JPH09235723A - Method for improving construction of weak ground - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the cost of the execution of works by charging treated soil, in which a high-molecular solidifying agent is added and mixed to a weak mud and nodulized and solidified, into a casing penetrated into the ground and extracting the casing. SOLUTION: A high-molecular solidifying agent is added and mixed to weak mud 1 consisting of surplus soils discharged by excavation construction works and agitated, and the weak mud 1 is nodulated and solidified and treated soil 3 is formed. A casing 4 having a hopper 5 in an upper section is penetrated into the ground by an exciter 6, and treated soil 3 is charged into the hopper 5 and thrown away into the casing 4 through an on-off valve 5. The inside of the casing 4 is supplied with compressed air while treated soil 3 is discharged into the ground as extracting the casing 4, and a soil improving pile P' is formed. The casing 4 is drawn out in constant length, the casing 4 is lowered and the pile P' is compressed, and a soil improving pile P is shaped. The same operation is repeated, and the sufficiently compacted pile P is formed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for improving soft ground, and more particularly to a method for improving soft ground by placing a ground improvement pile on soft ground.

[0002]

2. Description of the Related Art The mainstream of ground improvement methods is
This is the so-called sand compaction pile method.

[0003] In this method, a casing is driven into a soft ground to a predetermined depth, and sand introduced into the casing,
The pile is compacted, that is, a compacted pile is formed in the soft ground by pushing up the sand and the like from the tip while pulling up the casing while squeezing the gravel or the like with a vibrator or a rod. According to the sand compaction pile method, a sufficient supporting force can be obtained for soft ground.

As a ground improvement pile using a cement-based solidifying agent, a cement-based solidifying agent is kneaded into a paste, poured into the ground, and directly mixed with the soil in the ground by stirring and mixing. There is one that forms the soil cement pile.

[0005]

However, the biggest problem with the former sand compaction pile method is that the material, sand and gravel, is so expensive that it cannot be procured domestically, and most of it is procured from foreign countries. It is the current situation. Even foreign-made ones are quite expensive. Further, during a long period of time, there is a problem that the sand compaction pile is divided along the way due to the flow pressure in the soft ground, especially in the deep layer, and the bearing capacity is lost.

[0006] In the latter soil cement pile, since the cement-based solidifying agent and the soil in the ground are stirred and mixed in the ground, it is impossible to judge whether both are sufficiently and uniformly stirred and mixed. However, because of that, there is a possibility that the supporting force may vary, and the stirring rod for stirring and mixing must be moved up and down and rotated at a considerable frequency, which is extremely complicated. .

The present invention replaces the use of expensive sand and gravel,
By using the soft mud discharged from the excavation work such as the shield construction method and the underground continuous wall construction method on the ground, the cost of the pile forming material can be reduced and the construction cost can be reduced. It is an object of the present invention to provide an improved construction method for soft ground that can make strength uniform.

[0008]

The invention according to claim 1 is
On the ground, a high-molecular solidifying agent 2 is added to and mixed with soft mud soil 1 to form aggregated solidified treated soil 3, and the treated soil 3 is put into a casing 4 that penetrates into the ground, and this casing 4 It is characterized in that the treated soil 3 therein is discharged into the ground while pulling out the soil to form a ground improvement pile P in the ground.

The present invention according to claim 1 is characterized in that a softened mud 1 is added and mixed with a polymer solidifying agent 2 on the ground to form an aggregated treated soil 3. For the soft mud 1 used in the present invention, the residual soil discharged from excavation work such as the shield construction method and the underground continuous wall construction method, or sludge accumulated on the bottom of a river or other high water content mud is used. Since the mud is unnecessary, it does not cost itself, it is very easy to procure, and the cost of construction is much lower. In addition, since the treated soil 3 is formed by adding and mixing the polymer-based solidifying agent 2 to the soft mud soil 1 on the ground, it is naturally possible to uniformly and sufficiently stir and mix, and variations occur in the mixing of both. There is no.

