KR101212789B1 - Piling Crane Apparatus Equipped with Sleeve Structure for Casing Pipe for Strengthening Weak Soil on Sea and Process therewith - Google Patents

Abstract

The anti-crane device for reinforcing soft ground at sea according to the present invention is installed to be fixed by a coupling structure 81 at the tip of the anti-ship vessel 10 such as a barge on which the leader 20 is installed, and a removable sleeve pipe therein. The fixed sleeve pipe 80 having a large diameter so that the 90 can penetrate up and down, and is connected by a wire rope 93 at the upper portion to move up and down along the inside of the fixed sleeve pipe 80, and a casing therein. The pipe 30 is characterized in that it comprises a sleeve structure consisting of a movable sleeve pipe 90 which serves to protect the casing pipe by moving up and down. The sleeve structure is a means for fixing the movable sleeve pipe 90, a hydraulic fixing device 92 is installed above the fixed sleeve pipe (80).

Description

Piling Crane Apparatus Equipped with Sleeve Structure for Casing Pipe for Strengthening Weak Soil on Sea and Process therewith}

The present invention relates to an anti-tacrane device for reinforcing soft ground at sea and a soft ground reinforcing treatment method using the same. More specifically, the present invention provides a new driving mechanism for protecting a casing pipe protection sleeve that can vertically generate a reinforcing column by solidification by preventing the casing pipe from being bent by algae in a deep sea or a severe seabed. It relates to a crane device and a method for strengthening the soft ground using the same.

There are two methods for strengthening soft ground at sea: Marine Foundation Jet System (MFJS) and Deep Cement Mixing (DCM).

The MFJS method is a method of forming a columnar concrete mortar column ('reinforced column') in the sea floor by injecting and drawing a multi-tube rod into the sea floor by the rotational force of the upper auger motor. The target soft ground is cut by ejecting high pressure water and air from the nozzle of the monitor attached to the bottom end of the rod (meaning the bottom end with an opening or a nozzle to discharge mortar, water, and air discharged through the rod into the ground). After discharging the mortar at a low pressure from the mortar outlet at the bottom, and at this time is to cut the fluidized raw soil to the top while filling the place with mortar to form a columnar concrete mortar column. This process has already been developed by the present inventors and has been filed in patent application No. 2010-32173 (filed Apr. 8, 2010).

In the DCM method, when the cement mortar is injected into the tip nozzle while the stirring rod and the stirring blade are rotated by the rotation force of the upper auger motor, and the cement mortar is injected into the tip nozzle, the clay and the cement mortar are well mixed to form a cylindrical cement mixing column. do. One of these methods has already been developed by the present inventor and has been filed in patent application No. 2009-5313 (filed Jan. 23, 2009).

The MFJS method and the DCM method developed by the present inventors are actively practiced because they have many advantages when applied by sea. However, the above techniques are applied at sea, and casing pipes are bent by algae in deep seabeds. The casing pipe is a pipe having a small diameter of about 10 to 20 cm in diameter and is provided in plural from the ship to form a columnar concrete column (reinforcement column) on the sea bottom. In other words, a large diameter concrete pile (reinforcement column) having a diameter of about 100 to 300 cm is formed by using a multi-pipe casing pipe lowered to the bottom of the sea. The casing pipe lowered to the sea floor is bent.

Since the casing pipe must be located exactly where the reinforcing column is to be formed, its position is determined by a position tracking device such as GPS. However, if the casing pipe is bent by the flow rate of the algae, the position is changed and the position of the reinforcement pillar is out of the original position. If the position of the reinforcement column is out of the original position can eventually lead to the sub-holes can have enormous consequences. In addition, if the casing pipe is bent and penetrated into the sea floor, the concrete reinforcement pillar is also formed obliquely and cannot support the upper load properly.

Therefore, the present inventors can prevent the casing pipe from bent by algae in deep sea or deep sea algae in the anti-crane device for reinforcing the soft ground at sea, which can produce a reinforcement column by solidification treatment at the correct position. A new anti-crane device has been developed with a sleeve structure for casing pipe protection.

