JP6867649B2 - Sealing agent supplies and chemical injection method - Google Patents

Description

The present disclosure relates to a sealant, a sealant article, and a chemical injection method.

Conventionally, a chemical injection method for the purpose of improving the ground has been known. The chemical injection method is disclosed in Patent Document 1. As the chemical injection method, there are a strainer method, a double packer method and the like. Further, the double packer method includes a seal grout method and a ground packer method.

In the chemical injection method, first, an excavation hole is formed in the ground, and an injection outer pipe is inserted into the excavation hole. In addition, the injection inner tube is inserted into the injection outer tube. An injection port is formed in the injection outer tube. The drug solution is pumped to the injection port by the injection inner tube. The chemical solution is generally an acidic silica-based chemical solution. The pumped chemical solution is discharged from the injection port of the injection outer tube and permeates the ground. The chemical solution that has penetrated into the ground solidifies to form an improved body, which improves the ground.

If there is a gap between the outer injection pipe and the ground, the chemical solution discharged from the injection port of the outer injection pipe will escape through this gap. Therefore, in the seal grout method double packer method, a cement bentonite filler is filled between the injection outer pipe and the ground in order to suppress the escape of the chemical solution described above. The chemical solution discharged from the injection port splits the cement bentonite filler and permeates the ground.

Japanese Patent No. 3313351

In the seal grout type double packer method, the chemical solution discharged from the injection port of the injection outer pipe permeates the ground through the narrow space created by the splitting of the cement bentonite filler. Therefore, it has been difficult to expand the range in which the chemical solution permeates in the ground (hereinafter referred to as the permeation source).

In addition, in the double packer method of the ground packer method, the hole wall of the excavation hole may collapse before the packer is expanded. In this case, the adhesion between the packer and the ground is reduced, and the penetration source is reduced.

One aspect of the present disclosure is to provide a sealant, a sealant article, and a chemical injection method capable of expanding the permeation source and suppressing the collapse of the hole wall.

One aspect of the present disclosure is a sealant used in a chemical injection method, which contains a gel of aluminum hydroxide, has a specific gravity in the range of 1.05 to 1.30, and has a pH of 4 to 11.1. A sealant that is within range. According to the sealing agent, which is one aspect of the present disclosure, the permeation source can be expanded and the collapse of the hole wall can be suppressed.

Another aspect of the present disclosure is a sealant product used in a chemical injection method, which comprises a plurality of unit agents to be mixed at the time of use, and at least one of the unit agents contains trivalent aluminum ions. The sealant formed by mixing the plurality of unit agents contains a gel of aluminum hydroxide, the specific gravity of the sealant is in the range of 1.05 to 1.30, and the pH of the sealant immediately after mixing. Is a sealant product in the range of 4 to 11.1. According to the sealant product, which is another aspect of the present disclosure, the penetration source can be expanded and the collapse of the hole wall can be suppressed.

Another aspect of the present disclosure is a sealant used in a chemical injection method, which is a sealant containing a highly water-absorbent resin and water. According to the sealing agent, which is another aspect of the present disclosure, the permeation source can be expanded and the collapse of the hole wall can be suppressed.

Another aspect of the present disclosure is a chemical injection method of injecting a chemical solution into the ground and improving the ground by solidifying the injected chemical solution, in which an drilling hole is formed in the ground and an injection pipe is formed in the drilling hole. Is inserted, and a sealant is filled between the injection pipe and the hole wall of the drilling hole, and the chemical solution having a pH of less than 4 is discharged from the injection port of the injection tube, and the chemical solution is discharged. At least a part of the sealant is dissolved and penetrates into the ground, and the sealant contains a gel of aluminum hydroxide, has a specific gravity in the range of 1.05 to 1.30, and has a pH of 4 to 11. This is a chemical injection method within the range of 1. According to the chemical injection method, which is another aspect of the present disclosure, the permeation source can be expanded and the collapse of the hole wall can be suppressed.

