JPH10331152A - Water shutoff construction for artificial pond, etc. - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily construct a water shutoff layer for a pond, etc., at a low cost, which has certain shutoff property even if the soil of the ground has a high water content. SOLUTION: Bentonite, cement or a solidifying material such as lime are scattered over the ground 3 at the same time approximately. The soil of the ground 3 and the bentonite and cement are mixed together in the subsequent period from the substantial end of the water absorption of bentonite to propagation of the hardening reaction by the solidifying material, and thereby a water shutoff layer 5 is formed. This mixing process is practicable at an early stage owing to water absorption, and tamping after mixing can be done satisfactorily. Because the mixing process can be performed before propagation of the earth being turned granular or porous caused by the solidifying material for enhancement of the strength of the layer 5, drop of the water permeation factor can be prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a seepage control method used for constructing an artificial pond or repairing a natural pond.

[0002]

Ponds are often used in parks and golf courses as hydrophilic facilities, landscape ponds, reservoirs or reservoirs, and are indispensable facilities. In the past, sheet-based (synthetic rubber, vinyl chloride, ethylene, or asphalt-based) water-blocking methods were generally used for constructing artificial ponds or repairing natural ponds. Have problems such as water leakage due to sheet breakage. On the other hand, as described in, for example, JP-A-63-67322, a water-blocking method using bentonite which is a special clay soil has been proposed. The water-blocking method using bentonite has the advantage that there are few problems such as water leakage due to breakage, and that it is friendly to the natural environment and that a pond excellent in landscape can be constructed at low cost. The following are examples of conventional water-blocking methods using bentonite.

[0003] A predetermined amount of bentonite made of powder is sprayed on the target soil, the local soil and the bentonite are mixed and compacted using a stabilizer or a tractor, thereby lowering the current permeability of the ground. Let
Reduce water leakage. The construction thickness of the impermeable layer formed by bentonite is 10 to 50 cm per layer. In this seepage control method, the target soil is desirably silt soil, cohesive soil, or the like. When the permeability is 1 × 10 ⁻⁴ cm / sec or more in sandy soil or the like, the amount of added bentonite may increase, which may be uneconomical. Typical addition amount is 70 ~
A 150kg / m ^3.

[0004] Bentonite mixed soil has the following properties. There is a negative correlation between the amount of added bentonite and the hydraulic conductivity, and the larger the added amount, the smaller the hydraulic conductivity. There is a negative correlation between the compaction density of the impermeable layer and the hydraulic conductivity, and when sufficiently compacted, the hydraulic conductivity decreases. As long as the water content of the target soil, which is the base material, is equal to or less than the liquid property limit value, the hydraulic conductivity has almost no effect. That is, as the water content ratio increases, the hydraulic conductivity converges to a constant value. In addition, in the case of a low water content ratio, the water immersion time becomes long and converges to a constant value when the bentonite absorbs and expands sufficiently. When shear strain occurs in the bentonite impermeable layer and a shear fracture surface occurs, the amount of water leakage temporarily increases,
Over time, the fracture surface self-heals and the water barrier effect is restored. It has high tackiness and is not easily washed away due to the attachment of soil particles. Bentonite is a viscous soil that exists in nature and has remarkable performances such as swelling, suspension, adhesiveness, and thixotropy. It does not become industrial waste. Although the bentonite impermeable layer absorbs and expands, the coefficient of permeability is not affected by the amount of expansion. Confining pressure swells when water immersion when 0.2 kgf / cm ² less than hardly swells greater than 0.3 kgf / cm ^2. Also, the water permeability hardly changes even when swelling. Even if gravel is mixed in the bentonite mixed soil, the hydraulic conductivity is not affected. That is, if a bentonite that can sufficiently close the gaps of the conglomerate soil is mixed, a good impermeable layer that can be easily compacted can be formed. However, it is necessary not to include a large amount of boulders or boulders that cannot be mixed by a stabilizer or a tractor.

[0005] By the way, in the above-mentioned conventional water shielding method,
If the water content of the soil to be mixed with bentonite becomes high due to rainfall, etc., if this water content is below the liquid limit value of the target soil, the water shielding effect of the bentonite mixing will not be impeded, but the bentonite mixing at the site will not be hindered. It becomes difficult to compact and shape the impermeable layer later. Although bentonite absorbs a large amount of water, it is still soft and difficult to compact sufficiently. If the water content is further increased, it becomes difficult to spray and mix the bentonite, and the degree of mixing is reduced.

