JPH1018285A - Jet grout method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To eliminate problem points such as the jet grout method requires a pit for slime disposal, a working place is easy to become dirty, in addition circumferential ground are to sink and rise by influence of impregnation of slime and discharge pressure. SOLUTION: The outside of a rod 3 for transmitting ultra-high pressure fluid for cutting and hardener liquid is surrounded by a casing pipe 2, and the discharge passage of slime is made therebetween. When the casing pipe 2 is gradually pulled up together with the rod 3 while it is rotated, the discharge passage reaching from the near of a ground excavation part to the ground by jetting is always secured, and since slime is discharged from the outlet of the discharge passage through its passage, it is directly collected in a collection vehicle and a tank.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a jet grout (ultra-high pressure jet injection) method used for a ground improvement method. More specifically, the present invention relates to a method in which slime (mucus) generated by this method is treated.

[0002]

2. Description of the Related Art In a jet grouting method, as shown in FIG. 4, a rod 3 is inserted into the ground and supplied to an ultrahigh pressure (typically 200 to 700 kgf /
cm ² ) Fluid A is jetted laterally from the nozzle at the tip of the rod to cut the ground with a jet, and the hardened material liquid B is filled in the cut part to form a solidified body (pile, etc.) for ground reinforcement in the ground. This is a construction method.

[0003] The ground is cut by an ultra-high pressure fluid using a rod 3
Is lifted up by a rough terrain crane or the like while being rotated by the column machine 22. The hardened material liquid B to be fed through the passage in the rod 3 is filled in the columnar cutting area formed by this.

This method includes a half replacement method and a forced stirring method called a CCP method. The semi-replacement method is a JSG that cuts the ground by injecting an ultra-high pressure hardener liquid with air.
(Jumbo Jet Special Grout) method and CJG (Column Jet Grout) method, in which cutting is performed with ultra-high pressure water accompanied by air and a hardening material liquid is injected from another nozzle
Are classified into two types. In these construction methods, slime C generated by cutting is discharged to the surface of the ground, and the cut soil is replaced with a hardening material liquid as much as possible.

In the slime discharge by these construction methods, the slime C is pushed up from the gap between the rod 3 and the hole surface of the guide hole 23 to the position of the pit 24 dug at the entrance of the hole by the pressure of the jet fluid. Done in a way. The slime C in the pit 24 is introduced into a storage groove 25 dug near the pit and drained, and the precipitated solid is scooped by a hydraulic shovel or the like and carried out by a dump truck. However, if the installation space for the storage groove cannot be ensured, the water is sucked and collected from the pit 24 by a sand pump or a vacuum truck.

In the JSG method, since cutting is performed with an ultrahigh-pressure hardening material liquid, a double tube having two passages for the compressed air and the hardening material liquid is adopted as the rod 3, and a blade bit is provided at the tip. A guide hole 23 having a diameter larger than the diameter of the rod is formed in the double pipe rod attached.

On the other hand, in the CJG method, since the compressed air, the ultra-high pressure water and the hardening material liquid are separately supplied, a triple pipe rod having three passages therein is employed. This rod has no excavation function, and therefore has a guide hole 23 in the CJG method.
Is perforated with a casing pipe.

The rod used in the CCP method is a single pipe rod having an excavating function. In this CCP method, a hole is excavated with a single pipe rod, the rod is inserted into the ground, and the ground is cut with an ultra-high pressure hardening material liquid spouted from a nozzle at the end of the rod. Stir and mix.

[0009]

The above-mentioned conventional jet grout method has the following problems.

(1) Storage grooves and pits for slime treatment are required. Although slime is not actively discharged by the CCP method, slime may erupt to the surface if the generated slime does not sufficiently penetrate into the surrounding strata. In such a case, the pits are formed even by the CCP method. Will be needed. In addition, even if pits are dug, slime overflows in the surroundings and the workplace is often soiled.

(2) When the ground surface layer of the constructed land is sandy soil, backfill soil, loose topsoil layer, or the like, the ground surface layer absorbs slime and softens, and the ground collapses, and ground, roads, etc. Collapse occurs.

(3) Cohesive soil is present near the surface of the construction site, slime with high viscosity occurs on the ground at the construction site, or soft clay soil exists between the construction site and the ground surface. In some cases, the ground may be raised by the slime discharge pressure. In addition, when the slime discharge resistance is large, the formation depth may not be particularly large in the JSG method in which the fluid injection pressure is lower than that in the CJG method.

An object of the present invention is to eliminate these problems.