In this invention, the aggregated treated soil 3 is formed by adding and mixing the polymeric solidifying agent 2 to the soft mud 1, and the polymeric solidifying agent is added to the soft mud 1. When 2 is added and mixed, the component having a water absorbing function and the component having an aggregating function in the polymer-based solidifying agent 2 act on the mud 1 to promote the solidification of the mud 1, and the component having the water absorbing function, Absorbs free water in the mud 1, reduces the apparent water content of the mud 1 and promotes solidification, and the component having a coagulation function is dissolved in the mud 1 to coagulate and aggregate dispersed particles. Promote solidification. Thus, the soft mud 1 is aggregated and solidified by the water-absorbing function and the aggregating function of the polymer-based solidifying agent 2 to form the granular treated soil 3. Since each soil particle of the treated soil 3 that has been once aggregated and solidified does not absorb moisture any more, it does not return to mud again. Then
The granulated treated soil 3 has a water permeability equal to or higher than that of sand or gravel.

According to the present invention, however, the treated soil 3 granulated as described above is put into a casing 4 which is penetrated into the ground, and the treated soil 3 inside the casing 4 is pulled out while the casing 4 is being pulled out. Is discharged into the ground, and the treated soil 3 discharged into the soil absorbs the moisture in the soil to form the soil improvement pile P, so that the moisture contained in the soft soil is absorbed in the treated soil. The density of the soft ground is increased to consolidate the soft ground, whereby the consolidation of the soft ground can be effectively achieved.

According to the second aspect of the present invention, on the ground, a high-molecular-weight solidifying agent 2 is added to and mixed with a soft mud soil 1 together with an inorganic solidifying agent such as a cement-based solidifying agent to form an aggregated solidified treated soil 3, Casing 4 in which this treated soil 3 is penetrated into the ground
It is characterized in that the ground improving pile P is formed in the ground by throwing the treated soil 3 into the ground while discharging the treated soil 3 inside the ground.

According to the second aspect of the present invention, the treated soil 3 is obtained by adding and mixing the polymer-based solidifying agent 2 with the inorganic solidifying agent such as the cement-based solidifying agent to the soft mud 1 on the ground to solidify the aggregates. The above-mentioned claim 1 because it forms
The solidifying action of the polymer-based solidifying agent 2 similar to that of the invention according to the invention and the solidifying action of the inorganic solidifying agent such as the cement-based solidifying agent further exert the action as the solidifying agent, and the inorganic solidifying The effect which cannot be obtained by the agent alone can be obtained. Further, according to the present invention, the amount of the inorganic solidifying agent added can be significantly reduced.

The invention according to claim 3 is the invention according to claim 1 or 2
In the improvement method for the soft ground described above, as the soft mud soil 1, the residual soil discharged from the excavation work such as the shield construction method and the underground continuous wall construction method is used.

When the residual soil discharged from the excavation work such as the shield construction method is used as the soft mud as in the invention according to claim 3, compared to the case where the sludge deposited on the bottom of the river is used. , The mud can be easily collected and the cost is low, and the mud with relatively good soil quality can be obtained. In addition, since the residual soil discharged from excavation work is very difficult for construction personnel to dispose of, the use of such residual soil is extremely convenient for construction personnel.

The invention according to claim 4 is the method for improving soft ground according to any one of claims 1 to 3, wherein the polymer-based solidifying agent contains a natural vegetable polymer as a main component.

According to the invention of claim 4, the polymer-based solidifying agent is a solidifying agent containing a natural vegetable polymer as a main component, and since PH is neutral, it causes a problem of environmental pollution. There is nothing to do. That is, in the conventional soft ground improvement method, a large amount of a cement-based or lime-based inorganic solidifying agent is added to sand or gravel, but such an inorganic solidifying agent is added in a large amount to the treated soil. Becomes alkaline and pollutes the environment. Therefore, it is necessary to change the pH of this treated soil to neutralize it, which requires a lot of labor and time.
However, the treated soil obtained by treating the soft mud with the solidifying agent containing the natural vegetable polymer as the main component does not require the conventional neutralization treatment, and the construction cost can be further reduced.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIGS. 1A to 1D show steps of forming a solidified aggregated soil by adding a polymer solidifying agent to soft mud on the ground and mixing them.

