CS231996B2 - A method for increasing the strength and watertightness of granular materials and / or solids - Google Patents

Abstract

The invention relates to a method for increasing the strength and watertightness of granular materials and/or solid bodies, in particular damaged underground sewer networks and civil engineering structures, using aqueous mixtures of monomers forming a hydrogel. The method is characterized in that aqueous gel-forming systems are applied to the object to be treated and/or introduced into this object and/or its surroundings, which contain by weight 10 to 40% acrylamide and/or methacrylamide, a total of 0.1 to 2% of a water-soluble vinyl comonomer, 0 to 2% of a water-soluble polyacrylamide or a water-soluble acrylic copolymer, further 0.01 to 2% of water-soluble free radical initiators and optionally 0.1 to 5% by weight of an amine salt formed with an organic or inorganic acid, the basicity of which is lower than that of ammonia, and this system is brought into contact with ammonia. The method according to the invention allows the gel to form at the desired time and a stable solid gel is formed in a shorter time. In this way, structural materials that are sensitive to sudden temperature changes are not damaged.

Description

(54) Method for increasing the strength and watertightness of granular materials and/or solid bodies

The invention relates to a method for increasing the strength and watertightness of granular materials and/or solid bodies, in particular damaged underground sewer networks and civil engineering structures, using aqueous mixtures of monomers forming a hydrogel. The method is characterized in that aqueous gel-forming systems are applied to the object to be treated and/or introduced into this object and/or its surroundings, which contain by weight 10 to 40% acrylamide and/or methacrylamide, a total of 0.1 to 2% of a water-soluble vinyl comonomer, 0 to 2% of a water-soluble polyacrylamide or a water-soluble acrylic copolymer, further 0.01 to 2% of water-soluble free radical initiators and optionally 0.1 to 5% by weight of an amine salt formed with an organic or inorganic acid, the basicity of which is lower than that of ammonia, and this system is brought into contact with ammonia.

The method according to the invention allows the gel to form at the desired time and a stable solid gel is formed in a shorter time. In this way, structural materials that are sensitive to sudden temperature changes are not damaged.

The invention relates to an improved method of consolidating, sealing and waterproofing granular materials and/or solid bodies, such as underground works and construction objects (especially defective underground sewerage networks and other pipelines) from pre-fabricated profile bodies or construction elements, as well as cavities and soil-rich areas.

A large number of methods have been developed to increase the tightness, strength and watertightness of underground mining and construction structures. These known methods are also suitable for soil consolidation, as well as for sealing and strengthening natural or artificial (e.g. drilled) joints and cavities rich in soil. One of the main areas of application of these methods is the repair and sealing of defective underground channels, pipelines and other water-tight structures.

The most modern of the known methods used for this are those in which a waterproof polymer gel is formed in or on the body to be treated and/or in its vicinity. According to Hungarian Patent No. 153,975, water glass is applied to the area to be treated in order to form a waterproof polymer, and this is hardened by the action of a gas mixture containing silicon tetrafluoride and hydrogen fluoride. The gas mixture can also be generated directly at the site of action by the reaction of fluoride salts (preferably sodium fluorosilicate) and acids. Although the strengthening and waterproofing effect achieved by this method is satisfactory, this method has not yet found widespread application in practice, since the gas mixture containing hydrogen fluoride, which is required for the formation of the gel, is extremely toxic.

According to Hungarian patent specification No. 158'538 and US patent specifications Nos. 2,801,983, 2,801,984 and 2,856,380, a waterproof polymer gel is formed from water-soluble and gel-forming acrylic monomers and a steric crosslinking agent (monovalent or divalent aldehydes or divinyl compounds and, in particular, methylene bis-acrylamide). Redox catalytic systems are used to initiate the polymerization, which contain alkali metal persulfate or ammonium persulfate as the oxidizing component and monovalent copper, divalent iron or divalent tin compounds, alkali metal thiosulfates, alkali metal sulfites or various amine compounds as the reducing component. Under the action of the redox catalytic system, a stable, solid hydrophilic gel is formed from the mixture of gel-forming monomers in an instant, which has an excellent sealing, reinforcing and waterproofing effect.