[0014]

In order to solve the above-mentioned problems, according to the present invention, a rod inserted into the ground is rotated and pulled up from a nozzle at the tip of the rod to be supplied through a passage in the rod. In a jet grouting method in which an ultra-high pressure fluid is jetted to cut the ground with a jet, a cutting portion is filled with a curing agent liquid supplied through a passage in the rod to form a solidified body in the ground, An external pipe that is pulled up with the rod is arranged outside, and a discharge path is created between the external pipe and the rod from the vicinity of the cutting section to the ground, and the slime generated by cutting by the jet flow is discharged through the discharge path. They were to be recovered from the road.

In this method, it is more desirable to collect the slime by suction through the discharge path. It is also desirable that slime is once collected in the tank by using a tank and a slide telescopic pipe described in an embodiment described later.

[0016]

[Function] Since an external pipe is provided to create a slime discharge path between the rod and the rod, and slime is directly collected from the discharge path,
No pits or storage grooves for slime treatment are required, and slime does not overflow to the periphery.

Further, since the outer pipe acts as a shielding wall, slime is not sucked into the surrounding stratum, and slime discharge pressure is not applied to the surrounding stratum, so that the surrounding ground is not depressed or raised.

Further, the slime in the discharge path can be collected by suction. In this case, the shortage of the slime pumping pressure can be compensated by the suction force, so that the slime can be formed even if the depth becomes deeper than the present.

In addition, since the casing pipe used for drilling the guide hole in the CJG method can be used as an external pipe, the operation is not complicated.

[0020]

FIG. 1 shows an embodiment of a jet grout method according to the present invention. 1 is a boring machine, 2 is a casing pipe having a drill bit at its tip,
3 is a rod passing through the casing pipe 2 and 4 is a monitor of the tip of the rod 3 and 5 is an upper end (rear end) of the rod 3
A swivel joint 6 is mounted on the upper end of the casing pipe 2.

FIG. 3 shows the details of the swivel joint mounting portion and the monitor portion. This is an improvement of the cutting equipment used for the CJG method for the method of the present invention. C
The rod 3 used in the JG method is a triple pipe. The hole of the first pipe, counted from the inside, is the passage 7, the passage between the first and second pipes 8, the second and third pipes. The space is used as a passage 9.

As shown in FIG. 3A, the swivel joint 5 has an ultrahigh-pressure water inlet 10 and a compressed air inlet 11.
And a hardening material liquid inlet 12, through which ultra-high pressure water, compressed air, and hardening material liquid introduced from the inlets are separately passed.

The monitor 4 is, as shown in FIG.
A super hard nozzle 13, an air nozzle 14 surrounding it concentrically, and a hardening material nozzle 15 are attached to the tip of the rod 3, and the ultra-high pressure water passed through the passage 7 passes through the nozzle 13 through the passage 8. The compressed air that has passed through the nozzle 14 passes through the passage 9
The hardening material liquid such as cement milk that has passed through the nozzles is jetted laterally from the nozzles 15. Here, in order to increase the cutting efficiency, an improved monitor having two nozzles 13 and 14 is used. However, the nozzles 13 and 14 need only be directed to one each.

As described above, the fluid is ejected by gradually lifting the rod 3 while rotating it. The rod 3 may be lifted by a rough terrain crane or the like. At this time, the casing pipe 2 is pulled up together.

Guide digging is performed to the planned depth while pouring water is flowed through the casing pipe 2. Conventional CJG
In the construction method, a casing pipe is pulled out after digging a guide hole, but in the present invention, a rod 3 is inserted into the pipe 2 while leaving the casing pipe 2, and slime is inserted between the rod 3 and the casing pipe 2. A discharge path 16 (see FIG. 3) is created.

After the rod 3 is inserted, the casing pipe 2 is pulled up so that the monitor 4 at the tip of the rod preferably comes off by about 1 m, and the swivel joint 6 is attached. With this swivel joint 6, the casing pipe 2
Is closed, and the pulling force of the rod 3 is transmitted to the casing pipe 2.

The swivel joint 6 is provided with an outlet 17 of a discharge passage 16 (see FIG. 3A), and slime generated by ground cutting passes through the discharge passage 16 to the outside from the outlet 17. . Therefore, a hose or the like is connected to the outlet 17 and the slime is directly collected by a collection vehicle or the like. If the collection vehicle is a vacuum vehicle, slime will be discharged smoothly, but if slime flows out without suction,
It may be collected in a tank truck or the like.

FIG. 2 shows a second embodiment. In the present invention, since the cutting is performed while pulling up the casing pipe 2 together with the rod 3, the position of the outlet 17 is gradually raised. Therefore, when a slime is collected by connecting a vacuum hose to the outlet 17, the swivel joint 5
A thick vacuum hose is pulled up together with a high-pressure hose (not shown) for fluid supply connected to the fluid supply. The flexible vacuum hose sways greatly due to the impact as the slime is sucked and passed, which causes the connection of multiple pipes (the combination of rod 3 and casing pipe 2 is referred to herein as multiple pipes). And other connection parts may be adversely affected. The second embodiment addresses this problem.