It is an object of the present invention to provide a new anti-crane device provided with a casing pipe protection sleeve structure to prevent the casing pipe from being bent by algae in a deep sea or a deep sea algae in an anti-crane device for reinforcing soft ground at sea. It is to provide.

Another object of the present invention in the anti-tarcrane device for reinforcing the soft ground at sea casing pipe to form a reinforcement column in the correct position by preventing the casing pipe bent by the algae in the seabed of deep or deep algae To provide a new anti-crane device with a protective sleeve structure.

The above and other objects of the present invention can be achieved by the present invention described in detail below.

The anti-crane device for reinforcing soft ground at sea according to the present invention is installed to be fixed by a coupling structure 81 at the tip of the anti-ship vessel 10 such as a barge on which the leader 20 is installed, and a removable sleeve pipe therein. The fixed sleeve pipe 80 having a large diameter so that the 90 can penetrate up and down, and is connected by a wire rope 93 at the upper portion to move up and down along the inside of the fixed sleeve pipe 80, and a casing therein. The pipe 30 is characterized in that it comprises a sleeve structure consisting of a movable sleeve pipe 90 which serves to protect the casing pipe by moving up and down.

The sleeve structure is a means for fixing the movable sleeve pipe 90, a hydraulic fixing device 92 is installed above the fixed sleeve pipe (80).

The movable sleeve pipe 90 has a strength that does not bend even in the flow rate of the fast tidal flow, and it is preferable that a plurality of guide protrusions 91 are formed therein to allow the casing pipe 30 to move smoothly therein. .

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

The present invention is to protect the casing pipe to prevent the formation of the reinforcement pillar at an exact position by preventing the casing pipe bent by the algae in the deep sea or algae seabed in the anti-crane device for strengthening the soft ground at sea By providing a new anti-crane device equipped with the structure has the effect of the invention that can be constructed with a high quality reinforced column.

FIG. 1 is a schematic view of a conventional anti-crane apparatus in which a casing pipe is bent by an alga at a deep sea or a deep algae to form an oblique reinforcement column.
FIG. 2 is a schematic side view of the anti-crane apparatus provided with a casing pipe protection sleeve structure to prevent the casing pipe from being bent by algae in a deep or algal seabed according to the present invention.
3 is a partially enlarged view showing an enlarged casing pipe protection sleeve structure of the present invention.

The present invention is an anti-tarcrane device for reinforcing soft ground at sea, which prevents the casing pipe from being bent by algae in deep sea or deep algae to create a reinforcement column by solidification treatment at the correct position. The present invention relates to a new anti-crane device having a sleeve structure for protecting a pipe and a soft ground reinforcement method using the same.

FIG. 2 is a schematic side view of the anti-crane apparatus provided with a casing pipe protection sleeve structure so as to prevent the casing pipe from being bent by algae in a deep or algal seabed according to the present invention, and FIG. A partially enlarged view showing an enlarged casing pipe protection sleeve structure.

The anti-crane device for reinforcing soft ground at sea according to the present invention includes a fixed sleeve pipe 80 installed to be fixed to the tip of the anti-ship vessel 10 and a movable sleeve moving up and down along the inside of the fixed sleeve pipe 80. It is characterized in that it comprises a sleeve structure consisting of a pipe (90).

The fixed sleeve pipe 80 is fixed to the distal end of the helm ship 10 by the coupling structure 81, and is installed at substantially the same height as the bottom surface of the helm ship. The seabed depth of the fixed sleeve pipe is installed at about the same height as the bottom of the ship, so that the ship can move smoothly without being stranded. The fixed sleeve pipe uses a coupling structure 81 to be fixed to the front end of the helm ship 10, the coupling structure is easily implemented by those skilled in the art to which the present invention belongs. Can be.

The movable sleeve pipe 90 penetrates up and down in the fixed sleeve pipe, and the casing pipe 30 moves up and down in the movable sleeve pipe.

First, the movable sleeve pipe 90 is connected to the wire rope 93 at the top, and the air rope is wound or unwound by a winch motor installed on the helm ship 10. When the wire rope is wound, the movable sleeve pipe 90 moves upward along the inside of the stationary sleeve pipe 80, and when the wire rope is released, the movable sleeve pipe 90 moves downward along the inside of the stationary sleeve pipe.