In forming this treated soil, first,
Consists of residual soil discharged from excavation work using the field construction method, etc.
As shown in FIG. 1 (A), the soft mud 1 has, for example, a volume of 4
0m ^ThreeIt is put in the pit T of the car, and it's shown in the same figure (B).
For example, using a hydraulic excavator M, for example, 60 kg
The high-polymer-based solidifying agent 2 of the soft mud 1 in the pit T (35 m
^ThreeAnd)). Then, as shown in FIG.
The hydraulic excavator M with the stirrer K at the tip
And mix the soft mud 1 in the pit T with the polymer-based solidifying agent 2.
Stir together. Soft mud 1 in this pit T and polymer solid
The mixture with the agent becomes fluid about 15 minutes after the start of stirring.
It disappears, and it is dry after stirring for 15 to 20 minutes.
And the process can be carried out as shown in FIG.
It becomes soil 3. This treated soil 3 is loaded on a dump truck and is currently installed.
Can be transported to the field.

In the process of forming the treated soil 3, when a softening mud 1 is mixed with a polymer-based solidifying agent, the water-absorbing component and the coagulating-functioning component in the polymer-based solidifying agent 2 are added to the mud 1 respectively. The component having the function of absorbing the water and promoting the solidification of the mud 1 absorbs the free water in the mud 1, reduces the apparent water content of the mud 1 and promotes the solidification, and also has the coagulating function. Dissolves in the mud 1 and coagulates and disperses the dispersed particles to promote solidification. In this way, the soft mud soil 1 is aggregated and solidified by the water-absorbing function and the aggregating function of the polymer-based solidifying agent 2 into the granular treated soil 3. The soil particles of the treated soil 3 that have been once aggregated and solidified do not absorb water any more, and therefore do not return to mud again. Then, this granulated treated soil 3
Has water permeability equal to or higher than that of sand or gravel.

Polymeric solidifying agent 2 used for the treated soil 3
Is preferably a solidifying agent manufactured and sold by Sumitomo Seika Chemical Co., Ltd. and Sumitomo Chemical Co., Ltd. under the registered trademark "Sumirock". There are # 100 to # 400 (trade name) and the like as the solidifying agent of the registered trademark "Sumirock", but in this embodiment, # 200 is used first. The registered trademark "Sumirock" has a natural vegetable polymer as a main component, is composed of the natural vegetable polymer and a synthetic polymer, and has PH of 6.5 to 7.5 and is neutral.

The results of the property test of the treated soil 3 by using # 200 are shown in Table 1 below. In Table 1, the slump value means the inner diameter of the upper end 10c.
m, the inner diameter of the lower end is 20 cm, and the treated soil to be measured is packed into an iron cone formed to have a height of 30 cm, the cone is placed upside down on a flat plate, and the cone is gently pulled up vertically. The drop of the upper end of the treated soil is measured in cm (slump test), and the measured value is called the slump value. The smaller the slump value, the better the solidification state of the treated soil. Incidentally, the soft mud soil 1 before being treated with the polymer-based solidifying agent 2 has a slump value of 20 to 26, cannot be transported, and cannot be used as a pile forming material.

As is clear from Table 1 above, the treated soil 3 obtained by using # 200 has a slump value of 0 cm,
The solidified state is very good, and the particle size is 10 mm at the maximum, so the water permeability is also good, and the PH is 8.5, which is neutral. Therefore, it is optimal as a ground improvement material for forming a ground improvement pile.

Table 2 below shows the addition amount of the polymeric solidifying agent 2 (# 200, PH7) to soft mud. This mud is sandy soil with a water content of 30-70.
%. From Table-2, in the case of mud with a water content of 30%, 1
be added polymeric solidifying agent 2 m ³ per 1 kg, good processing soil 3 was obtained in the solidified state, in the case of water content 50% mud is, 1 m ³ per 2kg of approximately polymeric solidifying agent If two additives, good processability soil 3 is obtained, in the case of water-containing 70% rate mud, by adding a polymeric solidifying agent 2 of about 4kg per 1 m ^3, good treated soil 3 It can be seen that

The graphs of FIGS. 4 and 5 show the addition amount of the polymer solidifying agent 2 (# 200, PH7) with respect to the PH value of mud having a water content of 30% and 30%. According to the graph of FIG. 4, when the water content of the mud is 30% and the PH value of the mud is 7, if about 1 kg of the polymeric solidifying agent 2 (# 200) is added per 1 m ³ of the mud, , Neutralized treated soil 3 was obtained, and PH value of mud was 10
In case of, about 2.5 kg of polymer solidifying agent 2 per 1 m ³
Is added, and when the PH value is 12, 1 m ³
It shows that about 6 kg of the polymer-based solidifying agent 2 should be added. FIG. 5 shows the case where the water content of the mud is 50%, and when the pH value of the mud is 7, it is neutralized by adding about 2 kg of the polymer solidifying agent 2 per 1 m ³ of the mud. 1 when the treated soil 3 is obtained and the PH value of the mud is 10.
This indicates that about 4 kg of the polymer-based solidifying agent 2 should be added per m ³ .

