JP2010077264A - Gypsum type soil stabilizer and method for manufacturing stabilized soil - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a gypsum type soil stabilizer which can reduce the water permeability of stabilized soil to prevent the soil from coming to mud again and a method for manufacturing stabilized soil which can produce stabilized soil capable of reducing the water permeability to prevent the soil from coming to mud again. <P>SOLUTION: The gypsum type soil stabilizer contains a curing material constituted of gypsum hemihydrate as the major component and powdered dry clay. The method for manufacturing stabilized soil includes mixing the gypsum type soil stabilizer containing a curing material constituted of gypsum hemihydrate as the major component and powdered dry clay and water with soil to be treated. The use of the gypsum type soil stabilizer or the stabilized soil manufactured with the use of the method for manufacturing stabilized soil can reduce the water permeability to prevent the soil from coming to mud again. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a gypsum-based soil stabilization treatment material used for stabilizing soil quality of soil used for backfilling or backfilling in spaces or underground cavities between a building structure and its surrounding ground, and soil The present invention relates to a method for producing a soil-stabilized soil in which the soil is produced stably.

  Conventionally, hydraulic hardening materials such as cement and lime have been mainly used as the hardening material used for the soil stabilization treatment. Soil-stabilized soils produced using such hardeners show strong alkalinity, and the hardeners contain a small amount of harmful substances such as hexavalent chromium. Since it cannot be reused when it is re-excavated later, it often has to be discarded as industrial waste.

  Conventionally, in order to prevent alkalinization during the soil stabilization treatment, development of a hardener mainly composed of gypsum that exhibits neutrality has been promoted. Such gypsum-based hardeners are also attracting attention in terms of their fast-curing properties, and have been used to improve soil quality for the purpose of improving the handling properties of soils that form a liquid with a high water content such as soft soils and mud soils. (First prior art).

  In addition, a soil-stabilized soil produced using a gypsum-based hardener may re-mudize due to the dissolution of calcium (Ca) content of gypsum, which is the main component of the hardener, in rainwater and groundwater. Although it was a concern, for example, a polymer agent is added to the hardened material, or as described in Patent Documents 1 and 2, blast furnace slag, fly ash (coal ash), or magnesium oxide (MgO). There was a soil-stabilized soil in which the dissolution of calcium (Ca) content of gypsum in this hardened material was suppressed by adding an alkaline hydraulic auxiliary such as (second conventional technology) ).

  Here, in the soil-stabilized soil according to the second prior art, as described above, a polymer agent and a hydraulic auxiliary agent are added to the gypsum-based hardener used for producing the soil-stabilized soil. Although it is designed to suppress the dissolution of calcium by adding, these polymer agents and hydraulic auxiliary agents generate new compounds by causing a chemical reaction with the gypsum component. In addition, the properties of the gypsum component are not changed so that the solubility of the calcium content is lowered.

  That is, these polymer agents and hydraulic auxiliary agents have their solubility lower than that of gypsum, so that when they are dissolved in water as a solvent, water is brought closer to saturation than when gypsum is dissolved. Thus, this only acts to lower the overall solubility of the gypsum-based hardener to which the polymer agent or hydraulic auxiliary is added.

For example, magnesium oxide (MgO) as a hydraulic auxiliary agent produces magnesium hydroxide (Mg (OH) ₂ ) by chemical reaction with water, and this magnesium hydroxide has a solubility in water of 0.0012 g. By being / 100 g, it acts to reduce the overall solubility of the gypsum-based hardener, including gypsum having a solubility in water of 0.208 g / 100 g. Thereby, magnesium oxide (MgO) suppresses dissolution of calcium content of gypsum in the gypsum-based hardener.
JP 2003-251321 A JP 2004-278133 A

  However, the soil-stabilized soil according to the first and second prior arts as described above has higher water permeability than the surrounding ground after being placed in the viscous ground, so that rainwater and groundwater can There was a problem that re-mudging would be caused because the soil flowed intensively in the soil.

That is, hemihydrate gypsum (CaSO ₄ · 1 / 2H ₂ O) as a main component of the gypsum-based hardener used for producing the soil-stabilized soil according to the first and second prior arts as described above, As a result of the hydration reaction with water, a crystalline structure of porous dihydrate gypsum (CaSO ₄ .2H ₂ O) is formed in a short time. This dihydrate gypsum has a water permeability coefficient of about 1 × 10 ⁻³ to 1 × 10 ⁻⁴ cm / s, and has a relatively high water permeability as compared with soil to be subjected to soil stabilization treatment. For this reason, the soil-stabilized soil mixed with the gypsum hardener has higher water permeability than the surrounding ground when the generated soil is reused.

Here, when it is necessary to particularly distinguish the powder state before the hydration reaction with water and the solidified state after the hydration reaction, the gypsum is water as described above. to distinguish the way call it before hydration "hemihydrate gypsum _{(CaSO 4 · 1 / 2H 2} O) ," by way call it "dihydrate gypsum _(CaSO 4 · _2H 2 O)" after the hydration reaction However, in this specification, when there is no need to call each other or when it is clear which state is present, no particular calling is made.

For example, a soil-stabilized soil that has been subjected to a stabilization treatment by mixing a gypsum hardener with a viscous soil has a permeability coefficient of 1 × 10 ⁻⁶ in the viscous soil in a state before the gypsum hardener is mixed. whereas was about ~1 × ¹⁰ -7 cm / s, permeability rises to about 1 × ¹⁰ -5 cm / s.

  Therefore, when soil-stabilized soil mixed with such gypsum-based hardeners is placed in a viscous ground, its water permeability is higher than that of the surrounding ground, so that rainwater and groundwater can flow into the soil-stabilized soil. There was a problem that it would begin to flow intensively.

  For this reason, the soil-stabilized soil mixed with gypsum hardener is exposed to a large amount of rainwater and groundwater flowing through the soil-stabilized soil due to such high water permeability. Because the calcium content of gypsum, which is the main component of the gypsum hardener, dissolves and flows out in the large amount of rainwater and groundwater that flows through this soil-stabilized soil, this soil-stabilized treatment finally. There was a problem that it would cause re-mudging of the soil.

  In particular, in the soil-stabilized soil according to the second prior art described above, as described above, the gypsum-based hardener used for producing this soil-stabilized soil contains a polymer agent or hydraulic support. By adding the agent, it was designed to suppress the dissolution of the calcium component by utilizing the poor solubility of the hardened crystals, but since these auxiliary agents are dissolved in water, If it is intended to maintain sufficient suppression of calcium dissolution by molecular agents and hydraulic auxiliaries, the soil-stabilized soil must continue to maintain a large amount of this polymer or hydraulic auxiliaries. In spite of this, there was a problem that it was not possible to maintain such a state in practice.

  For example, the table of FIG. 19 shows that a paste prepared by mixing gypsum and water was added with magnesium oxide as a hydraulic auxiliary agent, solidified, and then immersed in still water for only 28 days. The volume reduction rate with respect to the initial volume was verified, and was verified for each different ratio of magnesium oxide to the total amount of gypsum and magnesium oxide. FIG. 20 is a diagram of this.