In this method, a tank 18 is provided near the casing pipe 2. The tank 18 and the swivel joint 6 are connected by a slide telescopic pipe 19 having one end connected to the tank 18 and the other end connected to the outlet 17 of the swivel joint 6 so as to be vertically pivotable. Is collected in the tank 18 through the pipe 19. The pipe 19 slides as the multiple pipes are raised, and gradually expands.

When this method is used, the impact at the time of discharging the slime is sucked into the pipe 19, and the pipe 19 does not shake largely. Further, the telescopic pipe 19 shown does not hang down unlike the vacuum hose and does not hinder the work. Furthermore, since the slime is once collected in the tank,
Work can proceed even if the collection vehicle has not arrived at the site.

The tank 18 is provided with an air regulating valve 20 and a slime outlet 21. When the slime collected in the tank 18 is sucked out by a vacuum truck or the like, or when the slime is discharged toward the tank only by the pressure feeding pressure, the operation is performed by opening the air regulating valve 20. When the air regulating valve 20 is provided, the inside of the tank 18 can be sucked from there to make a negative pressure, and the slime in the discharge passage (16 in FIG. 3) can be sucked up by the negative pressure.

The method of the present invention is applied to CJG, JS
It can be effectively applied to any of the methods G and CCP. Although the multiple pipe of the embodiment is a quadruple pipe in which a casing pipe is added to a triple pipe rod for the CJG method, the multiple pipe when applied to the JSG method is a double pipe rod (which has no excavation function). It can be a triple pipe with a casing pipe added.

In addition, when applied to the CCP method, the multiple pipe is a double pipe in which a casing pipe is added to a single pipe rod (the drilling function is also unnecessary). When the method of the present invention is used for the CCP method, slime is actively discharged and C
The CP forced stirring method is changed to the half replacement method.

[0034]

As described above, according to the present invention, a slime discharge path surrounded by an external pipe is provided and slime is directly collected therefrom, so that it is not necessary to dig a pit or a storage groove for slime treatment. The construction work can be simplified and the construction cost can be reduced. In addition, the slime does not overflow to the surroundings, and the work environment can be kept clean.

Further, even if the surrounding ground is soft or clayy, the surrounding pipes are prevented from impregnating the slime and applying slime discharge pressure by the shielding effect of the external pipe, so that the surrounding ground is depressed. No bumps occur, and the reliability of the construction method is increased.

Slime can be collected by suction, and in this case, the formation depth can be further increased.

Further, according to the method of once recovering slime in a tank using a slide telescopic pipe and a tank,
It is not necessary to connect a vacuum hose hanging at the operator's feet to the multiple pipes due to the large sway caused by the impact at the time of slime discharge, so the connection of the multiple pipes and the connection of the fluid hose to the multiple pipes are effectively protected The life of the construction equipment is prolonged and work is facilitated.

[Brief description of the drawings]

FIG. 1 is a diagram showing an embodiment of a jet grouting method of the present invention.

FIG. 2 shows another embodiment.

FIG. 3 is a view showing an example of a multi-tube used in the method of the present invention, wherein (a) shows a swivel joint mounting portion of the pipe;
(B) shows a monitor unit.

FIG. 4 is a diagram showing an outline of a conventional CJG method.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Boring machine 2 Casing pipe 3 Rod 4 Monitor 5, 6 Swivel joint 7, 8, 9 Passage 13 Carbide nozzle 14 Air nozzle 15 Hardening material nozzle 16 Discharge path 18 Tank 19 Slide telescopic pipe 20 Air control valve 21 Slime outlet

Claims (3)

[Claims] 1. A rod inserted into the ground is rotated, and while pulling up, an ultra-high pressure fluid supplied from a nozzle at the tip of the rod to be supplied through a passage in the rod is jetted to cut the ground with a jet, and the cut portion is cut. In a jet grouting method of filling a hardener liquid to be supplied through a passage in a rod to form a consolidated body in the ground, an external pipe that is pulled up together with the rod is arranged outside the rod, and the external pipe and A jet grouting method characterized by forming a discharge path from near the cutting portion to the ground between the rod and the ground, and collecting slime generated by cutting by the jet through the discharge path. 2. The jet grouting method according to claim 2, wherein the slime is sucked and collected through the discharge path. 3. A swivel joint having an outlet of the discharge passage is attached to an upper end of the outer pipe, a tank is provided near the outer pipe, and one end is connected to the tank and the other end is connected between the tank and the swivel joint. The jet grout method according to claim 1 or 2, wherein the slime is temporarily collected in the tank by connecting the slime to the discharge path outlet of the swivel joint by a slide telescopic pipe which is respectively connected to the swivel joint so as to be able to turn up and down.