than the capillary capacity. In terms of weight and computation, it was found that the filling of the capillaries with the dry mass of the agent, after alcohol evaporation, was over 80% of the capillary volume, which was found after the brick and concrete were cut.

Example VI. The object, in the form of a building made of solid brick with a thickness of two bricks, with an average wall humidity of 14-15%, was refined by painting and deep injection of polyalkyloxy siloxane resin dissolved in ethyl alcohol. Several dozen + electrodes were used, spaced 50 cm apart, embedded in holes made in the wall, above the holes for hydrophobization - injection and two electrodes - embedded in the ground. The deep injection was carried out during 6 hours, using an average of 121 agent per 1 m ² of the wall section. During the injection, the + electrodes were attached to the wall in every second electrode and connected to -. After all the prescribed amount of agent had been injected, the injection was stopped for 8 hours and then the electric current was turned on again in the opposite direction to the original direction of flow for 12 hours. The center was rising towards the electrode -. The electrodes were removed. Two bricks were cut from the wall of the building in the field of the electric field and submerged in water. It was found that an almost horizontal hydrophobized layer 8-12 cm thick was formed in the bricks having the properties of example

I. At the same time, neutralization of salt crystals and building fungi located in the agent's action zone was found.

Example VII. The + and - electrodes were applied to the dry plaster block on both sides. There was no current flow. The block was moistened with water by sprinkling it until the current flow was obtained. Then the procedure of Example 1 was followed and the same properties were obtained.

Example VII. On a fragment of the old reinforced concrete structure, crushing of concrete and corrosion of metal bars of the reinforcement were found. After removing the damaged part of the concrete, it was supplemented with fresh concrete, then the electrode - was attached to the rebar, and the electrode + was attached to the surface of the concrete and refined in accordance with example I. After forging the reinforcement fragments, it was found by exposure to sulfuric and nitric acids,

High resistance of concrete, neutralizing the effect of salt, the tarnish of which occurred on part of the refined fragment, and construction fungi. It was also found that rust on the reinforcement bars formed a protective layer with a refining agent that was highly cohesive and resistant to salts and acids, and was not electrically conductive.

This example proves the great possibilities of protecting the reinforcement in reinforced concrete structures, which, despite the concrete coating, under the influence of time, groundwater or surface water containing harmful chemical substances and the action of stray currents, is subject to corrosion and even electrocorrosion.

To sum up, in the method according to the invention, electrically conductive solvents, moving along the direction of the current flow, were used to transport materials dissolved or suspended therein, in this case improvers. The solvent naturally evaporates in a short time, and the transported material settles in the form of a film on the capillaries, or almost completely fills the capillaries, giving the refined material new physical properties or restoring them, such as increasing resistance to moisture processes, the effects of even caustic chemicals, increasing resistance to aging processes, the action of microorganisms, surface discoloration, neutralization of building fungi development, neutralization of salt crystals and many others.

Most often, porous building materials contain moisture and chemical or organic compounds dissolved in water, which accumulate in capillaries and may, under certain natural conditions, lead to the spontaneous flow of direct current with low parameters. In the absence of current flow, porous materials should be deliberately moistened with water or a solvent. Depending on the structure of the porous material and the type of desired refinement, electrodes are attached to the surface of the material or fixed in previously made holes, their number ranges from two to many, arranged in a row or in the form of a grid. The distance between the electrodes is 30 to 50 cm.

Publishing Department of the Polish Patent Office. Mintage 90 copies. Price PLN 1.00.

Claims (4)

Patent claims 1. A method of refining porous materials and products or objects made of them, in particular electrically non-conductive, by means of an enrichment agent and an electric current, characterized in that at least one positive and negative electrodes are applied or fixed on the surface of the material or deeply and is connected to a direct current source and the current flow is checked, in the case of its absence, saturation is carried out with a saturating agent until the moisture content of about 2% occurs, after the current flow occurs, the material is saturated with a surface or deep enriching agent, capable of conducting current and distributing it in a directional manner in an electric field generated, preferably in the form of silicone resins or mixtures thereof, dissolved or diluted in solvents or diluents, and the electrodes are removed. 2. The method according to p. The process of claim 1, wherein the resin is a polyalkyloxy siloxane resin dissolved in aliphatic alcohols, especially ethyl, butyl, isobutyl alcohol, or in other organic solvents or mixtures thereof. 3. The method according to p. The method of claim 1, characterized in that the electric current flows intermittently, after which the polarity of the electrodes changes at least partially to the reverse. 4. The method according to p. The process of claim 1, characterized in that the conditioner itself, water or aliphatic alcohols are used as the moisturizing agent.