  When the solidified paste is immersed in still water, the calcium content of the gypsum and the magnesium oxide are dissolved, so that the volume decreases accordingly. Magnesium hydroxide produced by dissolving magnesium oxide in water has a lower solubility than gypsum, so when increasing the amount of magnesium oxide mixed in the paste, the amount of gypsum dissolved is small. However, when the amount of magnesium oxide is reduced, the amount of gypsum dissolved before reaching the saturated state increases.

  According to the verification results shown in FIGS. 19 and 20, when the mixing amount of magnesium oxide is 33%, the volume reduction rate per day is −0.368%. Therefore, it reaches -100% and the whole volume is lost. Further, even when the mixing amount of magnesium oxide is 44%, the volume reduction rate per day is −0.063%. % Volume will be lost.

  From these results, if the magnesium oxide is not contained in the soil-stabilized soil so as to exceed 50% of the total amount of the magnesium oxide and gypsum, the hydraulic property prevents the calcium content from dissolving. This means that the function as an auxiliary agent cannot be fully exhibited.

  On the other hand, the magnesium oxide in the soil treated with soil stabilization will be gradually discharged when exposed to a large amount of rainwater or groundwater passing through the soil treated with soil stabilization. When the function as a chemical agent is not fully exhibited, the amount of calcium in the gypsum that dissolves increases in an avalanche manner, and eventually this calcium passes through the soil-stabilized soil. It will run off with rainwater and groundwater. This has been found to have the same tendency even when a hydraulic auxiliary agent or polymer agent other than magnesium oxide is used. That is, if an auxiliary with low solubility is dissolved, it is no longer possible to prevent dissolution of calcium.

  Therefore, in the soil-stabilized soil according to the second prior art described above, a polymer agent and a hydraulic aid have been used. However, the polymer agent and the hydraulic aid contain a large amount of rainwater and groundwater. As a result, the amount of dissolved calcium increases in an avalanche manner, resulting in rainwater and groundwater flowing through the soil stabilized soil. As a result, there was a problem that eventually the soil stabilized soil was re-mudled.

  Therefore, in view of the above problems, the present invention reduces the water permeability of a soil-stabilized soil by physical action, suppresses the diffusion of calcium in the long term, and prevents re-mudging. It is an object of the present invention to provide a stable treatment material and a method for producing a soil-stabilized soil that can produce a soil-stabilized soil that has reduced water permeability and prevented re-mudging.

  In order to solve the above-mentioned problems, a gypsum-based soil stabilization treatment material according to the present invention is characterized by containing a hardener composed mainly of hemihydrate gypsum and powdered dry clay. is there.

  The gypsum-based soil stabilization material according to the present invention is characterized in that the dry clay is bentonite.

  The gypsum-based soil stabilization material according to the present invention is characterized in that the bentonite is contained in a weight ratio of 20% or more with respect to the hardened material.

  The gypsum-based soil stabilization material according to the present invention is characterized in that the bentonite is contained in a weight ratio of 40% to 100% with respect to the hardened material.

  The gypsum-based soil stabilization material according to the present invention is characterized in that the dry clay is a combination of bentonite and smectite group clay other than bentonite.

  The gypsum-based soil stabilization treatment material according to the present invention is characterized by containing a retarder that reduces the curing rate of the curing material.

  In addition, in order to solve the above problems, a method for producing a soil-stabilized soil according to the present invention includes a gypsum-based soil stabilization treatment containing a hardener composed mainly of hemihydrate gypsum and powdered dry clay. A material and water are produced by mixing and stirring the material to be treated.

Moreover, in order to solve the said subject, the manufacturing method of the soil stabilized soil by this invention is the following.
A slurry-shaped gypsum-based soil stabilization treatment material is prepared by mixing and stirring a hardener composed mainly of hemihydrate gypsum, dry powdered clay, and water,
The slurry-like gypsum-based soil stabilization treatment material is produced by mixing and stirring the treated soil.

  In order to solve the above problems, a method for producing a soil-stabilized treated soil according to the present invention comprises a hardened material mainly composed of hemihydrate gypsum, powdered dry clay, and water to be treated. It is characterized by being mixed and stirred.

Moreover, in order to solve the said subject, the manufacturing method of the soil stabilized soil by this invention is the following.
The soil to be treated is coarse-grained soil,
In the soil to be treated, a hardened material composed mainly of hemihydrate gypsum and powdered dry clay are mixed and stirred to produce a stable treated soil in the middle.
After the placement of the midway stable treated soil, water is supplied to the midway stabilized soil and hardened.

  The method for producing a soil-stabilized soil according to the present invention is characterized in that the dry clay is bentonite.

Moreover, the method for producing a soil-stabilized soil according to the present invention is characterized in that the amount of bentonite is 20% or more as a weight ratio with respect to the hardened material.
The content of bentonite is appropriately selected according to the water permeability of the surrounding ground.

The method for producing a soil-stabilized soil according to the present invention is characterized in that the amount of the bentonite is 40% to 100% as a weight ratio to the hardened material.
The content of bentonite is appropriately selected according to the water permeability of the surrounding ground.

The method for producing a soil-stabilized soil according to the present invention is characterized in that the dry clay is a combination of bentonite and a smectite group clay other than bentonite.
The content of each of the other smectite group clays other than bentonite and bentonite is appropriately selected according to the water permeability of the surrounding ground, and the other smectite group clay other than bentonite and bentonite As long as the mixing ratio is approximately neutral (pH≈7), it is sufficient.

  The method for producing a soil-stabilized soil according to the present invention is characterized in that the soil-stabilized soil contains a retarder that reduces the curing rate of the hardener.

According to such a gypsum-based soil stabilization material of the present invention,
By containing a hardener composed mainly of hemihydrate gypsum and powdered dry clay,
About the soil-stabilized soil manufactured using the said gypsum-type soil-stabilized material, the water permeability can be reduced and re-mudging can be prevented.
Furthermore, even if the surface of the soil stabilized soil is dissolved, the dissolved clay forms a film on the contact surface with the surrounding ground, and the dissolved calcium (Ca) content is adsorbed on the clay film. By suppressing external diffusion, re-mudging can be reliably prevented.

Moreover, according to the gypsum-based soil stabilization material of the present invention,
When the dry clay is bentonite,
Since the amount of decrease in water permeability of the soil-stabilized soil produced using this gypsum-based soil-stabilized material can be increased, re-mudging of the soil-stabilized soil can be reliably prevented.

Moreover, according to the gypsum-based soil stabilization material of the present invention,
By containing 20% or more of the bentonite as a weight ratio with respect to the hardener,
By appropriately selecting the content of the bentonite according to the water permeability of the surrounding ground,
Furthermore, the water permeability of the soil-stabilized soil can be reliably reduced, and re-mudification of the soil-stabilized soil can be prevented.

Moreover, according to the gypsum-based soil stabilization material of the present invention,
By containing 40% to 100% of the bentonite as a weight ratio to the hardener,
By appropriately selecting the content of the bentonite according to the water permeability of the surrounding ground,
Furthermore, the water permeability of the soil-stabilized soil can be reliably reduced, and re-mudification of the soil-stabilized soil can be prevented.