In the case where the water content of the target soil is high and construction is difficult as described above, conventionally, a method of draining and drying naturally over a long time, a method of replacing the soil with a high water content, cement, lime, etc. The soil improvement method using solidified material was adopted. Of these methods, the method of naturally reducing the water content and the method of replacing the method naturally take too much time, are not economical, and are not suitable. Therefore, a method of increasing the supporting force while lowering the water content by spraying a solidifying material is generally employed. In this method, a solidifying material such as cement or lime is preliminarily stabilized and mixed with local soil to improve trafficability and then mixed with bentonite. However, in general, when the stabilization treatment is performed, the strength of the soil is improved, but the soil is agglomerated and porous, and the permeability increases, so that the amount of bentonite used increases. There is a tendency that the amount of bentonite mixed increases as the consolidation reaction of the solidified material proceeds after soil improvement. Furthermore, the number of mixing operations increases, which is uneconomical.

[0007] The present invention is intended to solve such a problem, and provides a water-blocking method capable of easily and inexpensively constructing a water-blocking layer having reliable water-blocking even with a high water content ratio soil. The purpose is to provide.

[0008]

According to the present invention, in order to attain the above object, in a water shielding method for a ground having a high water content soil, a solidified material and bentonite are sprayed almost simultaneously on the ground. Later, the target soil of the ground, bentonite, and the solidifying material are mixed to form a water barrier layer.

As a result of repeated work and research, when the solidified material and bentonite are sprayed almost at the same time, surplus water is absorbed in a short period of time so that mixing can be performed, and compaction after mixing can be sufficiently performed. I understood that. In addition, since the strength characteristics are improved without lowering the water blocking effect, a stable water blocking layer can be formed.

Further, according to the present invention, the water barrier layer sprays bentonite between the time when the solidifying material is sprayed and the time when the hardening reaction of the solidified material starts, so that the moisture contained in the target soil is reduced to the solidified material and the bentonite. After water absorption, it is formed by mixing before the hardening material is hardened.

Thus, mixing can be performed without any trouble, and compaction after mixing can be sufficiently performed.
Since the mixing is performed before the agglomeration of the soil and the formation of the porous material by the solidified material, the reduction of the water permeability can be prevented.

[0012]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a sectional view showing a first embodiment of the present invention; In FIG. 1 showing a cross-sectional view of an artificial pond 1, reference numeral 2 denotes water in the pond 1, reference numeral 3 denotes ground,
Reference numeral 4 denotes a base layer of the ground 4, 5 denotes a water barrier layer formed of bentonite mixed soil formed on the base layer 4, and 6 denotes a protective layer formed on the water barrier layer 5. For example, the thickness a of the impermeable layer 5 is 10 to 50 cm per layer, and the thickness b of the protective layer 6 is 20 to 50 cm.
30cm, but not limited to. FIG.
FIG. 1A shows a state before the pond 1 is built, and FIG. 1B shows a state after the pond 1 is built.

Next, the water blocking method will be described. This water-blocking method is suitable when the water content of the bentonite-mixed soil in the base layer 4 of the ground 3 at the planned site of the pond 1 is high due to rainfall or the like. In this method,
Powdered, granular, granular or massive bentonite and a solidifying material are used. As the solidifying material, a cement-based material or a lime-based material can be used. Amount of bentonite is 70 to 150 kg / m ³ the mixed target soil.
The amount of the solidifying agent to be added depends on various conditions, but 2 to 8% by weight or 2 to 5% by weight is sufficient for both cement and lime. If the unconfined compressive strength of the ground 3 is 1 kgf / cm ² or more, it is possible to work using a civil engineering machine such as a backhoe or a bulldozer. For example, if the amount of the solidifying material is determined so as to obtain such a strength, Good. Moisture content is 150 ~
If it is as high as 200%, a larger amount of the solidifying material may be added.

At the time of construction, first, a predetermined amount of the solidified material and bentonite are sprayed almost simultaneously on the soil to be mixed by human power or a spraying machine. Next, the bentonite, the solidified material, and the soil to be mixed are mixed by a mixing machine such as a human power or a stabilizer. The mixed soil to be the impermeable layer 5 is compacted to a predetermined thickness by human power or an appropriate civil engineering machine, and the surface thereof is shaped. Thereafter, the mixed soil is covered with a protective layer 6 from above. This protective layer 6
Is, for example, the gravel spread on the slope of the pond 1 and the soil on the bottom.