Another aspect of the present disclosure is a chemical injection method of injecting a chemical solution into the ground and improving the ground by solidifying the injected chemical solution, in which an excavation hole is formed in the ground and an injection pipe is formed in the excavation hole. Is inserted, and a sealant is filled between the injection pipe and the hole wall of the excavation hole, and the chemical solution having a pH of less than 4 is discharged from the injection port of the injection tube, and the chemical solution is discharged. At least a part of the sealant is contracted and penetrates into the ground, and the sealant is a chemical injection method containing a highly water-absorbent resin and water. According to the chemical injection method, which is another aspect of the present disclosure, the permeation source can be expanded and the collapse of the hole wall can be suppressed.

It is explanatory drawing which shows the method of the hole wall collapse test. It is explanatory drawing which shows the example of the chemical solution injection method.

An embodiment of the present disclosure will be described.
1. 1. First Sealing Agent The first sealing agent is used in the chemical injection method. The chemical injection method is not particularly limited, and examples thereof include a strainer method, a seal grout type double packer method, and a ground packer method double packer method. The first sealant can be filled, for example, between the injection pipe and the hole wall of the borehole. The injection tube may be composed of an injection outer tube and an injection inner tube, or may be an injection tube having any other structure.

The first sealant comprises a gel of aluminum hydroxide. The specific weight of the first sealant is in the range of 1.05 to 1.30. The pH of the first sealant is in the range of 4-11.1. When the specific gravity and pH of the first sealant are within these ranges, the effect of suppressing the collapse of the hole wall of the excavation hole is high. Further, since the specific gravity and pH of the first sealant are within these ranges, the first sealant is easily dissolved when the chemical solution is discharged from the injection tube. When the first sealant is dissolved, the chemical solution discharged from the injection tube can permeate the ground over a wide range. As a result, the source of penetration can be expanded. The dosage form of the first sealant is, for example, liquid, slurry, suspension or the like.

The viscosity of the first sealant is preferably 100 mPa · s or more. This viscosity is a value measured under the following conditions.
Measuring equipment: BII type viscometer (manufactured by Toki Sangyo)
Rotor size: No. 3
Rotor speed: 60 rpm
Temperature: 20 ° C
When the viscosity of the first sealant is 100 mPa · s or more, the effect of suppressing the collapse of the hole wall of the excavation hole is even higher. Further, when the viscosity of the first sealant is 100 mPa · s or more, the first sealant is more easily dissolved in the chemical solution discharged from the injection tube. As a result, the penetration source can be further expanded.

The first sealant may further contain, for example, a surfactant, sodium silicate, and the like. When the first sealant contains a surfactant, the viscosity of the first sealant increases, so that the pore wall can be firmly held. Further, when the first sealant contains a surfactant, material separation in the first sealant can be suppressed. Further, when the first sealant contains a surfactant, it is possible to prevent the solubility of the first sealant from decreasing with the passage of time.

Examples of the surfactant include carboxymethyl cellulose, alkylallyl sulfonate, alkylammonium salt and the like. Moreover, you may use the mixture of 2 or more types selected from these.

When the first sealant contains sodium silicate, the viscosity of the first sealant increases, so that the pore wall can be firmly held. Further, when the first sealant contains sodium silicate, material separation in the first sealant can be suppressed. Further, when the first sealant contains sodium silicate, the first sealant itself gels after a certain period of time, so that the pore wall can be held more firmly.

2. Sealing agent supplies Sealing agent supplies are used in the chemical injection method. The chemical injection method is not particularly limited, and examples thereof include a strainer method, a seal grout type double packer method, and a ground packer method double packer method.

Sealing agent supplies include multiple unit agents. By mixing a plurality of unit agents, a first sealant is produced. The first sealant is a mixture of a plurality of unit agents, or one produced from a mixture. The plurality of unit agents are, for example, separated from each other when the first sealant is not used and are mixed at the time of use.

The number of unit agents may be two or three or more. Examples of the dosage form of the unit agent include liquid, slurry, and powder. The dosage form of the first sealant is, for example, liquid, slurry, suspension or the like.

At least one of the plurality of unit agents contains trivalent aluminum ions. At least one unit agent containing trivalent aluminum ions will be referred to as unit agent A below. The unit agent A contains, for example, an aluminum salt. Examples of the aluminum salt include aluminum sulfate, aluminum nitrate, aluminum chloride, alum, sodium aluminate and the like.