Moreover, according to the gypsum-based soil stabilization material of the present invention,
The dry clay is a combination of bentonite and other smectite clay other than bentonite,
The soil stabilization material can be neutralized,
Furthermore, the water permeability of the soil-stabilized soil can be reliably reduced, and re-mudification of the soil-stabilized soil can be prevented.

Moreover, according to the gypsum-based soil stabilization material of the present invention,
By containing a retarder that reduces the curing rate of the curing material,
Since the retarder acts to delay the curing of the soil-stabilized soil, the curing rate can be controlled by adjusting the amount of the retarder.

Moreover, according to the method for producing a soil-stabilized soil of the present invention,
By producing a gypsum-based soil stabilization treatment material containing a hardener composed mainly of hemihydrate gypsum and powdered dry clay, and water, mixing and stirring the treated soil,
Prevents material separation until curing,
Soil-stabilized soil that has reduced water permeability and prevented re-mudging can be produced.

Moreover, according to the method for producing a soil-stabilized soil of the present invention,
A slurry-shaped gypsum-based soil stabilization treatment material is prepared by mixing and stirring a hardener composed mainly of hemihydrate gypsum, dry powdered clay, and water,
By mixing and stirring the slurry-like gypsum-based soil stabilization treatment material to the treated soil,
Prevents material separation until curing,
Soil-stabilized soil that has reduced water permeability and prevented re-mudging can be produced.

Moreover, according to the method for producing a soil-stabilized soil of the present invention,
By mixing and stirring the hardened material composed mainly of hemihydrate gypsum, powdered dry clay, and water to the treated soil,
Prevents material separation until curing,
Soil-stabilized soil that has reduced water permeability and prevented re-mudging can be produced.

Moreover, according to the method for producing a soil-stabilized soil of the present invention,
The soil to be treated is coarse-grained soil,
In the soil to be treated, a hardened material composed mainly of hemihydrate gypsum and powdered dry clay are mixed and stirred to produce a stable treated soil in the middle.
After placing the midway stable treated soil, by supplying water to the midway stabilized soil and curing it,
It can be transported for a long time and can be cured in a short time.
Soil-stabilized soil that has reduced water permeability and prevented re-mudging can be produced.

Moreover, according to the method for producing a soil-stabilized soil of the present invention,
When the dry clay is bentonite,
Since the amount of decrease in water permeability of the soil-stabilized soil manufactured by this manufacturing method can be increased, re-mudging of the soil-stabilized soil can be reliably prevented.

Moreover, according to the method for producing a soil-stabilized soil of the present invention,
By the amount of the bentonite being 20% or more as a weight ratio with respect to the hardener,
By appropriately selecting the content of the bentonite according to the water permeability of the surrounding ground,
Furthermore, the water permeability of the soil-stabilized soil can be reliably reduced, and re-mudification of the soil-stabilized soil can be prevented.

Moreover, according to the method for producing a soil-stabilized soil of the present invention,
The amount of the bentonite is 40% to 100% as a weight ratio with respect to the hardener,
By appropriately selecting the content of the bentonite according to the water permeability of the surrounding ground,
Furthermore, the water permeability of the soil-stabilized soil can be reliably reduced, and re-mudification of the soil-stabilized soil can be prevented.

Moreover, according to the method for producing a soil-stabilized soil of the present invention,
The dry clay is a combination of bentonite and other smectite clay other than bentonite,
Stabilized material can be neutral
Furthermore, the water permeability of the soil-stabilized soil can be reliably reduced, and re-mudification of the soil-stabilized soil can be prevented.

Moreover, according to the method for producing a soil-stabilized soil of the present invention,
By including a retarder that slows down the curing rate of the curing material in the soil-stabilized soil,
Since the retarder acts to delay the curing of the soil-stabilized soil, the curing rate can be controlled by adjusting the amount of the retarder.

BEST MODE FOR CARRYING OUT THE INVENTION The best mode for carrying out a gypsum-based soil stabilization material and a method for producing a soil stabilization soil according to the present invention will be specifically described below with reference to the drawings.
FIGS. 1 to 15 are diagrams referred to for explaining a gypsum-based soil stabilization material and a method for producing a soil stabilization soil according to the first embodiment of the present invention.

The gypsum-based soil stabilization material according to the present embodiment is prepared by mixing hemihydrate gypsum (CaSO ₄ · 1 / 2H ₂ O) as a hardener and powdered dry clay. Bentonite is used as such dry clay.

  Moreover, in the manufacturing method of the soil-stabilized soil according to the present embodiment, such a gypsum-based soil-stabilized material is used. That is, a soil-stabilized soil is produced by mixing and stirring the gypsum-based soil-stabilized material and water in the soil to be treated.

  Here, bentonite which is a raw material for the gypsum-based soil stabilization treatment material is clay mainly composed of montmorillonite. This bentonite has the ability to absorb 5 to 10 times the amount of water, and has the property of increasing the viscosity and reducing the water permeability coefficient by absorbing and swelling the water.

  The method for producing a gypsum-based soil stabilization material and a soil stabilization soil according to the present embodiment is such that when the soil stabilization soil produced and placed is solidified, the swollen bentonite is impermeable to water. It takes advantage of the fact that it comes to exhibit sexual functions.

  In addition, the gypsum-based soil-stabilized material and the method for producing soil-stabilized soil according to the present embodiment pay attention to the fact that it takes time for the bentonite to swell and exhibit its viscosity. The viscosity of bentonite hinders the fluidity of soil-stabilized soil, which is necessary for placement, etc. It is something to avoid.

  In addition, the gypsum-based soil stabilization material according to the present embodiment and the method for manufacturing the soil stabilization soil, as described above, are impermeable to the swollen bentonite of the soil stabilization soil thus manufactured and placed. Since the amount of water passing through this soil-stabilized soil is reduced, the water in contact with the gypsum component contained in this soil-stabilized soil is thereby reduced. It is intended to reduce the amount of.

  In addition, as described above, the gypsum-based soil-stabilized material and the soil-stabilized soil manufacturing method according to the present embodiment are the amount of water that passes through the interior of the soil-stabilized soil that has been manufactured and placed. The amount of water that comes into contact with the gypsum component of this soil-stabilized soil is reduced, so the water that this soil-stabilized soil already contains is not contained in this soil-stabilized soil. Since it acts to be retained inside, after the gypsum component is dissolved and saturated in such retained water, the saturated state is maintained and no further gypsum component is dissolved. Therefore, the apparent solubility of gypsum is reduced.

  Therefore, the gypsum-based soil-stabilized material according to the present embodiment, and the method for producing soil-stabilized soil, pay attention to the soil-stabilized soil produced and placed by this, and the above-mentioned “background technology”. As compared with the second prior art in the column, the soil-stabilized soil according to the second prior art has a high solubility of the gypsum-based hardener due to its polymer agent and hydraulic auxiliary. The soil stabilization treated soil in the present embodiment only reduces the apparent solubility of the gypsum, whereas it only reduces the apparent solubility of the gypsum contained therein. In addition, by reducing the amount of water that comes in contact with the gypsum component of the soil stabilized soil, the outflow is prevented, so that the amount of gypsum dissolved more effectively is reduced. It is one that is Tsu.