The polymer-based solidifying agent 2 using # 200 of the registered trademark "Sumirock" has been described above. The polymer-based solidifying agent 2 made of # 400 is a cement-based or lime-based solidifying agent. When used in combination with the above, the effect as a solidifying agent is further exhibited, and an effect that cannot be obtained by using an inorganic solidifying agent such as a cement-based or lime-based solidifying agent alone can be expected.

Table 3 below shows the case where # 400 polymer solidifying agent 2 and lime solidifying agent were not added at all (Experiment No.
1), the case where the treated soil 3 is formed by adding only the lime-based solidifying agent to the soft mud without using the # 400 polymer-based solidifying agent 2 (Experiment No. 2), and the # 400 polymer-based 3 shows three experimental results in the case of treating soft mud by using solidifying agent 2 and a lime-based solidifying agent in combination to form treated soil 3 (Experiment No. 3).

Referring to Table 3 above, in the case where the solidifying agent of Experiment No. 1 was not used at all, the slump value was high, the condition of the treated soil was very bad, and it was unusable. 2
In the case of, that is, when only the lime-based solidifying agent was added to the soft mud to form the treated soil 3, the slump value was 1.1 cm,
State of the treated soil is almost good, mud 1 m ³ per 10
Since 0 kg of lime-based solidifying agent is required, the treated soil becomes very expensive. And in the case of Experiment No. 3, # 40
When the soft mud is treated by the combined use of the polymer-based solidifying agent 2 of 0 and the lime-based solidifying agent to form the treated soil 3, the slump value is as small as 0.2 cm, and the solidified state of the treated soil Is extremely good, and moreover, 1 kg of the polymer-based solidifying agent and 50 kg of the lime-based solidifying agent are required per 1 m ^{3 of the} mud. Thus, in the case where the polymer-based solidifying agent 2 of # 400 and the lime-based solidifying agent are used in combination, as compared with the case where the treated soil 3 is formed by adding only the lime-based solidifying agent to the soft mud, There is an advantage that the cost of the treated soil 3 can be significantly reduced. # 40
Although the experimental result in the case of using the polymer-based solidifying agent of 0 and the cement-based solidifying agent in combination is not shown, the cost of the treated soil 3 can be largely reduced also in this case as in the above case.

Next, an example of the method of the present invention will be described with reference to FIG. In the pile forming apparatus shown in FIG. 2, a hopper 5 is provided on the upper portion of the casing 4, and a vibrator 6 is attached to the upper end portion thereof. The casing 4 is penetrated into the ground by the vertical vibration action of the exciter 6. In the communication passage between the hopper 5 and the casing 4, for example, an on-off valve a which is normally held in a closed position by a spring (not shown) is provided.
Is provided, and when the treated soil 3 is introduced into the hopper 5 and flows down in the hopper 5, the opening / closing valve a is opened by the flow pressure thereof. An air supply nozzle (not shown) that supplies compressed air into the casing 4 is provided so that the inside of the casing 4 is kept at a high pressure when the on-off valve a is closed so that the treated soil 3 inside is easily discharged. . The pile forming device is suspended by a lifting operation wire (not shown) that is suspended from the top of a leader (not shown).

