JP3387398B2 - How to penetrate caisson foundation - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a caisson foundation penetration method.

[0002]

2. Description of the Related Art When constructing a foundation in water, in the case of a pile foundation, mechanical force such as impact or vibration can be used as a pushing force. For example, large coasts, harbors and marine structures In such a deep water foundation, such mechanical force makes it difficult to lay the foundation structure.

Therefore, in such a deep water foundation, a method of submerging the caisson by its own weight and ballast load is generally adopted. In the method of constructing such a foundation, the skirt portion provided at the lower end of the caisson is set on the bottom of the water bottom, and the weight of the caisson and the ballast load are applied to the skirt to penetrate the bottom of the bottom of the water. .

However, even in such a foundation construction method, it may be difficult to penetrate the skirt portion to a necessary rooting length only by its own weight and ballast load due to various conditions such as the condition of the submarine ground. .

In such a case, conventionally, the pressure inside the skirt portion is reduced, and the pressure difference (suction) between the skirt portion is used to penetrate the skirt portion into the subsea ground. .

However, such a caisson foundation penetration method has technical problems described below.

[0007]

That is, in the method of lowering the pressure in the skirt part and utilizing the suction of the skirt part to penetrate the caisson foundation into the water bottom ground, the hydraulic gradient by suction around the skirt part is used. Becomes larger, and in the sandy ground, the surrounding soil and sand flow into the skirt portion, so that boiling is likely to occur.

[0008] In the cohesive land, if the hydraulic gradient becomes large, partial water flow tends to occur. For this reason,
There was a problem that the inflowing earth and sand filled the inside of the skirt or a large amount of water inflowed, so that the suction did not work effectively and the penetration could not be performed efficiently.

The present invention has been made in view of such conventional problems, and an object thereof is to reduce the hydraulic gradient of the skirt portion so that the caisson can be efficiently penetrated. It is to provide a method of penetration of the foundation.

[0010]

In order to achieve the above-mentioned object, the present invention has a skirt portion provided at the lower end of a caisson in the bottom of the sea, and the caisson has its own weight, ballast load, suction load, etc. In the method of penetrating a caisson foundation for penetrating the skirt portion into the submarine ground by applying the load of, a high fluidity and viscosity are provided, and at least the outer peripheral side of the planned skirt portion is centered. After forming a water-impermeable layer having a predetermined width on the water bottom ground in advance, the skirt portion is bottomed on the water-impermeable layer, and then the skirt portion is made to penetrate the water-impermeable layer. Then, the suction load is used to penetrate into the water bottom ground. According to the method of penetrating the caisson foundation configured as described above, it has high fluidity and viscosity on the water bottom ground, and has a predetermined width at least on the outer peripheral side around the planned landing portion of the skirt portion. Since the water-impermeable layer is formed in advance, the skirt portion is bottomed on the water-impermeable layer, and then the skirt portion is penetrated through the water-impermeable layer and penetrated into the water bottom ground by suction load. The water-impermeable layer existing on the side makes the water permeation distance longer, reduces the hydraulic gradient, and prevents the inflow of sediment or water into the skirt portion. The water-impermeable layer can be selected from a mixture obtained by kneading lime fine powder and an appropriate amount of aggregate, an admixture, or a viscous substance obtained by kneading cohesive soil, lime, cement and the like. To exemplify a more specific formulation example, lime 250 to 300 kg / m3, aggregate 1500 to 1
It is 600 kg / m3, water 150 to 200 kg / m3, and admixture (separation reducing agent) 1 to 5 kg / m3.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION Preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings. 1 and 2 show an embodiment of a method for penetrating a caisson foundation according to the present invention.

According to the caisson foundation penetration method shown in the figure, the caisson 12 submerged in the subseabed 10 is
The tubular caisson body 12a and the caisson body 12a
Top plate 12b provided on the upper end side of the caisson body 12
a bottom plate 12c provided on the inner surface side of a and the caisson body 1
A skirt portion 12d integrally provided on the lower end side of 2a is provided.

On the upper side of the caisson 12, the main body 1 is provided.
2a, a top slab 12b, and a bottom slab 12c define an upper compartment 14 and a bottom slab 12c and a skirt 12d define a lower compartment 16 on the lower side. The lower end of the lower compartment 16 Is open.

A drain pipe 17 is connected to the lower compartment 16 so as to penetrate the bottom plate 12c, and the upper end of the drain pipe 17 is connected to a decompression device (not shown).

The caisson 12 thus constructed is prefabricated and towed to the submersion site to be submerged and installed in the subsea ground 10. In the present embodiment, before the caisson 12 is submerged, A water-impermeable layer 18 is formed on the water bottom ground 10.

The water-impermeable layer 18 has high fluidity and viscosity, has an outer diameter larger than the outer diameter of the skirt portion 12d of the caisson 12, and is centered on the planned bottom of the skirt portion 12d. The outer peripheral side of the skirt portion 12d is formed to have a predetermined width.