This process has the disadvantage that the polymerization either proceeds too quickly or a significant portion of the toxic starting monomer does not react. At the point of use, the prepared aqueous gel-forming solution must therefore be brought into contact with the soil to be consolidated or the object selected for treatment at high speed, and this requires special, very powerful equipment (e.g. pumps). These equipment can become clogged very easily with the polymer that is formed, and their cleaning is time-consuming, material-intensive and labor-intensive.

In Hungarian patent application MA-2924, a method is proposed for increasing the strength and watertightness of granular material and/or solid bodies using a stabilized aqueous gel-forming system based on acrylates. According to this method, an aqueous gel-forming system, which contains as a gel-forming component one or more water-soluble acrylic monomers, as a steric crosslinking agent methylene-bis-acrylamide comonomer and/or one or more divalent aldehydes, an alkali metal persulfate or ammonium persulfate and at least one amine compound forming a redox catalytic system and further optionally auxiliary substances, is applied to the object to be treated or to this object or its vicinity in a completely or almost completely saturated state with molecular oxygen and then the oxygen supply is disconnected. When the system is no longer saturated with oxygen, gel formation occurs immediately or at a predetermined time.

This procedure is suitable for eliminating the shortcomings of methods working with unstabilized gel-forming systems based on acrylates, but difficulties arise when the viscosity of the gel-forming system is significantly increased by the addition of a polymer (above 10 mPa. .sj.). The inhibiting effect of air or a mixture of gases containing oxygen, which are blown through the system, decreases proportionally with the increase in viscosity and the inhibiting effect slows down. However, for reasons of economy, it is in many cases expedient to significantly increase the viscosity, because in the case of an excessively diluted solution, large amounts of reactive solution leak into the surroundings of the treated object. The polymerization of the leaked solution is also delayed or inhibited by the air contained in the pores of the soil and the unreacted monomer contaminates the surroundings.

According to Hungarian patent application number 1521/80, these disadvantages are circumvented by using an aqueous gelling system that does not contain amine compounds. The gelling system used at the treatment site is heated by blowing hot water vapor and/or inert gas to a temperature of at least 40 °C, expediently to 60 °C. In this way, gel formation can always be started at the desired time and the gel is formed very quickly. Another advantage is that the gel can be formed from a very highly viscous gelling system in a shorter time. Problems with environmental pollution can also be significantly reduced in this way.

However, in the practical application of the method according to Hungarian patent application No. 1521/80, it turns out that in many cases it is not possible to

231896 structural material intended for the treatment of sewerage networks is not sufficiently resistant to sudden changes in temperature, and therefore during the heat treatment of these channels additional cracks and damaged areas are formed. This results in a requirement to develop a new process that combines all the advantages of the method according to Hungarian patent application number 1521/80 and at the same time is not harmful to the structural materials of the objects intended for treatment.

The method according to the invention fully meets these requirements.

In our own experiments, it was found that aqueous gel-forming systems containing 10 to 40% by weight of acrylamide and/or methacrylamide, a total of 0.1 to 2% of a water-soluble vinyl comonomer, 0 to 2% of a water-soluble polyacrylamide or a water-soluble acrylamide copolymer, and 0.01 to 2% of water-soluble free radical initiators (for example, organic peroxy compounds and azo compounds, alkali metal peroxysulfate or ammonium peroxysulfate, etc.), depending on the type and concentration of the free radical initiator, change into a gel within 0.5 to 30 hours. However, when such a system is brought into contact with ammonia, the rate of gel formation increases rapidly and a stable solid gel is formed from the aqueous solution within about 3 to 30 minutes. Based on knowledge of the relevant technical literature, it is surprising that ammonia has such an effect, since as redox reducing components Ammonia is never used in catalytic systems and the accelerating or retarding effect of ammonia on polymerization has never been mentioned.