  In addition, the gypsum-based soil stabilization material and the method for producing the soil-stabilized soil according to the present embodiment, as described above, include bentonite that is dry clay in this gypsum-based soil stabilization material. However, this does not impair the original function of improving the strength of the soil-stabilized soil.

  Further, the gypsum-based soil stabilization material according to the present embodiment, and the method for producing the soil-stabilized soil, in particular, is that bentonite is used as dry clay to be mixed with this gypsum-based soil stabilization material. Since the calcium ions of gypsum dissolved in water act to suppress the swelling of this bentonite and reduce the speed of thickening, it does not reduce the fluidity required when placing in soil-stabilized soil. The amount of bentonite can be increased.

  As a result, the gypsum-based soil-stabilized material and the soil-stabilized soil manufacturing method according to the present embodiment improve the water-impermeable function exhibited by the bentonite by incrementing the amount of bentonite mixed. It is what you want to do.

  Next, the flexibility of the manufacturing method of the soil-stabilized soil according to the present embodiment will be described.

  As described above, in the method for producing a soil-stabilized soil according to the present embodiment, a gypsum-based soil-stabilized material containing gypsum and powdered bentonite and water are mixed and stirred in the soil to be treated. Thus, the soil-stabilized soil is manufactured. The procedure for producing such a soil-stabilized soil is flexible and can be considered in several ways.

  That is, as a first example of a method for producing a soil-stabilized soil according to the present embodiment, as shown in FIG. 1, gypsum-based soil is first prepared by mixing and stirring gypsum and powdered bentonite. After producing a stable treatment material, the procedure which mixes and stirs each of this gypsum-type soil stabilization treatment material and water with to-be-processed soil, and manufactures a soil stable treatment soil can be considered.

  The soil-treated soil thus produced is transported to the construction site and placed before the loss of fluidity due to the gypsum component solidifying or the bentonite component exhibiting viscosity. The soil-stabilized soil after placing is solidified thereafter, thereby exhibiting strength and exhibiting a water-impermeable function.

  Further, as a second example of the method for producing a soil-stabilized soil according to the present embodiment, as shown in FIG. 2, gypsum-based soil is obtained by first mixing and stirring gypsum and powdered bentonite. After preparing a stabilization treatment material, this gypsum-based soil stabilization treatment material is mixed with water to form a slurry (slurry), and then such a slurry-like gypsum-based soil stabilization treatment material is applied to the treated soil. A procedure for producing a soil-stabilized soil by mixing and stirring can be considered.

  As a third example of the method for producing a soil-stabilized soil according to the present embodiment, as shown in FIG. 3, gypsum, powdered bentonite and water are mixed and stirred together almost simultaneously. After preparing a slurry-like gypsum-based soil stabilization treatment material by the above, the slurry-like gypsum-based soil stabilization treatment material can be mixed and stirred into the treated soil to produce a soil-stabilized soil. .

  As a fourth example of the method for producing a soil-stabilized soil according to the present embodiment, as shown in FIG. 4, gypsum-based soil is first prepared by mixing and stirring gypsum and powdered bentonite. After preparing a stable treatment material, this gypsum-based soil stabilization treatment material is mixed and stirred in the treated soil to prepare a stable treatment soil on the way, and after placing such a stable treatment soil on the construction site, A procedure can be conceived in which the soil is treated and stabilized as soil-treated soil by supplying water and starting hardening.

  In addition, as a fifth example of the method for producing a soil-stabilized soil according to the present embodiment, as shown in FIG. 5, gypsum, powdered bentonite, and water are almost simultaneously treated together. A procedure for producing a soil-stabilized soil by mixing and stirring the soil is conceivable.

  Further, as a sixth example of the method for producing a soil-stabilized soil according to the present embodiment, as shown in FIG. 6, first, gypsum and powdered bentonite are first mixed with the soil to be treated almost simultaneously. Stabilized soil on the way is produced by stirring, and after placing such a stable soil at the construction site, water is supplied to start hardening, so as to stabilize the soil in the placed state A procedure to make it complete can be considered.

  As described above, the method for producing a soil-stabilized soil according to the present embodiment has flexibility in its procedure, and accordingly, the gypsum system used in the method for producing such a soil-stabilized soil is included. The substantial concept of the soil stabilization material, that is, the gypsum-based soil stabilization material according to the present embodiment can be considered as follows.

  That is, the gypsum-based soil stabilization treatment material according to the present embodiment is prepared by mixing gypsum and bentonite as described above. It can be considered to include those prepared by mixing bentonite and water into a slurry (slurry) (see FIGS. 2 and 3). Such a slurry-like gypsum-based soil stabilization treatment material was added with water necessary for producing a soil-stabilized soil using the gypsum-based soil stabilization treatment material according to the present embodiment by changing the procedure. Because it is only a thing.

  In addition, the slurry-like gypsum-based soil stabilization treatment material prepared in this way is prepared by first mixing gypsum and bentonite to produce the original gypsum-based soil stabilization treatment material, and then mixing it with water. It may be prepared in a slurry state (see FIG. 2), or by mixing gypsum, bentonite, and water together from the beginning, the gypsum-based soil stabilization material may be prepared in a slurry form from the beginning. It is good also as making it (refer FIG. 3).

  Further, in the concept of the gypsum-based soil stabilization treatment material according to the present embodiment, there is a combination of gypsum and bentonite, and these are directly mixed into the treated soil without being mixed with each other. It can be considered that what is used by mixing with soil to be treated is also included (see FIGS. 5 and 6). This is because the use of gypsum and bentonite in this manner is substantially the same as using the gypsum-based soil stabilization material according to the present embodiment.

  In addition, when gypsum and bentonite are mixed directly into the treated soil almost simultaneously, water is mixed with gypsum and bentonite at the same time. Alternatively, the water may be mixed at a stage different from the stage of mixing the gypsum and bentonite (see FIG. 6).

  Next, the soil-stabilized soil manufactured using the gypsum-based soil-stabilized material according to the present embodiment, that is, the soil-stabilized soil manufactured by the soil-stabilized soil manufacturing method according to the present embodiment, The result of verifying that re-mudging can be prevented by the decrease in water permeability will be described.

  FIG. 7 shows a solidified gypsum-based soil stabilization treatment material prepared by mixing gypsum, bentonite, and water into a slurry (slurry) and immersed in still water for a period of 14 days or 28 days. Accordingly, the ratio of the weight after the lapse of 14 days or 28 days to the initial weight in such a solidified product is shown for each different blending ratio of gypsum and bentonite.

  Paying attention to each solidified product of gypsum-based soil stabilization treatment material prepared by mixing 0-60g of bentonite with 50g of gypsum, the one after 28 days is lighter than that after 14 days. It can be seen that the longer the contact time with water, the more calcium content of the gypsum flows out and lightens.

  Moreover, it turns out that the outflow of a calcium content becomes such that such a gypsum type | system | group soil stabilization treatment material has the compounding quantity of the bentonite more. It can be seen that the outflow of calcium content can be prevented almost completely in a gypsum-based soil stabilization material prepared by mixing 80 g of bentonite with 50 g of gypsum.