At least one of the plurality of unit agents may contain, for example, a component that adjusts the pH of the first sealant within the range of 4 to 11.1 (hereinafter, referred to as a pH adjusting component). Examples of the pH adjusting component include alkaline substances such as sodium aluminate, sodium hydroxide, potassium hydroxide, and sodium metasilicate. Examples of the pH adjusting component include acidic substances such as aluminum sulfate, sulfuric acid, hydrochloric acid, and nitric acid. The pH adjusting component can be added to, for example, any one or more unit agents other than the unit agent A among the plurality of unit agents.

At least one of the plurality of unit agents may contain, for example, a surfactant. Examples of the unit agent containing a surfactant include unit agent A. When any of the unit agents contains a surfactant, the viscosity of the first sealant increases, so that the pore wall can be firmly held. Further, when any of the unit agents contains a surfactant, material separation in the first sealant can be suppressed. Further, when any of the unit agents contains a surfactant, it is possible to prevent the solubility of the first sealant from decreasing with the passage of time. In particular, when the unit agent A contains a surfactant, the surface of the sol particles when aluminum hydroxide is formed can be protected. As a result, it is possible to further suppress the decrease in the solubility of the first sealant with the passage of time.

Examples of the surfactant include carboxymethyl cellulose, alkylallyl sulfonate, alkylammonium salt and the like. Moreover, you may use the mixture of 2 or more types selected from these.

At least one of the plurality of unit agents may contain, for example, sodium silicate. Examples of the unit agent containing sodium silicate include any one or more unit agents other than the unit agent A. When the unit agent contains sodium silicate, the viscosity of the first sealant increases, so that the pore wall can be firmly held. Further, when the unit agent contains sodium silicate, material separation in the first sealant can be suppressed. Further, when the unit agent contains sodium silicate, the first sealant itself gels after a certain period of time, so that the pore wall can be held more firmly.

The first sealant, which is a mixture of a plurality of unit agents, comprises a gel of aluminum hydroxide. The specific weight of the first sealant is in the range of 1.05 to 1.30. The pH of the first sealant immediately after mixing is in the range of 4 to 11.1. When the specific gravity and pH of the first sealant are within these ranges, the effect of suppressing the collapse of the hole wall of the excavation hole is high. Further, since the specific gravity and pH of the first sealant are within these ranges, the first sealant is easily dissolved when the chemical solution is discharged from the injection tube. When the first sealant is dissolved, the chemical solution discharged from the injection tube can permeate the ground over a wide range. As a result, the source of penetration can be expanded.

The first sealant can be filled, for example, between the injection tube and the hole wall of the borehole. The injection tube may be composed of an injection outer tube and an injection inner tube, or may be an injection tube having any other structure.

The viscosity of the first sealant immediately after mixing is preferably 100 mPa · s or more. This viscosity is a value measured under the following conditions.
Measuring equipment: BII type viscometer (manufactured by Toki Sangyo)
Rotor size: No. 3
Rotor speed: 60 rpm
Temperature: 20 ° C
When the viscosity of the first sealant immediately after mixing is 100 mPa · s or more, the effect of suppressing the collapse of the hole wall of the excavation hole is even higher. Further, when the viscosity of the first sealant immediately after mixing is 100 mPa · s or more, the first sealant is more easily dissolved in the chemical solution discharged from the injection tube. As a result, the penetration source can be further expanded.

3. 3. Second Sealing Agent The second sealing agent is used in the chemical injection method. The chemical injection method is not particularly limited, and examples thereof include a strainer method, a seal grout type double packer method, and a ground packer method double packer method. The second sealant can be filled, for example, between the injection tube and the hole wall of the borehole. The injection tube may be composed of an injection outer tube and an injection inner tube, or may be an injection tube having any other structure.

The second sealant contains a highly absorbent resin and water. At least a part of the highly water-absorbent resin absorbs water and is in a swollen state.
The second sealant has a high effect of suppressing the collapse of the hole wall of the excavation hole. Further, when the chemical solution is discharged from the injection tube, the second sealant tends to shrink. When the second sealant contracts, the chemical solution discharged from the injection tube can permeate the ground over a wide range. As a result, the source of penetration can be expanded.

As the super absorbent polymer, a synthetic polymer superabsorbent polymer is preferable. As the synthetic polymer-based superabsorbent polymer, a polyacrylate-based superabsorbent resin is preferable. As the polyacrylate-based superabsorbent polymer, an acrylic acid polymer partially sodium salt crosslinked product is preferable.