It has also been found that the gel formation rate can be further increased by adding to the aqueous gel-forming system in an amount of 0.1 to 5% by weight of an amine salt formed with organic acids, the basicity of which is lower than that of ammonia. This amine salt does not affect the gel formation rate in the system at all in the absence of ammonia. However, the action of ammonia releases the corresponding amine from the salt, which together with the free radical-releasing initiator forms a redox catalytic system, thereby considerably increasing the gel formation rate.

These findings make it possible to achieve gel formation in the gel-forming system as in the case of the method according to Hungarian patent application No. 1521/80 — always at the desired moment after connection and the gel is formed in the area connected with the gel-forming system or filled with it in a very short time. Since the treatment with ammonia does not damage the treated objects even slightly, the method according to the invention can also be used in those areas in which the method according to Hungarian patent application No. 1521/80 would lead to damage to the structural materials.

In addition to the effect already mentioned, ammonia has another advantage, namely that it expels a significant proportion of oxygen that is adsorbed or dissolved in the pores of the soil or in the groundwater, as a result of which oxygen can no longer have an inhibitory effect and the polymerization rate increases. For these reasons, the reactive solution polymerizes practically quantitatively and reacts with the hydrogel, and no toxic monomers remain in the environment. A small amount of ammonia remains in the soil or in the treated objects (compared to the monomer, it is a harmless substance), which is then bound in the soil and acts as an artificial fertilizer.

The subject of the invention is therefore an improved method for increasing the strength and watertightness of granular materials and/or solid bodies, in particular damaged underground sewer networks and objects of deep mine workings using aqueous mixtures of monomers forming a hydrogel. In the sense of the invention, 10 to 40% by weight of acrylamide and/or methacrylamide is applied to the treated object or introduced into this object and/or its vicinity together with 0.1 to 2% by weight of a water-soluble vinyl comonomer, up to 2% by weight of a water-soluble polyacrylamide or a water-soluble acrylamide copolymer, 0.01 to 2% by weight of a water-soluble initiator providing free radicals and optionally 1 to 5% by weight of an organic or inorganic acid forming salts with an amine whose basicity is less than that of ammonia, and the resulting aqueous gel-forming system is mixed with ammonia.

As a vinyl comonomer according to the invention, used in the aqueous gel-forming system, divinyl compounds (especially methylene-bis-acrylamide) and/or water-soluble vinylcarboxylic acids, such as acrylic acid, methacrylic acid, itaconic acid, maleic acid and similar unsaturated carboxylic acids, are suitable. Aqueous gel-forming systems can also contain vinylcarboxylic acids in the form of salt-forming components derived from amine salts. In this case, the copolymerization component required for gel formation is released from the amine salt by treatment with ammonia.

Of the above-mentioned components, those which contain known auxiliaries can also be used as aqueous gelling systems. Such components include, for example, polymers which increase the viscosity of the aqueous gelling system (e.g. polyacrylamide, hydrolyzed polyacrylamide, hydrolyzed polyacrylonitrile, potassium, sodium and ammonium salts of polyacrylic acid and other water-soluble polymers) or granular or fibrous substances which increase the strength of the gel (e.g. sand, quartz flour, asbestos fibres, glass fibres, bentonite, ash, perlite expanded to fine grains). If a system which also contains an amine salt is used, the basicity of the amine component of the amine salt must be greater than the basicity of the auxiliaries, since in the opposite case (when the more strongly basic auxiliary substance is released from the amine salt of the amine) gel formation would start too early.

As already mentioned, the aqueous gel-forming systems used in the process according to the invention can be stored independently of the type and concentration of inhibitor at room temperature for generally about 0.5 to 30 hours without change. In the case of a longer storage time than has been required so far, the gel-forming system described in Hungarian patent application MA-2924 can be stabilized by introducing molecular oxygen or a gas mixture containing molecular oxygen (preferably air).