In carrying out the method of the present invention, the pile forming device is suspended from the top of the leader via a lifting wire, and the exciter 6 is operated to vertically vibrate the casing 4 while lifting the lifting wire. This casing 4 is penetrated into the ground while feeding out (see and in FIG. 2). Then, when the casing 4 reaches a predetermined depth in the ground, the operation of the exciter 6 is stopped, and as shown in FIG. 2, the treated soil 3 is put into the casing 4 from the hopper 5 by a required amount. . As described above, the treated soil 3 is obtained by adding and mixing a predetermined amount of the polymeric solidifying agent (# 200) to the soft mud to solidify the aggregate, or the soft soil is a predetermined amount of the polymeric solidifying agent 2 ( # 400) is added and mixed with a predetermined amount of cement-type or lime-type solidifying agent to solidify the aggregate. The treated soil 3 may be put into the casing 4 when the casing 4 penetrates into the ground.

After the treated soil 3 is put into the casing 4 in this way, compressed air is supplied into the casing 4 and the lifting operation wire is wound while the inside is pressurized to about 1 kg / cm ² . While operating, the casing 4 is pulled out, the treated soil 3 inside the casing 4 is discharged from the lower end portion thereof into the ground, and the ground improvement pile P ′ is formed as shown in FIG. Then, after pulling out the casing 4 for a certain length, the casing 4 is lowered by about half of the pulling length while operating the exciter 6 while feeding out the lifting operation wire again to compress the ground improvement pile P '. , The ground improvement pile P whose diameter is expanded as shown in FIG.
To form After that, the above-described operation is repeated to form the fully improved soil improvement pile P in the soil (see and in FIG. 2).

3 to 3 show the construction sequence by the pile forming apparatus having another structure. In the construction apparatus shown in FIG. 3, the outer rotary casing 7 and the inner fixed casing 8 are provided.
When the penetration into the ground, the outer casing 7 and the inner casing 8 penetrate into the ground while the rotating casing 7 rotates, and when the predetermined depth is reached, the treated soil 3 is transferred from the inner casing 8 into the ground. To the inner casing 8 while rotating the outer casing 7 in the reverse direction or without rotating, and in the process of pulling the outer casing 7, the discharge of the treated soil 3 inside the casing is promoted by the vibration force of the vibrator 9 (vibroflot). And, it is designed to be compacted. 2 is also a publicly known forming apparatus shown in FIG. 3, and it goes without saying that the present invention is not limited to the adoption of this forming apparatus.

The treated soil 3 used in the method of the present invention is prepared by adding and mixing the softening mud 1 with the polymeric solidifying agent 2, or by adding the softening mud 1 with the polymeric solidifying agent 2 to a cement-based or lime-based inorganic solidified material. It is a granular soil solidified by adding and mixing with the agent, and each soil particle itself of the granular treated soil 3 once solidified does not absorb water any more.
It does not return to mud again, and the granulated treated soil 3 has a water permeability equal to or higher than that of sand or gravel. Therefore, the treated soil 3 is discharged from the casings 4 and 8 into the ground to form a compacted soil-improving pile P, so that the interstitial water between the soil particles in the surrounding soil is absorbed and the water content of the soil in the soil is increased. As well as
Increase the volume of the pile P itself. As the ground improvement pile P expands in this manner, the surrounding ground is consolidated, and the consolidation strengthens the ground strength.

[0034]

According to the invention of claim 1, instead of using sand or gravel as a conventional method as a material for forming a soil improvement pile, a polymer solidifying agent is added and mixed to soft mud. The treated soil that has been solidified into aggregates is used as the soft mud, and the soft mud is the residual soil discharged during excavation work such as the shield construction method and underground continuous wall construction method, or the sludge accumulated on the bottom of rivers ( Since sludge) and other high water content mud can be used, it is extremely easy to procure and
The cost of the polymer itself is low, and the polymer-based solidifying agent used for the treatment of this soft mud is expensive, but the amount used is about 1 to 10 kg per 1 m ^{3 of} mud (of soft mud). The amount of material is different depending on the water content, etc.), and considering that sand or gravel is not used, the material cost can be greatly reduced compared to the conventional method, and its economic cost is extremely great.

Further, since the treated soil is formed by adding and mixing the polymeric solidifying agent to the above soft mud on the ground, it is naturally possible to uniformly and sufficiently agitate and mix, and variations occur in the mixing of both. Never.

Further, the treated soil used in the present invention is a treated soil which is aggregated and solidified by the water-absorption function and the coagulation function of the polymer-based solidifying agent, and has been granulated. Since each soil particle of soil does not absorb moisture any more, it does not return to mud again, and since this treated soil that has been granulated has water permeability equal to or higher than that of sand or gravel, It is most suitable as a material for forming soil improvement piles.