When the second sealant contains a synthetic polymer-based super absorbent polymer, the effect of suppressing the collapse of the hole wall of the drilled hole is even higher. Further, when the second sealant contains a synthetic polymer superabsorbent polymer, the second sealant is more likely to shrink when the chemical solution is discharged from the injection tube.

When the second sealing agent contains a polyacrylate-based superabsorbent polymer, the effect of suppressing the collapse of the hole wall of the drilled hole is even higher. Further, when the second sealant contains a polyacrylate-based superabsorbent polymer, the second sealant is more likely to shrink when the chemical solution is discharged from the injection tube.

When the second sealant contains an acrylic acid polymer partially sodium salt crosslinked product, the effect of suppressing the collapse of the hole wall of the excavation hole is particularly high. Further, when the second sealant contains an acrylic acid polymer partially sodium salt crosslinked product, the second sealant is particularly liable to shrink when the chemical solution is discharged from the injection tube.

The second sealant preferably contains 1000 parts by mass of water and 1 to 100 parts by mass of a highly water-absorbent resin. It is more preferable that the second sealant contains 1000 parts by mass of water and 1.5 to 20 parts by mass of a highly water-absorbent resin.

When the second sealant contains 1 part by mass or more of a highly water-absorbent resin with respect to 1000 parts by mass of water, the effect of suppressing the collapse of the hole wall of the excavation hole is high.
When the second sealant contains 1.5 parts by mass or more of a highly water-absorbent resin with respect to 1000 parts by mass of water, the effect of suppressing the collapse of the hole wall of the excavation hole is even higher.

When the second sealant contains 100 parts by mass or less of a highly water-absorbent resin with respect to 1000 parts by mass of water, the production cost of the second sealant can be reduced.
When the second sealant contains 20 parts by mass or less of a highly water-absorbent resin with respect to 1000 parts by mass of water, the production cost of the second sealant can be further reduced.

The dosage form of the second sealant is, for example, liquid, slurry, suspension or the like. The second sealant may further contain components other than water and the highly water-absorbent resin.
4. Chemical injection method The chemical injection method of the present disclosure is a method of injecting a chemical into the ground and improving the ground by solidifying the injected chemical. The chemical injection method of the present disclosure may be, for example, a strainer method, a seal grout type double packer method, a ground packer type double packer method, or any other chemical injection method.

In the chemical injection method of the present disclosure, an excavation hole is formed in the ground. Next, the injection pipe is inserted into the drilling hole, and a sealing agent is filled between the injection pipe and the hole wall of the drilling hole. This state can be realized, for example, by filling the drilling hole with a sealant and then inserting the injection pipe into the drilling hole. Further, the above state can be realized, for example, by inserting the injection pipe into the drilling hole and then filling the space between the injection pipe and the hole wall of the drilling hole with a sealing agent. The sealing agent used in the chemical injection method of the present disclosure is any one of the above-mentioned "1. First sealing agent", the above-mentioned "2. Sealing agent supplies", and the above-mentioned "3. Second sealing agent". It is the one mentioned in the section.

Next, the chemical solution having a pH of less than 4 is discharged from the injection port of the injection tube. Since the first sealant used in the chemical injection method of the present disclosure is easily dissolved by the chemical solution and the second sealant used in the chemical injection method of the present disclosure is easily contracted by the chemical solution, the chemical solution is discharged from the injection tube. At that time, at least a part of the sealant dissolves or shrinks. When the sealant dissolves or shrinks, the chemical solution discharged from the injection tube can permeate the ground over a wide range. As a result, the source of penetration can be expanded.

An example of the chemical injection method is shown in FIG. In STEP-1, a drilling hole 101 is formed in the ground 100, an injection pipe 103 is inserted into the drilling hole 101, and a sealant 107 is filled between the injection pipe 103 and the hole wall 105 of the drilling hole 101. is there. The injection pipe 103 includes an injection port 109 and a ground packer 111.