For example, an aqueous gelling system can be mixed with ammonia in the following ways:

For example, an aqueous gelling system can first be applied to the object to be treated, or to this object and/or its surroundings, the excess gelling system is removed as necessary, and then ammonia or its aqueous solution is introduced into the gelling system. (However, gaseous ammonia is introduced in a practical manner.) The solution is also suitable for channels and objects lying above or below the groundwater level and for the treatment of granular material.

bj It is also possible to first introduce ammonia in the form of a gas or an aqueous solution onto the object to be treated or into this object or its surroundings, but expediently in the form of a gas, then remove the excess ammonia as necessary and finally introduce an aqueous gel-forming system. This method is particularly recommended for the treatment of canals, objects and granular materials lying above the groundwater level (for example, the upper layers of the bottom and rocks).

Application to the object to be treated or introduction into this object or its surroundings can be carried out in the manner described in the patent documents cited below.

If, for example, a larger diameter canal is to be repaired by the method according to the invention, space-limiting elements are expediently introduced into the canal, which are described in Hungarian patent document No. 153 148. In this case, a significantly smaller amount of gel-forming system is used to fill the canal. The excess gel-forming system can be removed, for example, by means of a pump, if necessary. According to a preferred embodiment of the method according to the invention, compressed air with a pressure of several hundred kilopascals is introduced during the pumping out of the excess liquid, thereby preventing the liquid from flowing back.

By contacting the aqueous gelling system with ammonia, a stable solid gel is formed within a short time (generally within a few minutes) which has the desired sealing, strengthening and waterproofing effects. The method according to the invention can also be used successfully for the rapid gelation of a highly viscous gelling system. The resulting gel is elastic and swells under the action of water. It is therefore also suitable for sealing cracks which may be formed by soil movement and which have a width of a few millimetres. The strength and sealing parameters of the resulting gel correspond to the relevant data of the gel which was produced according to Hungarian patent application No. 1521/80.

The method according to the invention has all the advantages of the method according to Hungarian Patent Application No. 1521/80 and in addition has the advantage that it is also applicable to the reinforcement of structural materials suffering from damage due to low strength due to sudden thermal changes.

The process according to the invention will be illustrated by the following examples, which, however, do not limit the invention in any way. Example 1

A glass tube 50 cm long and 5 cm in diameter is filled with moist soil. Ammonia gas is introduced from the bottom up through the soil cylinder formed in this tube at a rate of 1000 liters per hour for about 15 minutes. Then 100 ml of an aqueous gel-forming solution of this weight is applied to the cylinder.

composition: 20.0% 0.1% 0.1% 1.0% 78.8% acrylamide methylene-bis-acrylamide ammonium persulfate triethanolamine hydrochloride water.

The liquid is absorbed into the cylinder within 2 to 5 minutes and when it has traveled 20 to 30 cm it turns into a gel, first the front side of the liquid and then, in a few minutes, the entire amount of solution. If the sand cylinder is not treated with ammonia in this experiment, the gel formation process takes about 5 hours.

Example 2

Fig. 1 shows a section of the canal intended for repair. The section of the canal is closed with a pipe closure 1 and then filled with a solution located in a tank 4, which is introduced through a shaft 2. The solution in the shaft should reach 2 meters higher than the lower opening of the shaft. The hydrostatic pressure of the column of liquid in the shaft ensures that leaks, cracks and cavities 5 are filled. The shaft is additionally filled with liquid according to the degree of filtration. The solution has the composition shown in example 1.

After a suitable period of time (generally one hour) has elapsed, the solution is removed from the channel through the shaft 2. As shown in Fig. 2, the shafts 2 and 3 are closed by airtight cover plates 6 and 7, which control the respective opening and connection possibilities. The cover plates must be weighted or attached to the shaft so that they do not lift up under the gas pressure during subsequent treatment. After the excess solution has been pumped back into the tank 4, ammonia gas is forced from the tank 8 into the channel section through the pipe 9. In this process, the closing devices 12 and 13 are closed and the closing devices 13 and 15 are opened. When gas appears in the closing device 15, it is closed and the gas supply is adjusted so that an overpressure of 20 kPa is created in the channel section. The pressure in the channel section is monitored by pressure gauges 10 and 11.