  Next, FIG. 8 shows the water permeability for each of the different blending ratios of gypsum and bentonite for the solidified gypsum-based soil stabilization material prepared by mixing gypsum, bentonite and water into a slurry. It is a table like that. FIG. 9 is a diagram of this. As shown in FIGS. 8 and 9, the gypsum-based soil stabilization material has a lower water permeability as the amount of bentonite is increased.

  Next, FIG. 10 is a table showing the flow values of gypsum-based bentonite mixed with different amounts of gypsum and bentonite for a gypsum-based soil-stabilized material prepared by mixing gypsum, bentonite and water into a slurry. is there. FIG. 11 is a diagram of this.

  Here, the flow value is based on the former Japan Highway Public Corporation standard (cylinder method JHS A-313), and a cylindrical body having an inner diameter of 80 mm and a height of 80 mm, with both end faces open on the plate. After the sample is placed and filled with the slurry-like measurement object, the maximum diameter of the measurement object spread on the plate by gently pulling the cylinder upward and the maximum It is a numerical value obtained by measuring the diameter direction and the length of the diameter in the perpendicular direction and averaging the two. This flow value serves as an index of fluidity, and the larger the value, the more the measurement object has fluidity.

  Also, the numerical value in the column described as “swelling” in the flow value column in the table of FIG. 10 was prepared by first mixing bentonite with water and then swelling it with gypsum. Refers to the flow value of the paste. The paste thus produced does not correspond to the gypsum-based soil stabilization treatment material according to the present embodiment, but merely serves as a comparison target with the gypsum-based soil stabilization treatment material.

  Further, the numerical value in the column of “powder” in the flow value column in the table of FIG. 10 (indicated as “non-swelled” in FIG. 11) is gypsum and powdered bentonite. This refers to the flow value of the gypsum-based soil stabilization material according to the present embodiment, prepared by mixing water and water simultaneously.

  As shown in FIGS. 10 and 11, the gypsum-based soil stabilization material according to the present embodiment has superior fluidity and lower viscosity than a paste produced by swelling bentonite. I understand.

Next, FIG. 12 shows the flow value of the soil-stabilized soil produced using the gypsum-based soil-stabilized material according to the present embodiment so that its wet density is 1.8 g / cm ³ . It is the table | surface shown for every different mixture ratio of a gypsum and bentonite.

  Here, sand classified as coarse-grained soil was used as the soil to be treated as a raw material of the soil-stabilized soil. Moreover, the description method of the column of the flow value in the table is almost the same as the description method of the table of FIG. 10, and the numerical value of the column described as “swelling” is the gypsum and the pre-swelled bentonite. This refers to the flow value of the paste prepared by mixing with the sand, and the numerical value in the column described as "powder" is obtained by mixing the gypsum-based soil stabilization material according to the present embodiment with the sand. It refers to the flow value of the prepared soil stabilized soil.

  As shown in FIG. 12, the soil-stabilized soil produced using the gypsum-based soil-stabilized material according to the present embodiment is more fluid than that obtained by mixing paste prepared by swelling bentonite with sand. Is excellent and the viscosity is low.

  Further, according to the results shown in FIG. 12, for example, when producing a soil-stabilized soil using the gypsum-based soil-stabilized material according to the present embodiment, when the flow value is set to about 175 mm, Whereas the blending amount of bentonite corresponding to such a flow value is 40 g with respect to 50 g of gypsum, a paste prepared by pre-swelling bentonite and mixed with the soil to be treated has a flow value of 175 mm. Since the amount of bentonite in the vicinity of 178 mm is 20 g, the soil-stabilized soil produced using the gypsum-based soil-stabilized material according to the present embodiment contains about twice as much bentonite. It can be seen that it can be made to.

Next, FIG. 13 shows the quality of the soil-stabilized soil produced using the gypsum-based soil-stabilized material according to the present embodiment. As shown in the figure, the soil stabilization treated soil has a blending ratio of bentonite and gypsum in the gypsum-based soil stabilization treatment material set to 156/260 = 0.6, and a mixing ratio of water and gypsum 520/260 = 2 is set. Thereby, as for this soil-stabilized soil, the water permeability is reduced to 3.40 × 10 ⁻⁶ cm / s.

On the other hand, as shown in FIG. 8, the gypsum-based soil stabilization material prepared by mixing 50 g of gypsum, 30 g of bentonite and 100 g of water is the gypsum-based soil stabilization material used to produce the soil-stabilized soil shown in FIG. As can be seen from the comparison with the treatment material, the bentonite / gypsum mixing ratio (30/50 = 0.6) and the water / gypsum mixing ratio (100/50 = 2) are made to be equal to each other. It is what. This gypsum-based soil-stabilized material has a hydraulic conductivity of 3.31 × 10 ⁻⁶ cm / s, which is a value very close to the hydraulic conductivity of the soil-stabilized soil shown in FIG.

  Thereby, the water permeability of the soil-stabilized soil produced using the gypsum-based soil stabilization material according to the present embodiment is substantially determined based on the water permeability of this gypsum-based soil stabilization material. I understand.

  Next, FIG. 14 is a table showing the uniaxial compressive strength of the paste prepared by mixing gypsum and water for each blending ratio of different water and gypsum. FIG. 15 is a diagram showing the correlation between the mixing ratio of water and gypsum in such a paste and the uniaxial compressive strength exhibited by mixing the paste with sand.

  As shown in FIGS. 14 and 15, the paste prepared by mixing gypsum and water has a uniaxial compressive strength that depends on the mixing ratio of water and gypsum. It can be seen that the uniaxial compressive strength hardly changes even if the wet density is mixed.

  Therefore, from these results, the soil-stabilized soil produced using the gypsum-based soil stabilization treatment material according to the present embodiment has a uniaxial compressive strength that is the same as that of water and gypsum in the gypsum-based soil stabilization material. It turns out that it comes to depend on the mixture ratio of.

  As a result, it can be understood that the soil-stabilized soil produced using the gypsum-based soil stabilization material according to the present embodiment has a strength that does not depend on the soil quality of the treated soil, and the gypsum-based soil stabilization material. It can be seen that the bentonite contained in does not act to impair the function of improving the strength of the soil-stabilized soil by this gypsum-based soil-stabilized material.

  Next, a description will be given of how to determine the respective amounts of gypsum and bentonite necessary for producing the gypsum-based soil stabilization material according to the present embodiment.

  In order to determine the amount of gypsum and bentonite necessary to produce a gypsum-based soil stabilization material, first, the soil-stabilized soil produced using this gypsum-based soil stabilization material is The amount of gypsum based on Fig. 14 is obtained from the amount of water required to have sufficient fluidity, and the amount of this water and the strength required for the soil-stabilized soil (uniaxial compressive strength). To ask. The amount of bentonite relative to the amount of gypsum is determined from FIGS. 8 and 9 in consideration of the non-water permeability required for the soil-stabilized soil.