In STEP-2, the ground packer 111 is bulged and brought into close contact with the hole wall 105. In STEP-3, the chemical solution 113 having a pH of less than 4 is discharged from the injection port 109. When the sealant 107 is the first sealant, the chemical solution 113 discharged from the injection port 109 dissolves the sealant 107 near the injection port 109. When the sealant 107 is the second sealant, the sealant 107 near the injection port 109 is shrunk. In STEP-4, the chemical solution 113 in which the sealing agent 107 is dissolved or shrunk permeates the ground 100. In STEP-5, the chemical solution 113 sufficiently spreads on the ground 100 and solidifies to form the improved body 115.

5. Examples corresponding to the chemical injection method using the first sealant (1) Manufacture of sealant supplies A of Examples 1 to 8 and 11 to 14 and Comparative Examples 2 to 6 by blending the components shown in Table 1. Liquid and liquid B were produced. Solution A and solution B correspond to unit agents, respectively. The combination of liquid A and liquid B corresponds to the sealant product. In addition, the components shown in Table 1 were blended to produce solutions A, B, and C of Examples 9 and 10. Solution A, solution B, and solution C correspond to unit agents, respectively. The combination of solution A, solution B, and solution C corresponds to the sealant product.

表１における配合量の単位は質量部である。表１における「Al₂(SO₄)₃」は、硫酸アルミニウム (北陸化成(株)製、Al₂O₃：12%)を意味する。表１における「活性剤」は、界面活性剤を意味する。実施例１１のＡ液に配合されている界面活性剤はカルボキシメチルセルロース(信越化学工業(株)製、製品名:アスカクリーン)である。実施例１２のＡ液に配合されている界面活性剤はアルキルアリルスルホン酸塩である。実施例１３のＡ液に配合されている界面活性剤はアルキルアンモニウム塩である。実施例１４のＡ液に配合されている界面活性剤は、アルキルアリルスルホン酸塩(花王(株)製、製品名:ビスコトップ100A)と、アルキルアンモニウム塩(花王(株)製、製品名:ビスコトップ100B)とを質量比１：１で混合したものである。

The unit of the blending amount in Table 1 is a mass part. _{“Al 2} (SO ₄ ) ₃ ” in Table 1 means aluminum sulfate (manufactured by Hokuriku Kasei Co., Ltd., Al ₂ O ₃ : 12%). "Activator" in Table 1 means a surfactant. The surfactant contained in the solution A of Example 11 is carboxymethyl cellulose (manufactured by Shin-Etsu Chemical Co., Ltd., product name: Asuka Clean). The surfactant contained in the solution A of Example 12 is an alkylallyl sulfonate. The surfactant contained in the solution A of Example 13 is an alkylammonium salt. The surfactants contained in the solution A of Example 14 are alkylallyl sulfonate (manufactured by Kao Corporation, product name: Viscotop 100A) and alkylammonium salt (manufactured by Kao Corporation, product name:). It is a mixture of Biscotop 100B) and a mass ratio of 1: 1.

"NaAlO _2" in Table 1, sodium aluminate (Hokuriku Chemical Co., Ltd., product _{name: AS17, Al 2 O 3:} 19%) means. "No. 5" in Table 1 means No. 5 sodium silicate (manufactured by Fuji Chemical Co., Ltd., SiO ₂ : 25.5%, Na ₂ O: 7%).

For Examples 1 to 8 and 11 to 14, and Comparative Examples 2 to 6, the liquid A was mixed with the liquid B, and the mixture was further stirred to produce a sealant. This sealant corresponds to the first sealant. The sealants of Examples 1-8 and 11-14 contain a gel of aluminum hydroxide and are a viscous suspension.

Further, in Examples 9 and 10, solution C was mixed with the stirred solution A, then solution B was mixed, and the mixture was further stirred to produce a sealant. This sealant corresponds to the first sealant. The sealants of Examples 9 and 10 contain a gel of aluminum hydroxide and are a viscous suspension.

Further, the following components were mixed to produce a sealant of Comparative Example 1.
Cement: 62.1g
Bentonite: 15.5g
Water: 222.4g
(2) Physical Properties of Sealing Agent The pH, specific weight, and viscosity of the sealing agent were measured for each Example and each Comparative Example. For Examples 1 to 8 and 11 to 14 and Comparative Examples 2 to 6, measurements were carried out immediately after mixing and stirring the solutions A and B. For Examples 9 and 10, the measurement was performed immediately after mixing and stirring the solutions A, B, and C. Both measurements were performed at 20 ° C. The specific gravity is measured by measuring 200 ml of the sealant using a measuring cylinder and measuring the mass of the measured sealant. The method for measuring the viscosity is the method described in the above-mentioned "1. Sealing agent" and the above-mentioned "2. Sealing agent supplies". The measurement results are shown in Table 2.