After 25 to 30 minutes, the gas supply is interrupted and the shut-off device 13 is closed. Then the connection of the shut-off device 15 is connected to the line 17 of the tank 16 and the shut-off devices 12 and 15 are opened. Then, the ammonia gas remaining in the channel section is forced out by the air compressor 16 with the help of air compressed through the line 9 into the line 17 and from there into the tank 16 filled with dilute hydrochloric acid, where it is absorbed. Then the shut-off plates, pipe fittings, etc. are dismantled and the repair is completed.

The solution, injected or pressurized into damaged areas, cracks, leaky joints and areas where the sewer is leaking, forms a gel under the action of gas. The gel hardens and forms a waterproof layer 5. This not only seals the damaged areas and leaks, but also seals the surrounding soil and makes it impermeable to water. This significantly improves the placement of the pipes, which is crucial for the stable operation and service life of the sewer network.

Naturally, the procedure can also be carried out by simultaneously repairing a sewer section located between three or more shafts and then correspondingly installing additional air connections, tanks, and the like.

Example 3

If the cleaning, crawling and inspection shafts of the sewer section intended for treatment are not to be used for any reason or if the solution is to be saved, the method can be carried out according to the procedure shown in Fig. 3. The outflow side of the shaft 3 is closed with a pipe closure 18. This is provided with a corresponding feedthrough 19, to which a venting or introduction line 20 serving similar purposes can be connected as needed. The closing device 14 is opened to introduce the solution into the sewer section. The repair is carried out essentially in the manner explained in connection with Fig. 2, of course with the difference that the gas and compressed air are effectively introduced through an airtight plate placed on the shaft 2.

When a section lying between three or more shafts is to be repaired at once, the shafts between the end points of the section can be eliminated by connecting the inlet and outlet sides of these shafts to a shut-off pipe provided with bushings and connecting them between the two with a hose.

Example 4

Fig. 4 shows the possibility of repairing a sewer with a larger cross-section. It would be uneconomical or time-consuming to fill the entire cross-section of the canal with a solution. After the section is closed, a spacer 21 equipped with an inflatable plastic hose is inserted into it. The composition of the solution used for filling and the work steps during the repair are similar to those described in examples 1 and 2.

Using appropriate auxiliary means, it is also possible to occasionally not repair the entire section of the channel, but only the damaged part of the section, for example the part that is leaking.

The method is also suitable for repairing sewers below the groundwater level. In this case, the liquid must be filled to a level above the groundwater level to guarantee the necessary pressure.

This method can also be used to repair brick-built canals. Particularly good results are achieved when repairing older canals built of bricks laid on lime mortar. In these canals, the lime mortar is relatively quickly wasted under adverse conditions by ex- or infiltrated water that forms behind the canal walls, which causes potholes, cavities and the canal to break through. This often leads to the collapse of street canals.

During repair, the solution fills the voids in the canal wall that have been washed out and the harmful cracks, and after the gel has formed, the clarifiers almost stick together. A cross-section of such a canal is shown in Fig. 5. The layer formed around the canal wall makes the canal completely waterproof.

Example 5

Fig. 6 shows the repair of a damaged and leaking sump located in groundwater.

The sump is cleaned appropriately and then, through the inlet opening, filled with the solution according to example 1. In the event that water is being filtered from the sump into the surroundings, additional topping up of the level to a constant solution level is ensured. After a suitable period of time (about 1 to 2 hours), when filtration from the sump can hardly be observed or cannot be detected at all, the solution is removed from the sump using the procedure described in example 2 and ammonia gas is introduced into it. After 25 to 30 minutes, the gas supply is stopped. This completes the repair. The solution has penetrated the damaged areas, partially seeped into the surrounding soil and a gel has formed there. The gel plug 23 and the soil layers containing the gel guarantee complete watertightness of the sump.

