JP2001295264A - Method for adjusting characteristic of fluidized soil - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for adjusting the characteristic of fluidized soil, allowing strength after the lapse of a fixed time to be heightened while maintaining fluidity immediately after manufacture, thereby facilitating quality control and reducing cost. SOLUTION: In the fluidized soil provided with fluidity and strength by adding a hardener to treated soil, blast-furnace slag KS, ordinary Portland cement OPS which is an alkaline material, or Portland blast-furnace cement KC is added as the hardener to maintain fluidity immediately after manufacture and to adjust strength after the lapse of the fixed time.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for adjusting characteristics of fluidized soil, and more particularly to a method for adjusting characteristics of fluidized soil suitable for backfilling a tunnel, inverting a subway, and the like.

[0002]

2. Description of the Related Art Fluidized soil used for applications that do not require much strength, such as buried soil and embankment, is mixed with the soil to be treated, such as construction soil, or generated during construction foundation work. A solidifying material such as cement is added to the mud which has been mixed and disintegrated to provide a fluidity and a certain level of strength.

Conventionally, as the fluidized soil, a soil to be treated such as mud having a certain property or muddy water has been used in order to secure necessary fluidity and strength. In other words, only soil to be treated or mud having properties limited to a certain range could be used.

[0004]

However, the following problems have been encountered with the conventional flow-treated soil using only construction-generated soil and a solidifying material such as cement. First, the quality of fluidized soil is generally defined by three standard items: unconfined compressive strength, flow value as an indicator of fluidity, and bleeding rate as an indicator of volume reduction rate. However, conventionally, it has been difficult to satisfy all of these criteria.

[0005] This is because, for example, when the added amount of the solidifying material is increased for the purpose of increasing the strength, the fluidity is impaired. Conversely, in order to ensure the fluidity, the amount of water is increased to obtain a more diluted treated soil. This is because contradictory phenomena such as the necessity of having to do so occur. If the fluidity is impaired due to the increase in the amount of the solidified material, a chemical such as a fluidizing agent must be added as a secondary agent to secure the fluidity, which increases the cost.

Secondly, from the social point of view of promoting effective use of construction-generated soil and the like, when an attempt is made to produce fluidized soil using a wide variety of soils, the soil to be treated has a fine particle content. All properties are included, from low sandy soils to sandy clayey soils.

As a result, the quality of the fluidized soil greatly changes depending on whether there are many sandy soils or many clayey soils,
In addition to not being able to perform sufficient quality control, unless specially selected soil with limited properties is used, it is not possible to produce fluidized soil that satisfies the standard items, further increasing costs. Occurs.

Therefore, the present invention provides a method for adjusting the characteristics of a fluidized soil which can increase the strength while maintaining the fluidity, thereby facilitating quality control and reducing the cost. The purpose is to:

[0009]

SUMMARY OF THE INVENTION The present invention is a method for adjusting the characteristics of a fluidized soil, and is configured as follows to solve the above-mentioned technical problems. That is, the present invention is a fluidized treated soil having fluidity and strength by adding a solidified material to the soil to be treated, by adding blast furnace slag and an alkaline material, or blast furnace cement as the solidified material, It is characterized by maintaining fluidity immediately after production and adjusting the strength after a certain period of time.

As the soil to be treated, mud mixed with water generated in construction or the like or muddy mixed with muddy water generated in construction foundation work or the like can be used. Cement and the like can be used as the alkaline material, and various commercially available blast furnace cements can be used.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, an embodiment of a method for adjusting characteristics of fluidized soil according to the present invention will be described in detail with reference to the drawings.

The present invention is a fluidized treated soil having fluidity and strength by adding a solidified material to a soil to be treated, wherein blast furnace slag and cement or blast furnace cement is added as a solidified material. As a result, the fluidity can be maintained immediately after the production, and the strength can be adjusted to be high after a certain period of time.

As the soil to be treated, as in the prior art, mud mixed with water generated from construction or the like or muddy mixed with muddy water generated during construction foundation work can be used. As the blast furnace slag, a slag melt produced in a blast furnace in a pig iron manufacturing process can be used. The mixing ratio of the blast furnace slag and the cement can be appropriately set according to the strength of the fluidized soil to be developed. The more blast furnace slag,
The strength tends to increase.