表２には、シール剤におけるAl₂O₃濃度及びSiO₂濃度を併せて示す。

Table 2 also shows the Al ₂ O ₃ concentration and the SiO ₂ concentration in the sealant.

(3) Hole wall collapse test A hole wall collapse test was conducted on the sealants of each Example and each Comparative Example as follows. As shown in STEP-1 of FIG. 1, a cubic acrylic water tank 1 was prepared. The dimensions of the water tank 1 are 20 cm in length, width, and height. The water tank 1 is open on its upper surface.

Further, as shown in STEP-1 of FIG. 1, a half-split pipe 3 was prepared. The half-split pipe 3 has a shape in which a hollow cylinder is divided into two by a cross section parallel to the axial direction thereof. As shown in STEP-1 of FIG. 1, the half-split pipe 3 was brought into contact with one side surface 5 of the water tank 1 from the inside. At this time, the divided surface 7 of the half-split pipe 3 was in contact with the side surface 5. The axial direction of the half-split pipe 3 is the vertical direction. A space 9 surrounded by the half pipe 3 and the side surface 5 was created.

Next, the portion of the water tank 1 excluding the space 9 was filled with No. 6 Kay sand 11. At this time, the space 9 was prevented from entering the No. 6 Kay sand 11. The relative density of No. 6 Kay sand 11 is 50%. The height from the bottom surface of the water tank 1 to the surface of the No. 6 silica sand 11 is 15 cm.

Next, as shown in STEP-2 of FIG. 1, the space 9 was filled with the sealant 13 from above. Next, as shown in STEP-3 of FIG. 1, the half-split pipe 3 was pulled up. At this time, the surface of the No. 6 silica sand 11 that was in contact with the half-split pipe 3 (hereinafter referred to as the hole wall 15) is in a state of facing the outer peripheral surface of the sealant 13.

The degree of collapse of the hole wall 15 after pulling up the half-split pipe 3 was judged according to the following criteria. The results are shown in Table 2 above.
◎: Does not collapse.

◯: The sand slowly settles and the hole wall 15 collapses slightly, but the hole wall 15 is almost retained.
Δ: The hole wall 15 slowly collapses, and the hole wall 15 cannot be held over time.
X: The hole wall 15 collapses.

ND: The space 9 cannot be filled with the sealant 13 because the viscosity is excessively high.
With the sealant of each example, the hole wall 15 was difficult to collapse. In the sealants of Comparative Examples 2 to 6, the hole wall 15 was easily disintegrated, or the result was "ND". The reason why the pore wall 15 is likely to collapse in Comparative Examples 4 to 6 is that the pH of the sealant is excessively low or too high, so that a gel of aluminum hydroxide is not sufficiently formed and the viscosity of the sealant is low. It is presumed to be.
(4) Solubility test
Solubility tests were conducted on the sealants of Examples 2, 10 and 14 and Comparative Example 1 as follows. The sealant was allowed to stand for 2 days after preparation and cured. Next, 1 g of the sealant and 99 g of the chemical solution were mixed and stirred for 2 hours. The mixing ratio of the sealant and the chemical solution is a general mixing ratio when the sealant is used in the chemical solution injection method. The basic composition of the chemical solution used is as follows.

Colloidal silica: 44g
No. 5 sodium silicate: 274 g
Industrial dilute sulfuric acid: Approximately 40 g
Water: 736g
The pH of the chemical solution was set to any of 1, 2, 3, and 4 by adjusting the amount of industrial dilute sulfuric acid.

Next, the sediment was separated from the mixture of the sealant and the chemical solution by centrifugation at 3500 rpm for 10 minutes. The sediment is mainly composed of an aluminum hydroxide gel that remains undissolved, silica gel generated by the reaction of the chemical solution, and the like. Next, the reduction rate X (%) of the aluminum hydroxide gel was calculated by the following formula (1).

