JP3108757B2 - Pneumatic caisson sinking method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for laying a pneumatic caisson.

[0002]

2. Description of the Related Art The pneumatic caisson method is, as is well known, provided with a floor plate at the bottom of a box, an airtight working room below the floor plate, and excavating below the floor plate while sending compressed air thereto.
The pneumatic caisson body is settled by its own weight or loaded load, but the point is to ensure that it is settled vertically to a predetermined depth.

[0003] Underground water that enters the working chamber when the working pressure is kept lower than the theoretical pressure is drained by installing a submersible pump, and when the pneumatic caisson is sunk in the bedrock, The rocks are crushed by blasting and excavated, but the slippage is performed using an unloading bucket.

[0004]

When a pneumatic caisson is laid on a ground having a soft stratum on a sloping bedrock, the ground support force of the caisson blade becomes uneven during the digging, and the caisson May easily be inclined, and it may be difficult to settle vertically.

If the working pressure is kept lower than the theoretical pressure, drainage efficiency is not good because groundwater infiltrates into the working chamber, and it takes time to put blasts into the dumping bucket. Workability was not good.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned disadvantages of the prior art, and when a pneumatic caisson is laid on a ground having a soft stratum on a sloping bedrock, the ground support of the caisson blade opening during the sinking is provided. Equalizing the force, preventing the caisson from tilting, lowering the groundwater level in the working room, lowering the working pressure, increasing the effective working time, and improving the efficiency of blast debris removal Another object of the present invention is to provide a pneumatic caisson sinking method.

[0007]

SUMMARY OF THE INVENTION In order to achieve the above object, the present invention firstly provides a pneumatic caisson for laying a pneumatic caisson on a ground having a soft stratum on a sloped rock. Prior to the construction of the skeleton, the replacement wall was constructed by drilling immediately below the caisson cutting edge, and the leading pit wall was drilled in the soft soil layer at the center of the replacement wall,
The leading pit wall is penetrated to form a leading pit on the bedrock, a caisson skeleton is installed, and in the soft soil layer portion, the caisson skeleton is digged by excavating while functioning as a slip pit in the preceding pit wall, In the bedrock, the preceding pit functions as a free surface for blasting, and by functioning as a slip pit, a caisson is laid while excavating the inner wall side of the replacement wall. Second, the replacement wall is made of clay mortar or Third, the preceding pit is provided with a corrugated pipe and a mortar to prevent the collapse of the wall surface in the soft stratum portion, so that the wall surface is prevented from being collapsed. The gist is to remove the caisson when it sinks.

According to the first aspect of the present invention, the replacement wall formed at the caisson blade allows the ground support force of the caisson blade during subsidence to be equalized, thereby preventing inclination. In addition, since the replacement wall functions as a water blocking wall, the groundwater level in the working room can be reduced.

Further, a hole for charging an explosive is drilled,
The bedrock is blown up by charging, and in this case, the preceding pit can be made to function as a free surface of blasting by blasting around the preceding pit.

According to the second aspect of the present invention, in addition to the above functions, the displacement wall is formed of clay mortar, so that the strength is low enough not to hinder the settlement of the caisson and functions as a water stop wall. It can have a sufficient strength.

According to the third aspect of the present invention, the displacement wall is formed of fiber-mixed clay concrete in which clay and fiber are mixed with ordinary concrete, so that in addition to the function of the second aspect, the presence of gravel is reduced. The strength change in the depth direction can be small, the presence of the fiber has high water barrier, can secure the integrity of the joint, and is strong in toughness and excellent in impact resistance Things. In particular, compared to clay mortar, there is less concern about water pollution in seawater, and it can be properly disposed during excavation, excelling in environmental protection. Is also good.

According to the fourth aspect of the present invention, in addition to the above function, the leading pit is provided with a corrugated pipe and a mortar in the soft stratum to prevent the collapse of the wall surface. The caisson sinks while being removed, so it does not hinder the settlement.

[0013]

Embodiments of the present invention will be described below in detail with reference to the drawings. 1 to 12 show a process diagram of a method of laying a pneumatic caisson of the present invention. In the present invention, a pneumatic caisson is laid on a steeply sloping rock as shown in FIG. Fresh rock of steep rock mass, 2 is weathered rock of the upper layer of the fresh rock 1, 3 is sedimentary soil, and 6 is groundwater table. And this water table 6
As is clear from the position, the ground to which the present invention is applied has a high groundwater level.

When a pneumatic caisson is laid in such a sloping rock area, the first step shown in FIG.
As shown in FIG. 3, a hole immediately below the caisson blade to be sunk is pre-drilled, and as a second step, a replacement wall 7 is constructed as shown in FIG. As a method for constructing the replacement wall 7, for example, a rock is excavated by a casing rotary excavation method using a casing rotary excavator (see FIG. 2), a clay mortar is poured into the hole 8, and the casing is pulled out. Clay mortar replacement wall 7
(See FIG. 3).