  In addition, as a procedure when producing a soil-stabilized soil using the gypsum-based soil stabilization material according to the present embodiment, the gypsum-based soil stabilization material is mixed and stirred in the soil to be treated, thereby stabilizing the soil in the middle. When creating and placing the stabilized soil on the way and then supplying water to harden it, that is, when the treated soil is finally completed as a soil-stabilized soil after placement The sum of the gaps between the soil particles of the soil to be treated in the soil-treated soil after completion is the total volume of the gypsum-based soil stabilizing material according to the present embodiment, that is, gypsum and bentonite. It may be considered that it corresponds to the total volume of the mixture with water.

  Therefore, after the placement of the gypsum and bentonite necessary for producing the gypsum-based soil stabilization material, the total volume of the gap between the soil particles of the soil to be treated in the finished soil stabilization soil If these volume ratios obtained by conversion from the mass ratio with the water to be supplied are multiplied, the respective mixing amounts of gypsum, bentonite and water can be obtained as the volume.

  Furthermore, if each density is multiplied by the volume of each mixing amount of gypsum, bentonite, and water, each mixing amount can be obtained as its mass.

For example, when the strength (uniaxial compressive strength) of the soil-stabilized soil after completion is set to 400 kN / m ² , the mass ratio (water / gypsum) between water and gypsum is reduced according to the table in FIG. 2 and, if the mass ratio between bentonite and gypsum (bentonite / gypsum) is set to 0.8, the mass ratio between gypsum, bentonite and water is It can be seen that 1: 0.8: 2.

  In addition, each of the mass ratio values between gypsum, bentonite, and water is divided by its density to obtain a volume ratio, and between the soil particles of the soil to be treated in the soil-stabilized soil to produce this. By multiplying the total volume of the gap portion, the amount of each mixture of gypsum, bentonite and water can be determined as the volume. Moreover, if each density of these gypsum, bentonite, and water is multiplied by the density, the mixing amount of each can be obtained as the mass.

  According to the gypsum-based soil stabilization material according to the first embodiment, the soil stability-treated soil produced by using this gypsum-based soil stabilization material is reduced in water permeability and re-mudged. Can be prevented.

  Moreover, according to the manufacturing method of the soil-stabilized soil which concerns on 1st Embodiment, the soil-stabilized soil which reduced water permeability and prevented re-mudging can be manufactured.

  In addition, according to the gypsum-based soil stabilization material and the method for producing a soil-stabilized soil according to the first embodiment, bentonite is used as the dry clay contained in this gypsum-based soil stabilization material. As a result, it is possible to increase the decrease in water permeability of the soil-stabilized soil produced using this gypsum-based soil-stabilized material, so that it is possible to reliably prevent re-mudging of the soil-stabilized soil. .

  Further, according to the gypsum-based soil stabilization material and the method for producing the soil-stabilized soil according to the first embodiment, as shown in FIG. When the component is contained in an amount of 20% or more as a weight ratio with respect to gypsum, a decrease in water permeability appears remarkably, so that the gypsum-based soil containing an auxiliary agent for re-mudging suppression. If it is a stable treatment material, when it is set as such a mixture ratio, the water permeability of the soil-stabilized soil can be reliably lowered, and re-mudging of this soil-stabilized soil can be prevented.

  In addition, according to the gypsum-based soil stabilization material and the method for producing the soil-stabilized soil according to the first embodiment, in particular, the weight ratio of bentonite in the gypsum-based soil stabilization material to the gypsum. When 40% to 100% is included, the water permeability can be reduced to a level that could not be achieved by the prior art. After all, the water permeability of the soil-stabilized soil can be reliably reduced, and re-mudging of the soil-stabilized soil can be prevented.

That is, as described in Patent Document 2 in the above-mentioned “Background Art” column, when magnesium oxide is added to a gypsum-based hardener, the blending ratio of magnesium oxide to gypsum is practical. In the case of adjusting within the range, the permeability coefficient of the soil-stabilized soil using such a gypsum-based hardener is at most about 2 × 10 ⁻⁵ cm / s, but according to the present embodiment. In the gypsum-based soil stabilization material, when the bentonite component is contained in a weight ratio of 40% to 100% with respect to gypsum, as shown in FIG. 9, its water permeability is 2 × 10 ⁻⁵ cm. / S can be made smaller.

  Therefore, according to the gypsum-based soil stabilizing treatment material and the method for producing a soil-stabilized soil according to the present embodiment, in particular, the component of bentonite in the gypsum-based soil stabilization material is 40 as a weight ratio to gypsum. When it is made to contain from 100% to 100%, it is possible to reliably reduce the water permeability of the soil-stabilized soil, and prevent re-mudging of the soil-stabilized soil, as compared with the prior art.

  In addition, according to the gypsum-based soil stabilization material and the method for producing a soil-stabilized soil according to the first embodiment, in particular, the powdered bentonite used for this gypsum-based soil stabilization material is treated soil. When mixing with gypsum first and then throwing it into the treated soil without mixing directly, gypsum will act as a bulking agent even if the amount of bentonite is small. Is uniformly mixed with the soil to be treated, so that the certainty of preventing re-mudging of the soil-stabilized soil can be remarkably improved.

  That is, as described above, in the soil-stabilized soil according to the second prior art in the column of “Background Art”, a polymer agent and a hydraulic auxiliary agent are added to the gypsum-based hardener as described above. However, the content of these polymer agents and hydraulic auxiliaries is actually reduced to a small amount so as not to impair the quick setting, which is an advantage of gypsum. It is very difficult to uniformly disperse the hydraulic auxiliary agent in the soil-stabilized soil.

  For this reason, the above-mentioned soil-stabilized soil according to the second prior art is such that the calcium (Ca) content of gypsum in the gypsum-based hardened material produces a part that is relatively easy to dissolve and a part that is difficult to dissolve. As a result, rainwater and groundwater tend to concentrate on the portion that is easily dissolved. Therefore, the soil-stabilized soil according to the second prior art described above has a potential factor for deterioration of the soil.

  In addition, in the soil-stabilized soil according to the second prior art described above, if the amount of the polymer agent or hydraulic auxiliary agent is increased, the strength improvement of the soil-stabilized soil is improved. Since it also occurs due to a pozzolanic reaction with a high degree of dependence, it will require curing for a certain period of time before the strength stabilizes. Since there was a problem that the original strength, such as being ready to be evaluated, was lost, eventually eliminating the potential factor of the soil degradation while keeping the strength of the gypsum hardener. I couldn't do it.

  In contrast, the gypsum-based soil stabilization material and the method for producing the soil-stabilized soil according to the present embodiment mix the powdered bentonite used for this gypsum-based soil stabilization material with gypsum before coating. When throwing it into the treated soil, the problem of the second prior art described above can be fundamentally solved, so the reliability of preventing soil re-mudging is significantly improved. Can be made.

  Next, FIG. 16 to FIG. 18 are diagrams which are referred to for explaining the gypsum-based soil stabilization treatment material and the method for manufacturing the soil stabilization treatment soil according to the second embodiment of the present invention. The overlapping description about the same structure as the manufacturing method of the gypsum-type soil stabilization processing material and soil stabilization processing soil which concerns on the said 1st Embodiment shall be abbreviate | omitted.