It is believed that blast furnace slag rapidly forms a gel-like coating when water is added. It is considered that when a gel-like coating is formed on the blast furnace slag added to the mud, particles such as the mud and the blast furnace slag are easily separated, and the fluidity is improved.

The gel-like coating has a property of gradually dissolving when an alkali stimulus is applied. After a certain period of time, the gel-like coating is dissolved and the blast furnace slag comes into direct contact with water, so that the calcium component and water contained in the blast furnace slag react with each other to produce hydration products in the same manner as concrete. You. Thereby, the hardness of the mud is increased and the strength is increased.

At the beginning, when water was added to the blast furnace slag,
The rapid formation of a gel-like coating prevents water from penetrating further into the slag particles and prevents the formation of calcium and water hydration products of the blast furnace slag,
Fluidity is maintained.

The blast furnace slag is in the form of fine powder (specific surface area of 4,0).
(Approximately 00 cm ² / g).
In this case, an effect of suppressing bleeding (separation of mixing water caused by a difference in specific gravity of materials) can also be exerted.

Next, the blast furnace cement will be described. This blast furnace cement is obtained by mixing blast furnace slag with cement. According to JIS (R5211-1997), the blast furnace cement is classified into Class A, Class B and Class C according to the ratio of blast furnace slag to cement. Class A has a blast furnace slag content (mass%) of 5
Over 30 and below, B is over 30 and below 60, C is 6
It is more than 0 and 70 or less.

The strength of the fluidized soil increases as the amount of blast furnace slag increases. That is, the highest value is obtained when the C type is used. Also in this case, the fluidity of the fluidized soil is maintained without lowering. In the present invention, any one of Class A to Class C is used depending on the required strength of the fluidized soil.

As described above, by using blast furnace slag and cement together or using blast furnace cement as a solidifying material, the strength can be increased while maintaining fluidity. In addition, the strength can be adjusted by changing each mixing ratio.

Furthermore, when the soil to be treated is a sandy soil which is liable to cause a bleeding phenomenon, the bleeding phenomenon can be suppressed by adding a certain amount of fine blast furnace slag. By appropriately utilizing these two effects, it becomes possible to produce fluidized treated soil that satisfies the specified quality using a wide range of soil to be treated, and as a result, the effective use of construction-generated soil that is becoming a social problem Can proceed.

As described above, the present invention utilizes a gel-like coating formed by the reaction between blast furnace slag and water, and a hydration product formed by the reaction between the calcium component of blast furnace slag and water, so that it can be used during construction. It is intended to satisfy both the maintenance of the fluidity immediately after the production and the improvement of the strength after a certain period of time after the construction. In the present invention, since the soil to be treated having a wide range of properties can be used due to the large difference in the content of the fine particles, the quality control of the fluidized soil can be facilitated and the cost can be reduced.

[0023]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS As shown in FIG. 1, the content of fine particles S (75 μm or less) of mud as a soil to be treated, the mixing ratio of blast furnace slag KS, the mixing ratio of ordinary Portland cement OPC,
The properties of the fluidized soil obtained by changing the mixing ratio of the blast furnace cement KC and the mixing ratio of the water W were measured.

As a result, when the blast furnace slag KS and the ordinary Portland cement OPC were added to the mud and when the blast furnace cement KC was added, as compared with the conventional case where only the ordinary Portland cement OPC was added, It was found that the fluidity immediately after the production was maintained and the strength after a certain period of time could be sufficiently increased.

Conventionally, it has been difficult to increase the strength of the fluidized soil after a certain period of time as the content of fine particles S in the mud becomes higher. As described above, even in the test cases -4, -4, -4, and -4 in which the content of the fine particles S was as high as 70%, the strength could be considerably increased.