Equation (1) X = ((W ₀ − W ₁ ) / W ₀ ) × 100
In formula (1), W ₁ is the mass of the sediment. W ₀ is the mass of the aluminum hydroxide gel contained in the sealant before being mixed with the chemical solution. Table 3 shows the types of sealants, the pH of the chemical solution, and the value of the reduction rate X.

実施例２、１０、１４のシール剤では、ｐＨが４未満の薬液を使用すると、減少率Ｘが大きくなった。すなわち、実施例２、１０、１４のシール剤は、ｐＨが４未満の薬液を加えると、溶解し易かった。比較例１のシール剤では、薬液のｐＨによらず、減少率Ｘが小さいか、シール剤がゲル化するという結果であった。
６．第２のシール剤を使用する薬液注入工法に対応する実施例
（１）シール剤の製造
表４に示す配合で水と高吸水性樹脂とを混合し、実施例１５〜１８のシール剤を製造した。実施例１５〜１８のシール剤は第２のシール剤に対応する。

In the sealants of Examples 2, 10 and 14, when a chemical solution having a pH of less than 4 was used, the reduction rate X became large. That is, the sealants of Examples 2, 10 and 14 were easily dissolved when a chemical solution having a pH of less than 4 was added. In the sealant of Comparative Example 1, the result was that the reduction rate X was small or the sealant gelled regardless of the pH of the chemical solution.
6. Examples corresponding to the chemical injection method using the second sealant (1) Production of sealant Water and highly water-absorbent resin are mixed with the formulation shown in Table 4 to produce the sealants of Examples 15 to 18. did. The sealants of Examples 15-18 correspond to the second sealant.

表４における配合量の単位は質量部である。高吸水性樹脂は、三洋化成工業株式会社製の商品名Geosapである。Geosapは、アクリル酸重合体部分ナトリウム塩架橋物である。アクリル酸重合体部分ナトリウム塩架橋物は、合成ポリマー系の高吸水性樹脂に対応し、ポリアクリル酸塩系の高吸水性樹脂に対応する。

The unit of the blending amount in Table 4 is a mass part. The super absorbent polymer is a trade name Geosap manufactured by Sanyo Chemical Industries, Ltd. Geosap is a partially sodium salt crosslinked product of an acrylic acid polymer. The acrylic acid polymer partially sodium salt crosslinked product corresponds to a synthetic polymer-based superabsorbent polymer and a polyacrylate-based superabsorbent polymer.

In the sealants of Examples 15 to 18, the highly water-absorbent resin absorbs water and is in a swollen state. The sealants of Examples 15-18 have a slurry dosage form.
(2) Shrinkage Test A shrinkage test was conducted on the sealants of Examples 15 to 18 as follows. 10 g of the sealant and 90 g of the chemical solution were mixed and stirred for 30 minutes. The mixing ratio of the sealant and the chemical solution is a general mixing ratio when the sealant is used in the chemical solution injection method. The basic composition of the chemical solution used is as follows.

Colloidal silica: 44g
No. 5 sodium silicate: 274 g
Industrial dilute sulfuric acid: Approximately 40 g
Water: 736g
The pH of the chemical solution was set to 3.0 by adjusting the amount of industrial dilute sulfuric acid.

Next, the mixed solution of the sealant and the chemical solution was suction-filtered using a filter paper. The filter paper used was a 5C filter paper manufactured by ADVANTEC. Next, the mass w of the filtration residue was measured.
Next, the reduction rate Y (%) of the sealant was calculated by the following formula (2).

Equation (2) Y = (1- (w / 10)) × 100
The rate of decrease Y is shown in Table 4 above. The reduction rate Y was large in any of the sealants of Examples 15 to 18. That is, the sealants of Examples 15 to 18 tended to shrink when the chemical solution was added.
(3) Hole wall collapse test A hole wall collapse test was performed on the sealants of Examples 15 to 18. The method of the hole wall collapse test is basically the same as the method described above. However, when the No. 6 Kay sand 11 was packed in the portion of the water tank 1 excluding the space 9, water was added together with the No. 6 Kay sand 11. In the portion of the water tank 1 excluding the space 9, the water surface was set to be higher than the surface of the No. 6 silica sand 11.