As shown in FIG. 1, the formation of the hardly water-permeable layer 18 is performed by centering on the planned bottom of the skirt 12d.
Instead of forming the skirt portion 12d in a ring shape so as to have a width inside and outside, the skirt portion 12d may be formed on the water bottom ground 10 so as to cover the entire area on the inner peripheral side of the skirt portion 12d.

Further, the shape of the water-impermeable layer 18 is important for the width of the outer peripheral side of the skirt portion 12d, and this width is, for example, the inner diameter length of the skirt portion 12d, although it varies depending on the characteristics of the water bottom ground 10. It is sufficient if there is a similar width.

The water-impermeable layer 18 can be selected from a mixture obtained by kneading lime fine powder with an appropriate amount of aggregate and an admixture, or a viscous material obtained by kneading cohesive soil, lime, cement and the like.

Illustrating a more specific formulation example, lime 2
50-300 kg / m ³ , aggregate 1500-1600 kg
/ M ³ , water 150 to 200 kg / m ³ , and admixture (separation reducing agent) 1 to 5 kg / m ³ .

Further, a gelled product obtained by dissolving guar gum and its modified products, or plant mucilage such as locust bin gum, alone or in combination, in water and adding boron or boric acid thereto has a viscosity of In addition, it has a viscosity of tens of thousands of cp on the alkali side, has a high viscosity, and has a high fluidity, and thus can be suitably used.

When the formation of the water-impermeable layer 18 having the above properties is completed, the skirt portion 12d of the caisson 12 is finished.
However, it is laid down so as to reach the bottom on the water impermeable layer 18.

Then, the tip of the skirt portion 12d penetrates the water-impermeable layer 18 and slightly penetrates into the water bottom ground 10 so that water does not enter the lower compartment 16 defined by the skirt portion 12d. To do so.

Next, as shown in FIG. 2, the inside of the lower compartment 16 is decompressed by draining the water in the lower compartment 16 through the drainage pipe 17. When decompressing the lower compartment 16,
A pressure difference (suction) is generated inside and outside the skirt portion 12d, and the skirt portion 12d is caused to penetrate into the water bottom ground 10 by a suction load utilizing this pressure difference.

At this time, if necessary, the upper compartment 14 is filled with ballast so that a ballast load acts on the skirt portion 12d. Then, when the skirt portion 12d is penetrated into the subseabed ground 10 by a predetermined length, the caisson 12 is finished to be set down, and then the structure such as the pier 20 is constructed on the top plate 12b.

According to the caisson foundation penetration method performed as described above, the water bottom ground 10 is provided with high fluidity and viscosity, and the outer periphery of the skirt portion 12d is centered around the planned landing portion. The water-impermeable layer 18 having a predetermined width is previously formed on the side, and the skirt portion 12d is bottomed on the water-impermeable layer 18, and then the caisson 12 is subjected to a ballast load or a suction load to remove the skirt portion 12d. Since it penetrates into the water bottom ground 10, the impervious layer 18 existing on the outer peripheral side of the skirt portion 12d increases the water permeation distance and reduces the hydraulic gradient, and the inflow of earth or sand or water into the skirt portion 12d. Can be prevented.

[0027]

As described above in detail in the embodiments,
According to the caisson foundation penetration method according to the present invention, the water-impervious layer existing on the outer peripheral side of the skirt portion increases the water permeation distance, reduces the hydraulic gradient, and allows the sand or water to flow into the skirt portion. Therefore, the caisson can be efficiently penetrated.

[Brief description of drawings]

FIG. 1 is an explanatory diagram of a first step showing an embodiment of a method for penetrating a caisson foundation according to the present invention.

FIG. 2 is an explanatory diagram of a process performed subsequent to the process of FIG.

[Explanation of symbols]

10 subsoil 12 caisson 12a caisson body 12b Top plate 12c bottom plate 12d skirt part 14 Upper compartment 16 Lower compartment 18 Slightly permeable layer

Continuation of front page (56) Reference JP-A-5-9940 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) E02D 23/08 E02D 23/02 E02D 23/00 E02D 27 / 18

Claims (2)

(57) [Claims] 1. A skirt portion provided at the lower end of a caisson is set in the bottom of the water bottom, and a load such as its own weight, a ballast load, or a suction load is applied to the caisson to penetrate the skirt into the bottom ground. In the caisson foundation intruding method, which has high fluidity and viscosity, a hardly water-permeable layer having a predetermined width at least on the outer peripheral side of the planned bottom of the skirt is centered on the bottom of the water. After being formed in advance, the skirt portion is bottomed on the water-impermeable layer, and thereafter,
The caisson foundation penetration method, wherein the skirt portion is penetrated through the water-impermeable layer and penetrated into the water bottom ground by the suction load. 2. The water-impermeable layer is a mixture of fine lime powder and an appropriate amount of aggregate, an admixture, or clay, lime,
The caisson foundation penetration method according to claim 1, which is selected from a viscous material obtained by kneading cement or the like.