In the present invention, however, the treated soil granulated as described above is put into the inside of the casing that penetrates into the ground, and the treated soil inside the casing is pulled out while the casing is being pulled out. Since the treated soil discharged into the ground absorbs moisture in the ground to form a soil improvement pile, the moisture contained in the soft soil is absorbed into the treated soil, and the density of surrounding soft ground is increased. It is possible to effectively achieve the consolidation of soft ground.

According to the second aspect of the present invention, a high-polymer solidifying agent is added to and mixed with soft mud on the ground together with an inorganic solidifying agent such as a cement solidifying agent to form aggregated solidified treated soil. Therefore, the action as a solidifying agent is further enhanced by the aggregate solidifying action of the same polymeric solidifying agent as in the above-described invention according to claim 1 and the solidifying action of the inorganic solidifying agent such as cement-based solidifying agent. The effect is further exerted, and an effect that cannot be obtained by the inorganic solidifying agent alone can be obtained. And
In particular, according to the present invention, the amount of the inorganic solidifying agent added may be about half as compared with the case where the inorganic solidifying agent is used alone. Therefore, even if the high molecular solidifying agent is expensive, compared with the conventional method. The material cost can be significantly reduced.

According to the third aspect of the present invention, by using the residual soil discharged from the excavation work such as the shield construction method as the soft mud, compared with the case of using the sludge accumulated at the bottom of the river, The mud can be collected easily and the cost is low, and mud with relatively good soil quality can be obtained. Also,
Since the residual soil discharged from excavation work is very difficult for construction personnel to dispose of, the use of such residual soil is extremely convenient for construction personnel.

According to the invention of claim 4, the polymer-based solidifying agent is a solidifying agent containing a natural vegetable polymer as a main component, and since PH is neutral, it causes a problem of environmental pollution. Never. That is, in the conventional method, a large amount of a cement-based or lime-based inorganic solidifying agent is added to sand or gravel, but such an inorganic solidifying agent causes the treated soil to become strongly alkaline because it is added in large amounts. , Because it pollutes the environment,
It is necessary to change the pH of this treated soil to neutralize it, which requires a great deal of labor and time. However, the treated soil obtained by treating the soft mud with the above-mentioned polymer-based solidifying agent does not require such a neutralization treatment and has the effect of further reducing the construction cost.

[Brief description of drawings]

1 (A) to 1 (D) are explanatory views showing a process of forming treated soil used in the method of the present invention.

FIG. 2 is an explanatory diagram showing an example of a construction example of the present invention.

FIG. 3 is an explanatory diagram showing another example of a construction example of the present invention.

FIG. 4 is a graph showing the amount of addition of the polymer-based solidifying agent with respect to the PH value of soft mud, which is the case where the water content of sandy mud is 30%.

FIG. 5 is a graph showing the addition amount of the polymer-based solidifying agent with respect to the PH value of soft mud, which shows that the water content of sand mud is 50%.
Is the case.

[Explanation of symbols]

 1 Soft Mud 2 Polymer Solidifying Agent 3 Treated Soil 4 Casing 5 Hopper 6 Exciter 7 Outer Casing 8 Inner Casing P Ground Improvement Pile

Claims (4)

[Claims] 1. A treated soil obtained by adding and mixing a polymeric solidifying agent to soft mud on the ground to form aggregate-solidified treated soil, and the treated soil is put into a casing that penetrates into the ground. This is a method for improving soft ground, in which the treated soil inside is discharged while pulling out to form a ground improvement pile in the ground. 2. On the ground, a high-polymer solidifying agent is added to and mixed with soft solid mud together with an inorganic solidifying agent such as a cement solidifying agent to form aggregated solidified treated soil, and the treated soil is penetrated into the ground. A method for improving soft ground, in which the ground is piled into the casing, the treated soil is discharged into the ground while pulling out the casing, and a ground improvement pile is formed in the ground. 3. The method for improving soft ground according to claim 1 or 2, wherein as the soft mud, residual soil discharged from excavation work such as a shield construction method is used. 4. The method for improving soft ground according to claim 1, wherein the polymer-based solidifying agent contains a natural vegetable polymer as a main component.