The results of the wall collapse test are shown in Table 4 above. When any of the sealants of Examples 15 to 18 was used, the hole wall 15 was unlikely to collapse. When the sealants of Examples 16 to 18 were used, the hole wall 15 was more difficult to collapse. When the sealants of Examples 17 to 18 were used, the hole wall 15 was particularly difficult to collapse.

(4) Measurement of specific gravity The specific gravity of the sealants of Examples 15 to 18 was measured. The specific gravity is measured by measuring 100 ml of the sealant using a measuring cylinder and measuring the mass of the measured sealant. The measurement results of the specific gravity are shown in Table 4 above.

7. Other Embodiments Although the embodiments of the present disclosure have been described above, the present disclosure is not limited to the above-described embodiments, and can be implemented in various modifications.

(1) A plurality of functions possessed by one component in the above embodiment may be realized by a plurality of components, or one function possessed by one component may be realized by a plurality of components. .. Further, a plurality of functions possessed by the plurality of components may be realized by one component, or one function realized by the plurality of components may be realized by one component. Further, a part of the configuration of the above embodiment may be omitted. In addition, at least a part of the configuration of the above embodiment may be added or replaced with the configuration of the other above embodiment. It should be noted that all aspects included in the technical idea specified from the wording described in the claims are embodiments of the present disclosure.

(2) In addition to the above-mentioned chemical injection method, sealant, and sealant supplies, the present disclosure can be realized in various forms such as a product containing a sealant as a constituent element and a ground improvement method.

1 ... Water tank, 3 ... Half pipe, 5 ... Side surface, 7 ... Divided surface, 9 ... Space, 11 ... No. 6 silica sand, 13 ... Sealing agent, 15 ... Hole wall, 100 ... Ground, 101 ... Drilling hole, 103 ... Injection pipe, 105 ... Hole wall, 107 ... Sealing agent, 109 ... Injection port, 111 ... Ground packer, 113 ... Chemical solution, 115 ... Improved product

Claims (8)

It is a sealant product used in the chemical injection method.
Contains multiple unit agents that are mixed during use
At least one of the unit agents contains trivalent aluminum ions.
The sealing agent formed by mixing the plurality of unit agents is
Contains a gel of aluminum hydroxide,
The specific gravity of the sealant is in the range of 1.05 to 1.30.
PH of the sealant immediately after mixing Ri range der of from 4 to 11.1,
The viscosity of the sealant Ru der than 100 mPa · s sealant goods immediately after mixing. It is a chemical injection method that improves the ground by injecting a chemical solution into the ground and solidifying the injected chemical solution.
An excavation hole is formed in the ground,
An injection pipe is inserted into the excavation hole, and a sealant is filled between the injection pipe and the hole wall of the excavation hole.
The chemical solution having a pH of less than 4 is discharged from the injection port of the injection tube.
The chemical solution dissolves at least a part of the sealant and penetrates into the ground.
The sealant is
Contains a gel of aluminum hydroxide,
The specific gravity is in the range of 1.05 to 1.30.
A chemical injection method in which the pH is in the range of 4 to 11.1. The chemical injection method according to claim 2.
A chemical injection method in which the viscosity of the sealant is 100 mPa · s or more. It is a chemical injection method that improves the ground by injecting a chemical solution into the ground and solidifying the injected chemical solution.
An excavation hole is formed in the ground,
An injection pipe is inserted into the excavation hole, and a sealant is filled between the injection pipe and the hole wall of the excavation hole.
The chemical solution having a pH of less than 4 is discharged from the injection port of the injection tube.
The chemical solution shrinks at least a part of the sealant and penetrates into the ground.
The sealing agent is a chemical injection method containing a highly water-absorbent resin and water. The chemical injection method according to claim 4 , wherein the chemical solution injection method is used.
The superabsorbent polymer is a synthetic polymer-based superabsorbent polymer, which is a chemical injection method. The chemical injection method according to claim 4 or 5.
The superabsorbent polymer is a polyacrylate-based superabsorbent polymer, which is a chemical injection method. The chemical injection method according to any one of claims 4 to 6.
The super absorbent polymer is a chemical injection method containing a partially sodium salt crosslinked product of an acrylic acid polymer. The chemical injection method according to any one of claims 4 to 7.
The sealant is a chemical injection method containing 1000 parts by mass of water and 1 to 100 parts by mass of the highly water-absorbent resin.

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