Space-limiting elements can be placed in the sump before filling, which significantly reduces the amount of solution required.

Example 6

Fig. 7 shows the stabilization of an obliquely inclined reinforced concrete water tower.

In the vicinity of the foundation body 24, a conventional perforating injection pipe 25 used for ground consolidation work is driven in for each foundation body 24, up to the required depth of the ground. Then, a solution of the composition given in Example 1 is pumped from the reservoir 26 into the ground by means of a pump 27. The amount of solution is controlled according to the regulation for ground consolidation and the quality of the ground and can be, for example, 80 liters per pipe. During the injection of the solution, the closing device 28 is closed and the closing device 29 is opened. After the solution has been injected into the ground, the closing device 28 is opened, the closing device 29 is closed and ammonia is introduced under pressure from the reservoir 31 through the injection pipe through the pipe 30 for 25 to 30 minutes. The gas action causes the injected material to solidify and form a solid gel layer around the pipe, depending on its size, in a radius of 30 to 50 cm. This layer of gel provides a sufficiently solid foundation for the object.

Example 7

The procedure is as described in Example 6, but a solution with the following mass composition is used:

parts acrylamide parts methacrylamide parts triethylenediamine hydrochloride

0.2 parts methylene-bis-methacrylamide

0.2 parts potassium persulfate

0.5 parts polyacrylamide

75.1 parts water.

The properties of the resulting hydrogel are similar to those described in Example 6. The waterproofing of the material is excellent. The time for soil treatment with ammonia can be reduced to 15 to 20 minutes.

Example 8

The procedure is as described in Example 6, but a reactive solution with the following mass composition is used:

parts methacrylamide parts sodium methacrylate

0.5 parts tetraethylene glycol dimethacrylate parts diethylene triamine phosphate

0.1 part ammonium persulfate

0.4 parts of acrylamide-acrylic acid copolymer to parts of water.

The resulting hydrogel is stronger than that of Example 6 and has excellent water tightness. The time for soil treatment with ammonia can be reduced to 15 to 20 minutes.

Example 9

The procedure is as described in Example 6, with the difference that gaseous ammonia is introduced through a perforated pipe for 30 minutes and then a reactive solution with the following mass composition is injected into ¹ m of soil:

parts acrylamide 0.5 parts glycerin dimethacrylate parts dimethylaminoethanol salt of acrylic acid

0.5 parts ammonium persulfate, parts bentonite, parts water.

The obtained hydrogel is very elastic and has a great ability to stretch, as well as excellent waterproofness.

Claims (4)

FOREWORD Method for increasing the strength and watertightness of granular materials and / or solid bodies by means of aqueous mixtures of hydrogel-forming monomers, characterized in that aqueous gel-forming systems are applied to and / or into the article to be treated and / or into the article and / or its surroundings. containing from about 10% to about 40% acrylamide and / or methacrylamide, a total of about 0.1% to about 2% water soluble vinyl comonomer; up to 2% water-soluble polyacrylamide or water-soluble acrylic copolymer, further 0.01 to 2% free radical-providing initiators, water-soluble and optionally 0.1 to 0.1% by weight, but up to 5% amine salt formed with an organic or inorganic acid whose basicity it is less than the basicity of ammonia, which system is contacted with ammonia. 2. A method according to claim 1, wherein the aqueous gel-forming system is first introduced onto or into the article to be treated and / or around the article, the excess gel-forming system is removed as necessary, and then ammonia is introduced into the aqueous gel-forming system. 3. A method according to claim 1, characterized in that ammonia is first introduced on or into the article to be treated and / or around it, the excess ammonia is removed as necessary, and then an aqueous gel-forming system is introduced. Process according to any one of Claims 1 to 3, characterized in that the ammonia is used in gaseous form.