  In the gypsum-based soil stabilization material and the method for producing the soil-stabilized soil according to the second embodiment of the present invention, a retarder is included in the gypsum-based soil stabilization material. This retarder acts to reduce the curing rate of gypsum. As such a retarder, for example, sodium glutamate, gypsum plaster, citric acid and the like can be used.

  Each of FIGS. 16 to 18 is a graph showing changes in setting time when sodium glutamate, gypsum plaster, and citric acid are added when a hydration reaction is caused in gypsum.

  Here, in each of the diagrams of FIGS. 16 to 18, the curing time on the vertical axis represents the time until the temperature reaches a peak due to the heat generated when gypsum is cured by the hydration reaction. This is adopted as an index of curing time by hydration reaction.

  According to the gypsum-based soil stabilization material according to the second embodiment, as in the first embodiment, the soil-stabilized soil produced using this gypsum-based soil stabilization material, The water permeability can be reduced to prevent re-mudging.

  Moreover, according to the manufacturing method of the soil-stabilized soil which concerns on 2nd Embodiment, similarly to the said 1st Embodiment, the soil-stabilized soil which reduced water permeability and prevented re-mudging is manufactured. be able to.

  In addition, according to the gypsum-based soil stabilization treatment material and the method for producing a soil-stabilized soil according to the second embodiment, the gypsum-based soil stabilization treatment material is contained in the gypsum-based soil stabilization treatment material as in the first embodiment. By using bentonite as the dry clay, it is possible to increase the amount of decrease in water permeability of the soil-stabilized soil produced using this gypsum-based soil-stabilized material. The soil can be prevented from becoming muddy again.

  In addition, according to the gypsum-based soil stabilization material and the method for producing a soil-stabilized soil according to the second embodiment, as in the first embodiment, in particular, the gypsum-based soil stabilization material When the content of bentonite in the soil is 20% or more by weight with respect to gypsum, the water permeability of the soil treated with soil should be reliably reduced and re-mudging of the soil treated with soil should be prevented. Can do.

  In addition, according to the gypsum-based soil stabilization material and the method for producing a soil-stabilized soil according to the second embodiment, as in the first embodiment, in particular, the gypsum-based soil stabilization material When the content of bentonite in the mixture is 40% to 100% by weight with respect to gypsum, the water permeability of the soil with stable soil treatment is definitely lowered, and this soil stabilized soil is re-mudled. Can be prevented.

  In addition, according to the gypsum-based soil stabilization material and the method for producing a soil-stabilized soil according to the second embodiment, as in the first embodiment, the gypsum-based soil stabilization material, in particular, When the powdered bentonite used is not directly mixed with the soil to be treated but is first mixed with gypsum and then introduced into the soil to be treated, gypsum acts as a filler even if the amount of bentonite is small. Since the bentonite component is uniformly mixed with the soil to be treated, the certainty of preventing re-mudging of the soil-stabilized soil can be remarkably improved.

  Further, according to the gypsum-based soil stabilization material and the method for producing a soil-stabilized soil according to the second embodiment, since this gypsum-based soil stabilization material contains a retarder, By adjusting the amount of the retarder, the curing rate of the soil-stabilized soil can be controlled.

  For example, when sodium glutamate is used as a retarder, as shown in FIG. 16, the amount of addition is within the verification range in which this sodium glutamate is added in a range of 0 to 0.3% with respect to gypsum. As the setting time increases, the setting time becomes longer uniformly. Therefore, the setting rate of the soil-stabilized soil can be controlled by adjusting the amount of sodium glutamate at least in such a range.

  In addition, when using gypsum plaster as a retarder, as shown in FIG. 17, within the verification range in which this gypsum plaster is added in a range of 0 to 20% with respect to gypsum, with an increase in the amount of addition. Since the setting time is uniformly long, the setting speed of the soil-stabilized soil can be controlled by adjusting the amount of gypsum plaster at least in such a range.

  In addition, when citric acid is used as a retarder, as shown in FIG. 18, the curing time becomes the longest when citric acid is added to the gypsum within about 1% within the verified range. The hardening rate of the soil-stabilized soil can be controlled by adjusting the amount to 0 to 1% or 1 to 5% of gypsum.

  In the gypsum-based soil-stabilized material and the method for producing soil-stabilized soil according to the first and second embodiments, those that can be used as treated soil that is a raw material for the soil-stabilized soil. Although not specified, as such treated soil, coarse soil (soil containing 50% or more of coarse particles having a soil particle diameter of 0.075 mm or more) is preferable, and particularly, sandy soil (coarse soil). Among the granular soils, a soil containing a sand part having a soil particle diameter of 0.075 to 2 mm more than a gravel part having a soil particle diameter of 2 to 75 mm is preferable.

  On the other hand, when using fine-grained soil (soil containing 50% or more of fine particles having a soil particle diameter of 0.075 mm or less) as the soil to be treated, the viscosity of the soil to be treated is too high. Since it is difficult to mix only the gypsum-based soil stabilization treatment material into the treated soil without mixing (see FIGS. 4 and 6), the gypsum-based soil stabilization treatment material is mixed with the treated soil together with water. It is preferable to do so (see FIGS. 1 to 3 and FIG. 5).

  In addition, when fine-grained soil is used as the treated soil, both the gypsum-based soil stabilization material and water are used to reduce the water permeability compared to the case where coarse-grained soil is used as the treated soil. Therefore, it is preferable to use coarse-grained soil as the soil to be treated from the viewpoint of workability, economic efficiency, and the like.

  In the gypsum-based soil stabilization material and the method for producing the soil-stabilized soil according to the first and second embodiments, bentonite is used as the dry clay contained in the gypsum-based soil stabilization material. However, this bentonite preferably contains 50% or more of montmorillonite by mass ratio.

  In the gypsum-based soil stabilization material and the method for producing soil stabilization soil according to the present embodiment, bentonite is used as the dry clay, but other dry clay other than bentonite is used. It may be. As other dry clays other than bentonite, a clay composed of soil particles having a particle size of 5 μm or less, and a clay having a swelling degree of 2 or more and a pH of 10 or less is dried and ground. By doing so, a powdered product can be used.

  Specific examples of such dry clays include, for example, smectite group clays such as acid clay (pH 5-6, swelling degree 2-3), which can take in water between crystal structures. Can be used. Note that bentonite (pH 7 to 8.5, swelling degree 5 to 10) used in the first and second embodiments also belongs to the smectite group. In addition, dry clay may be used by arbitrarily combining bentonite and smectite group clay other than bentonite.

  Moreover, you may make it use the illite soil which has a mica as a main component instead of the bentonite in the said 1st and 2nd embodiment. Alternatively, any combination of smectite group clay such as bentonite and acid clay, illite soil, or clay other than these and can be used as a substitute for bentonite may be used. .

  Further, in the gypsum-based soil stabilization material and the method for producing the soil-stabilized soil according to the first and second embodiments, the hardening material of the gypsum-based soil stabilization material is composed only of gypsum. However, the hardener is not limited to such a material, and any material containing gypsum as a main component may be used. As such a curing material, a material containing a gypsum component in a mass ratio of 50% or more is particularly preferable.