The strength of the clay mortar forming the replacement wall 7 is low enough not to hinder caisson subsidence excavation, and strong enough to function as a water blocking wall.

Next, as a third step, as shown in FIG. 4, the leading pit wall 9 is drilled at the center position of the replacement wall 7 by using a rotary drilling method using a large-diameter drilling machine. The preceding pit wall 9 is built in the soft soil layer portion of the sedimentary soil 3 and the weathered rock 2 and functions as a deep well and as a slip pit, and prevents the wall surface of the preceding pit wall 9 from collapsing. To this end, for example, a retaining wall is provided with a mortar 11 using the corrugated pipe 10 as an inner mold. Alternatively, after the hole is drilled to a predetermined depth, the inside of the hole is back-filled with sand before removing the casing to prevent the wall from collapsing.

As a fourth step, as shown in FIG. 5, the preceding pit wall 9 built in the soft soil layer portion is penetrated, and a casing one size smaller than this is used to make the bedrock of the fresh rock 1 into the bedrock. The preceding pit 12

If the replacement wall 7, the preceding pit wall 9, and the preceding pit 12 have been constructed before the caisson was laid as described above, the opening of the preceding pit wall 9 as shown in FIG. Is cured with a lining plate 13 and a vinyl sheet 14, and a caisson blade fitting 15 is installed to construct a center. In this case, the central part 16a of the general part is earth and sand centure, and the central part 16b of the opening part is a tree centure.

Next, a reinforcing bar and a formwork are assembled on the upper part of the blade fitting 15, and as a sixth step, one lot for forming a blade as shown in FIG. Further, the shaft 18 such as a man shaft and a material shaft and the lock 19 such as a man lock and a material lock are outfitted.

As a seventh step, as shown in FIG. 8, the wooden centur 16b at the opening is removed and the caisson frame 17 is removed.
For example, an overhead traveling caisson excavator 20 is mounted as an excavating machine in a work chamber 21 of the
22 is suspended, and the sediment sentry of the sentur 16a in the general part is removed.

Next, the caisson frame 17 is started to be laid down. First, as an eighth step, air is supplied into the work chamber 21 through the lock 19 and the shaft 18, and the soft stratum of the sedimentary soil 3 and the weathered rock 2 is excavated by the caisson excavator 20, and the clay of the replacement wall 7 is The caisson skeleton 17 is settled while excavating the mortar, and when the caisson skeleton 17 is sunk for a predetermined length, the next lot is built on this and the discharging is performed by the discharging bucket provided in the preceding pit wall 9.
It is put into 22 and discharged from the shaft 18 to the ground. By repeating this, the caisson frame 17 is laid down.

In the meantime, the preceding pit wall 9 has been built in the ground in the soft stratum portion, and the preceding pit wall 9 is removed as the caisson frame 17 is laid down.

As a ninth step, as shown in FIG. 10, when the caisson blade reaches the bedrock of fresh rock 1, a hole for charging an explosive is drilled, and the bedrock is blasted by charging. In this case, by blasting the leading pit 12 as a center, the leading pit 12 can function as a free surface for blasting, and by causing the leading pit 12 to function as a slip pit, the discharging bucket arranged here can be used. 22 can be easily thrown.

After the bedrock is blown out in this way, the caisson body
17 is laid down, the skeleton is built, and this is repeated. When the caisson skeleton 17 is laid down, the ground support force of the caisson knuckle becomes uneven when the caisson knuckle reaches the bedrock due to the inclination of the bedrock, but the caisson skeleton 17 moves along the replacement wall 7. As a result, the ground support force is equalized, and the inclination of the caisson body 17 is prevented.

The replacement wall 7 also functions as a water stop wall,
The preceding pit wall 9 and the preceding pit 12 function as deep wells, and in conjunction with pumping water therefrom, the underground water level is lowered and the working pressure in the working chamber 21 can be reduced. Thereby, a long working time can be secured.

As a tenth step, as shown in FIG. 11, the caisson frame 17 is settled and the caisson frame 17 is penetrated through the sedimentary soil 3, the soft rock layer of the weathered rock 2 and the bedrock of the fresh rock 1 to a predetermined depth. 17 shows the state where it was sunk.

Next, as an eleventh step, as shown in FIG.
Collect excavation equipment such as caisson excavator 20 and earth removal bucket 22 in 21 and cast concrete 23 into working room 21 and remaining preceding pit 12 and remove outfitting such as shaft 18 and lock 19 .

Finally, grout is applied to the replacement wall 7 to secure the strength of the ground.