[0015] Spraying the bentonite and the solidified material almost simultaneously means that the bentonite is added between the time the solidified material is added to the target soil and the time the hardening reaction of the solidified material starts. Therefore, there may be a slight time difference between the application of the solidifying material and the application of the bentonite. The time from the addition of the solidifying material to the addition of the bentonite may be, for example, within 4 hours, more preferably within 2 hours.

After the bentonite is sprayed on the target soil, the bentonite absorbs water contained in the target soil. This water absorption time is within one hour after spraying. On the other hand, the solidifying material causes a curing reaction, which takes a longer time as described above. Mixing of bentonite, solidified material and target soil, after almost complete water absorption,
What is necessary is just to finish within several hours before hardening of a solidification material. In addition,
As will be described later, when the curing curing time elapses for 24 hours, the water permeability may increase by about one digit.

By sprinkling the bentonite and the solidifying material almost simultaneously as described above, the excess water is absorbed in a short period of time so that mixing can be performed, and compaction after mixing can be sufficiently performed. Then, the soil can be mixed before the soil is agglomerated and porous with the progress of the hardening reaction of the solidified material, so that an increase in the water permeability can be prevented, and a decrease in the water blocking effect can be prevented. On the other hand, since the strength characteristics of the water impermeable layer 5 are improved by the final curing by the solidified material, the stable water impermeable layer 5 can be formed. Since it is possible to suppress an increase in the hydraulic conductivity due to agglomeration and porosity of the soil, it is possible to reduce the amount of bentonite required to obtain a predetermined hydraulic conductivity, thereby reducing costs. Further, unlike the case where the mixing of the solidified material and the mixing of the bentonite are performed separately, only one mixing operation is required.

Here, the test results regarding the curing time of the solidified material will be described. In addition, test results showing various characteristics of bentonite will be described. Table 1 and Table 2 show the sample soils to be mixed.

[0019]

[Table 1]

[0020]

[Table 2]

Of these samples, No. 1 was clayey soil, No. 2
No. 3 is cohesive soil, No. 4 is cohesive soil, No. 4 is cohesive soil, No. 5 is sandy soil, No. 6 is cohesive soil, No. 7 is sandy soil (contains a lot of iron sand)
It is. Then, a specimen having a volume of 1000 cm ³ was produced from a mixture of the target soil, bentonite, and cement as a solidifying material, and a water permeability tester was used to evaluate the water shielding effect according to “Soil permeability test JIS A 1218”.

FIG. 2 shows the relationship between the amount of bentonite and the permeability. The water content of the target soil shown in Table 1 is the natural water content. In both cohesive and sandy soils, the permeability tends to decrease as the amount of bentonite increases.

FIG. 3 shows the relationship between the water content ratio of the target soil and the hydraulic conductivity. The amount of bentonite added is constant at 100 kg / m ³ . Regarding sandy soil, the hydraulic conductivity was almost constant without being affected by the water content of the target soil. For the cohesive soil, the permeability is almost constant if a certain moisture content is maintained, but the permeability tends to converge as the moisture content increases.

FIG. 4 shows the relationship between the compaction density of the bentonite mixed soil and the hydraulic conductivity. This is an experiment in which a specimen is manufactured by changing the number of times of compaction.
The amount of bentonite added was 80, 10 for the No. 6 sample.
0, 120kg / m ³ , 180, 200kg / m for No. 7 sample
^{It was set to 3} . The water content is the natural water content. In all cases,
As the compaction density increases, the permeability decreases. That is, it is understood that sufficient compaction is necessary to improve the water blocking effect. In addition, similarly to FIG. 2, it can be seen that by adding a large amount of bentonite, a sufficiently low water permeability can be obtained even with a small compaction energy.

FIG. 5 shows the results of an experiment on the effect of the cement stabilization on the hydraulic conductivity. The target sample is No. 2. The amount of cement added was 3%, and the time from the addition of cement to the mixing of bentonite (curing time) was 2 hours. The permeability coefficient shows a lower value when the cement stabilization treatment is performed.

FIG. 6 shows the relationship between the curing time and the permeability in the cement stabilization treatment. The target sample is
No. 2. The amount of bentonite added was 100 kg / m ³ and the amount of cement added was 3%. After 2 hours, 1 day and 2 days of curing time after addition of the cement, bentonite was added and mixed, and the hydraulic conductivity was measured for each case. As can be seen from FIG. 6, if the curing time is within 2 hours, a low permeability is obtained, and if the curing time exceeds at least one day, the permeability increases. As already explained, the reason why the permeability increases as the curing time increases is that even if the target soil after the hardening reaction of cement is remixed, pulverization cannot be performed sufficiently, This is because hardening cannot be performed well. From the above, it can be seen that it is desirable to shorten the time from the addition of cement to mixing the bentonite as much as possible and to perform the construction promptly. In the case of this embodiment, the curing time is preferably within 4 hours.