FIGS. 2 to 4 show test cases-4 and 4 of FIG.
In the cases of −4, −4, and −4, that is, in the test case in which the content of fine particles S is as high as 70%, the mixing ratio of water W was changed to 5 types to change the specific gravity of the whole. 5 shows various measurement results. 2 is the uniaxial compressive strength after 28 days, FIG. 3 is the flow value after 60 minutes, FIG.
Indicates the measurement result of the bleeding value after 3 hours.

The adjusted mud in FIGS. 2 to 4 is the mud before adding the solidifying material. In the production of the fluidized soil, the specific gravity of the adjusted mud is also controlled in order to control the specific gravity. Is shown on the horizontal axis. By adding a solidifying material to this adjusted mud, the degree of fluidization becomes the degree of fluidization, and the vertical axis in FIGS.
This shows the characteristics of the fluidized soil.

Further, for example, in FIG.
Is that the content of fine particles S in the fluidized soil is 10%, that OPC 70 is 70 (kg / m ³ ) of normal Portland cement, W is water, and KS50 is blast furnace cement. The ratio is 50 (kg / m ³ ), and KC70 is 70 kg / m
³ is shown.

As can be seen from FIG. 2, the blast furnace slag KS, even in the test case in which the strength is hardly developed by the conventional method among the test cases performed this time, that is, the test case in which the content of fine particles S is 70%, is obtained. By adding the ordinary Portland cement OPC or the blast furnace cement KC, the uniaxial compressive strength could be increased as compared with the conventional case.

In particular, when blast furnace slag KS and ordinary Portland cement OPC are added, the strength greatly increases, and it can be seen that the strength increase rate increases as the blast furnace slag KS increases.

FIG. 3 shows the measured flow values in the same test case as in FIG. From this figure, it can be seen that as the amount of blast furnace slag KS increases, the flow value slightly decreases, but the flow value does not decrease so much as to hinder the workability, that is, the flowability is maintained. You can see that it is done.

FIG. 4 shows a test case in which bleeding is most likely to occur among the test cases in FIG.
It shows bleeding values of 1, -1, and -1. As can be seen from the figure, as the amount of blast furnace slag KS increases, the bleeding value decreases.
That is, bleeding is suppressed.

[0033]

As described above, according to the present invention,
By adding blast furnace slag and alkaline material or blast furnace cement to the soil to be treated, a gel-like film is formed on the blast furnace slag immediately after production, so that fluidity can be maintained, and after a certain period of time, the gel-like film becomes Since it is dissolved by the alkali stimulus and a hydration product of the calcium component of the blast furnace slag and water is generated, the strength can be increased. Further, by adjusting the amount of blast furnace slag added, the strength can be adjusted. Therefore, since the soil to be treated having a wide range of properties can be used due to the large difference in the content of the fine particles, quality control becomes easy and the cost can be reduced.

[Brief description of the drawings]

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a view showing a mixing ratio of an additive component of a fluidized soil according to the present invention.

FIG. 2 is a view showing the uniaxial compressive strength of a fluidized soil according to the present invention.

FIG. 3 is a view showing a flow value of the fluidized soil according to the present invention.

FIG. 4 is a diagram showing a bleeding value of the fluidized soil according to the present invention.

[Explanation of symbols]

 KC Blast furnace cement KS Blast furnace slag OPC Ordinary Portland cement (alkaline material) S Fine fraction of soil to be treated

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme court ゛ (Reference) // C09K 103: 00 C09K 103: 00 (72) Inventor Shigeru Hayashibara 2-10-26 Fujimi 2-chome, Chiyoda-ku, Tokyo No. Maeda Construction Industry Co., Ltd. F term (reference) 2D040 AA06 AB07 BB09 CA01 CA04 CB03 2D055 CA08 JA00 KA08 4G012 PA29 PA30 4H026 CA01 CA05 CC06

Claims (1)

[Claims] 1. In a fluidized treated soil having fluidity and strength by adding a solidifying material to a soil to be treated, immediately after the production, by adding a blast furnace slag and an alkaline material or blast furnace cement as the solidifying material. A method for adjusting the characteristics of fluidized soil, comprising maintaining the fluidity of the soil and adjusting the strength after a certain period of time.