In a second embodiment of the present invention, the replacement wall 7 is formed of fiber-contained clay concrete obtained by mixing clay and fiber in ordinary concrete. Ordinary concrete is gravel, sand, cement and water. Table 1 shows examples of the mixing of fiber-contained clay concrete.

[0030]

[Table 1]

By forming the replacement wall 7 from fiber-contained clay concrete as described above, the presence of clay can be reduced to a low uniaxial compressive strength of 10 to 20 kgf / cm ^2. Has excellent inseparability in water.

In addition, the presence of gravel can reduce the change in strength in the depth direction, thereby enabling stable construction. In addition, the presence of the fiber has high water-blocking properties, can ensure the integrity of the joint at the seam, is strong in toughness, and can be excellent in impact resistance.

[0033]

As described above, in the method of submerging a pneumatic caisson according to the present invention, the ground support force is equalized by the replacement wall formed at the caisson blade opening, thereby preventing inclination when the caisson is submerged. . In addition, since the replacement wall functions as a water stop wall and the preceding pit functions as a deep well, the underground water level is reduced, the working pressure can be reduced, and the effective working time can be extended.

Further, by making the preceding pit function as a free surface for blasting and slip pit, rock excavation and earth discharging work can be performed efficiently.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional front view showing a state of a stratum using a pneumatic caisson laying method of the present invention.

FIG. 2 is a vertical sectional front view showing a first step of a method of laying a pneumatic caisson according to the present invention.

FIG. 3 is a longitudinal sectional front view showing a second step of the method of laying a pneumatic caisson of the present invention.

FIG. 4 is a longitudinal sectional front view showing a third step of the pneumatic caisson laying method of the present invention.

FIG. 5 is a vertical sectional front view showing a fourth step of the pneumatic caisson laying method of the present invention.

FIG. 6 is a longitudinal sectional front view showing a fifth step of the pneumatic caisson laying method of the present invention.

FIG. 7 is a longitudinal sectional front view showing a sixth step of the pneumatic caisson laying method of the present invention.

FIG. 8 is a vertical sectional front view showing a seventh step of the pneumatic caisson laying method of the present invention.

FIG. 9 is a vertical sectional front view showing an eighth step of the pneumatic caisson laying method of the present invention.

FIG. 10 is a vertical sectional front view showing a ninth step of the pneumatic caisson laying method of the present invention.

FIG. 11 is a vertical sectional front view showing a tenth step of the pneumatic caisson laying method of the present invention.

FIG. 12 is a vertical sectional front view showing an eleventh step of the method of laying a pneumatic caisson of the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Fresh rock 2 ... Weathered rock 3 ... Sedimentary soil 6 ... Groundwater surface 7 ... Replacement wall 8 ... Hole 9 ... Leading pit wall 10 ... Corrugated pipe 11 ... Mortar 12 ... Leading pit 13 ... Lining board 14 ... Vinyl sheet 15 ... Blade fittings 16a ... Centre of general part 16b ... Centre of opening part 17 ... Caisson frame 18 ... Shaft 19 ... Lock 20 ... Caisson excavator 21 ... Working room 22 ... Discharge bucket 23 ... Solid concrete

──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Eizuka Fukasawa 2-9-1-1, Tobita-Shi, Chofu-shi, Tokyo Kashima Construction Co., Ltd. (72) Inventor Toshiyuki Tanaka 2-1-1, Tobita-Shiita, Chofu-shi, Tokyo No. Kajima Corporation Technical Research Institute (56) References JP-A-6-199305 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) E02D 23/08 E02D 19/12 E02D 19/16

Claims (4)

(57) [Claims] When a pneumatic caisson is laid on a ground having a soft stratum on a sloped rock, prior to the construction of a pneumatic caisson frame, a hole is drilled immediately below the cutting edge of the caisson and replaced. Build the wall, drill the leading pit wall in the soft soil layer part at the center position of the replacement wall, drill the leading pit in the rock by penetrating the preceding pit wall, install the caisson body, In the soft soil layer portion, the caisson body is laid down by excavating while making the inside of the preceding pit wall function as a slip pit, and in the bedrock, the preceding pit functions as a free surface for blasting, and by functioning as a slip pit, the replacement wall A pneumatic caisson laying method characterized by laying a caisson while excavating the inner wall side of the building. 2. The method according to claim 1, wherein the replacement wall is formed of clay mortar. 3. The method according to claim 1, wherein the replacement wall is formed of fiber-contained clay concrete obtained by mixing clay and fiber in ordinary concrete. 4. The leading pit is provided with a retaining wall with a corrugated pipe and mortar in a soft stratum to prevent wall collapse.
The method of laying a pneumatic caisson according to any one of claims 1 to 3, wherein the retaining wall is removed when the caisson sinks.