  Further, in the gypsum-based soil stabilization material according to the second embodiment and the method for producing a soil-stabilized soil, the retarder was included in the gypsum-based soil stabilization material, As another embodiment, for example, it may be directly put into the soil to be treated, as long as it is finally contained in the soil-stabilized soil.

  Moreover, although the said 1st and 2nd embodiment demonstrated the manufacturing method of the gypsum-type soil-stabilized material and the soil-stabilized soil, the gypsum-type soil-stabilized material at the time of manufacture of the soil-stabilized soil. If it is not concerned with using, powdery bentonite may be added to cement or a cement-based soil stabilization material.

BRIEF DESCRIPTION OF THE DRAWINGS It is a manufacturing method of the gypsum-type soil stabilization process soil which concerns on the 1st Embodiment of this invention, Comprising: It is process drawing which shows the procedure of the 1st example. It is a manufacturing method of the gypsum-type soil stabilization processing soil which concerns on the 1st Embodiment of this invention, Comprising: It is process drawing which shows the procedure of the 2nd example. It is a manufacturing method of the gypsum-type soil stable processing soil which concerns on the 1st Embodiment of this invention, Comprising: It is process drawing which shows the procedure of the 3rd example. It is a manufacturing method of the gypsum-type soil stabilization process soil which concerns on the 1st Embodiment of this invention, Comprising: It is process drawing which shows the procedure of the 4th example. It is a manufacturing method of the gypsum-type soil stable processing soil which concerns on the 1st Embodiment of this invention, Comprising: It is process drawing which shows the procedure of the 5th example. It is a manufacturing method of the gypsum-type soil stabilization processing soil which concerns on the 1st Embodiment of this invention, Comprising: It is process drawing which shows the procedure of the 6th example. Although the solidified gypsum-based soil stabilization material according to the first embodiment of the present invention is immersed in still water for a certain period, the weight ratio with respect to the initial weight is shown for each different blending ratio of gypsum and bentonite. It is a table like that. It is the table | surface which showed the hydraulic conductivity of what hardened the gypsum-type soil stabilization processing material which concerns on the 1st Embodiment of this invention for every different mixture ratio of gypsum and bentonite. It is a diagram which shows the correlation with the compounding ratio of the gypsum and bentonite, and the water permeability in what solidified the gypsum-type soil stabilization processing material which concerns on the 1st Embodiment of this invention. The respective flow values of the gypsum-based soil stabilization treatment material according to the first embodiment of the present invention and the mixture to be compared with this gypsum-based soil stabilization treatment material are shown for different blending ratios of gypsum and bentonite. It is a table like that. Correlation between the blending ratio of bentonite and gypsum and the flow value in each of the gypsum-based soil stabilization treatment material according to the first embodiment of the present invention and the mixture to be compared with this gypsum-based soil stabilization treatment material FIG. The respective flow values of the soil-stabilized soil produced using the gypsum-based soil-stabilized material according to the first embodiment of the present invention, and the mixture to be compared with this soil-stabilized soil, are gypsum and bentonite. It is the table | surface shown for every different mixture ratio. It is a table | surface which shows the quality of the soil stable treated soil manufactured using the gypsum-type soil stable treated material which concerns on the 1st Embodiment of this invention. It is the table | surface which showed the uniaxial compressive strength about the paste produced by mixing gypsum and water for every mixing ratio of different water and gypsum. It is a diagram which shows the correlation between the mixture ratio of the water and the gypsum, and the uniaxial compressive strength in what mixed the paste produced by mixing a gypsum and water with sand. The diagram which shows the change of hardening time when adding the glutamic acid sodium as a retarder used for the gypsum-type soil stabilization processing material which concerns on the 2nd Embodiment of this invention when producing a hydration reaction in gypsum. It is. The diagram which shows the change of hardening time when adding the gypsum plaster as a retarder used for the gypsum-type soil stabilization processing material which concerns on the 2nd Embodiment of this invention when producing a hydration reaction in gypsum. It is. The diagram which shows the change of hardening time when adding the citric acid as a retarder used for the gypsum-type soil stabilization processing material which concerns on the 2nd Embodiment of this invention when making a gypsum cause a hydration reaction. It is. In relation to the soil stabilized soil according to the second prior art, the volume reduction after immersion for a certain period of time with respect to the original volume of the paste prepared by mixing gypsum and water and solidified by adding magnesium oxide It is the table | surface which showed the rate for every mixing rate of magnesium oxide. FIG. 20 is a diagram for the table shown in FIG. 19.

Claims (15)

  A gypsum-based soil stabilization material characterized in that it contains a hardener composed mainly of hemihydrate gypsum and powdered dry clay.   The gypsum-based soil stabilization material according to claim 1, wherein the dry clay is bentonite.   The gypsum-based soil stabilization material according to claim 2, wherein the bentonite is contained in a weight ratio of 20% or more with respect to the hardener.   The gypsum-based soil stabilization material according to claim 2, wherein the bentonite is contained in a weight ratio of 40% to 100% with respect to the hardener.   The gypsum-based soil stabilization material according to claim 1, wherein the dry clay is a combination of bentonite and a smectite clay other than bentonite.   The gypsum-based soil stabilization material according to any one of claims 1 to 5, further comprising a retarder that reduces the curing rate of the curing material.   It is characterized by being produced by mixing and stirring a gypsum-based soil stabilization treatment material containing a hardener composed mainly of hemihydrate gypsum and powdered dry clay, and water. A method for producing a soil with stable soil treatment. A slurry-shaped gypsum-based soil stabilization treatment material is prepared by mixing and stirring a hardener composed mainly of hemihydrate gypsum, dry powdered clay, and water,
A method for producing a soil-stabilized soil, characterized in that the slurry-like gypsum-based soil-stabilized material is mixed and stirred in the soil to be treated.   A method for producing a soil-stabilized treated soil, characterized in that a hardened material composed mainly of hemihydrate gypsum, powdered dry clay, and water are mixed and stirred in the soil to be treated. The soil to be treated is coarse-grained soil,
In the soil to be treated, a hardened material composed mainly of hemihydrate gypsum and powdered dry clay are mixed and stirred to produce a stable treated soil in the middle.
A method for producing a soil-stabilized soil, characterized in that, after placing the midway-stabilized soil, water is supplied to the midway-stabilized soil and cured.   The method for producing a soil-treated soil according to any one of claims 7 to 10, wherein the dry clay is bentonite.   The method for producing a soil-stabilized soil according to claim 11, wherein the amount of the bentonite is 20% or more as a weight ratio with respect to the hardener.   The method for producing soil-stabilized soil according to claim 11, wherein the amount of the bentonite is 40% to 100% as a weight ratio with respect to the hardener.   The method for producing a soil-treated soil according to any one of claims 7 to 10, wherein the dry clay is a combination of bentonite and a smectite group clay other than bentonite.   The method for producing soil-stabilized soil according to any one of claims 7 to 14, wherein the soil-stabilized soil contains a retarder that slows down the curing rate of the hardener.

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