FIG. 7 shows the relationship between the passage of time from the start of the water permeability test (water flow from above) and the water permeability coefficient. The target sample was No. 2, and the experiment was performed in a state of natural water content. The amount of bentonite added was 100 kg / m ³ . Permeability gradually decreases over time.
This is the same as the relationship between the water content and the water permeability in FIG. 3, and it is thought that the bentonite expands and the water permeability converges as the specimen absorbs water from the natural water content and the water content rises. It is.

FIG. 8 shows the results of an experiment on the restoration of the water blocking ability of bentonite. In this experiment, a bentonite mixed soil with a thickness of 5 cm (the amount of bentonite added was 120 kg / m ³ )
A layer of sand with a thickness of 10 cm was provided above and below the layer, and water was passed from above. Then, the layer of the sand and bentonite mixed soil was broken, and the water permeability was measured. After the fracture, the hydraulic conductivity increases, but decreases as the time elapses from the fracture to near the initial value. The thicker the bentonite mixed layer, the closer to the initial value.

As described above, according to the present water shielding method, even if the soil to be mixed with the ground 3 is a high water content soil, the water shielding layer 5 having reliable water shielding can be easily and economically constructed. it can.

In the present water-blocking method, the type of the water-blocking material is selected according to the type of the pond 1, the water depth, and other conditions, and the permeability and the construction thickness are changed so that the target water storage amount can be obtained. can do.

The present invention is not limited to the above-described embodiment, and various modifications can be made. For example,
In the above embodiment, the pond 1 such as a hydrophilic pond, a landscape pond, a reservoir, or a reservoir is described as an example, but the present invention is also applicable to a waste disposal site. For waste disposal sites,
The multilayer structure of the impermeable layer, the sheet and the drainage layer by the bentonite of the present invention makes it possible to complement the respective performances and minimize future leachate.

[0032]

According to the present invention, in a seepage control method for a ground where the target soil is a high water content soil, the solidified material and bentonite are sprayed almost simultaneously on the ground, and then the target soil, bentonite and the solidified material are spread on the ground. And a water-impervious layer having reliable water-impermeability can be easily and inexpensively constructed even with a high water content soil.

Further, according to the present invention, the water barrier layer sprays the bentonite between the time when the solidifying material is sprayed and the time when the hardening reaction of the solidified material starts, so that the moisture contained in the target soil is reduced to the solidified material and the bentonite. After water absorption, it is formed by mixing before hardening of the solidified material, and mixing can be performed without hindrance, and compaction after mixing can be performed sufficiently, while consolidation of soil by solidified material In addition, since the mixing is performed before the progress of the porosification, a decrease in the water permeability can be prevented.

[Brief description of the drawings]

FIG. 1 shows an embodiment of the present invention, in which (a) is a sectional view of a ground before construction, and (b) is a sectional view of a pond after construction.

FIG. 2 is a graph showing the relationship between the amount of bentonite and the permeability.

FIG. 3 is a graph showing a relationship between a water content ratio and a hydraulic conductivity of a target soil.

FIG. 4 is a graph showing the relationship between compaction density and permeability of bentonite mixed soil.

FIG. 5 is a graph showing the effect of cement stabilization on hydraulic conductivity.

FIG. 6 is a graph showing a relationship between a curing time and a hydraulic conductivity in a cement stabilization treatment.

FIG. 7 is a graph showing the relationship between the passage of time and the hydraulic conductivity.

FIG. 8 is a graph showing the restoration of the water blocking ability of bentonite.

[Explanation of symbols]

 3 ground 5 impermeable layer

Claims (2)

[Claims] In a water shielding method for a ground where the target soil is a soil with a high water content, a solidified material and bentonite are sprayed almost simultaneously on the ground, and then the target soil, bentonite and the solidified material are mixed with the ground. A water-blocking method, such as an artificial pond, characterized by forming a water-blocking layer. 2. The water-blocking layer sprays bentonite between the time when the solidified material is sprayed and the time when the hardening reaction of the solidified material starts, and after the moisture contained in the target soil is absorbed by the solidified material and the bentonite. 2. The method of claim 1, wherein the solidification material is formed by mixing before curing.