When the movable sleeve pipe 90 is to be fixed, the hydraulic sleeve 92 installed on the fixed sleeve pipe 80 is operated to fix the movable sleeve pipe 90. Once the wire rope is stopped at the position to which the movable sleeve pipe 90 is to be fixed, the hydraulic fixing device 92 is operated to secure the movable sleeve pipe by hydraulic pressure. Although the hydraulic fixing device 92 is schematically illustrated in the drawings of the present invention, such fixing means can be easily implemented by those skilled in the art.

When the position to construct the reinforcement pillars 200 is determined, the movable sleeve pipe 90 is fixed by the hydraulic fixing device 92 at that position, and the casing pipe 30 is lowered into the movable sleeve pipe. Since the movable sleeve pipe has a length sufficient to protect the casing pipe, the casing pipe can be prevented from being bent by the algae of the seabed. Of course, the removable sleeve pipe must have sufficient strength and diameter to not bend even in fast currents. The casing pipe is not bent by the tidal currents of the seabed to form the reinforcement pillar 200 so as not to be inclined at the correct position. FIG. 1 is a schematic view of a conventional anti-crane apparatus in which a casing pipe is bent by an alga at a deep sea or a deep algae to form an oblique reinforcement column. As shown in FIG. 1, the reinforcement pillars are formed obliquely and do not have sufficient strength, thereby causing secondary holes.

A casing pipe is a pipe having a small diameter of about 10 to 20 cm in diameter, and a large diameter columnar concrete column (reinforcement column) having a diameter of about 100 to 300 cm is formed on the sea bottom. If the depth is more than 10 m because of the aperture, the casing pipe lowered to the sea floor due to the flow of algae will bend. The present invention is to form a reinforcement column in the correct position by preventing the casing pipe having a small diameter to be bent by the flow rate of the algae.

Preferably, the movable sleeve pipe 90 has a plurality of guide protrusions 91 formed therein so that the casing pipe 30 can move smoothly therein. Although the accompanying drawings show that the guide protrusions are installed in all four positions inside the movable sleeve pipe, it is not necessarily limited thereto.

When the helm ship 10 moves, the movable sleeve pipe 90 must move upward with the casing pipe 30. As the height of the sea bottom changes, the movable sleeve pipe 90 must be properly moved so as not to be caught by the sea bottom. As for the depth of the sea bottom, conventional methods using ultrasonic waves or the like may be appropriately used.

The protection scope of the present invention will be embodied by the appended claims, and all simple modifications and changes of the present invention should be construed as belonging to the protection scope of the present invention.

10 barge 20 leader
30: rotating rod (casing pipe) 40: wire rope
50: Oga motor body 60: pulley
80: fixed sleeve pipe 81: binding structure
90: removable sleeve pipe 91: sleeve projection
92: hydraulic fixing device 93: wire rope
100: anti-crane 200: reinforced column

Claims (4)

In anti-crane apparatus for strengthening soft ground at sea,
A fixed sleeve having a large diameter so as to be fixed by the coupling structure 81 at the tip of the helm ship 10, such as a barge on which the leader 20 is installed, to allow the movable sleeve pipe 90 to penetrate up and down. Pipe 80; And
It is connected by a wire rope 93 in the upper portion to move up and down along the inside of the fixed sleeve pipe 80, the inside of the casing pipe 30 to move up and down to serve to protect the casing pipe ( 90);
Anti-tarcrane device for reinforcing soft ground at sea comprising a sleeve structure, characterized in that consisting of.
2. The method of claim 1, wherein the sleeve structure further comprises a hydraulic fixture (92) mounted above the stationary sleeve pipe (80) as a means for securing the movable sleeve pipe (90). Anti-crane device for ground strengthening.
According to claim 1, The movable sleeve pipe 90 has a strength that does not bend at the flow rate of the tidal flow is provided with a plurality of guide projections 91 are formed therein to allow the casing pipe 30 to move smoothly therein. Anti-tarcrane device for strengthening the soft ground at sea, characterized in that.
Soft ground at sea, characterized in that to form the reinforcement column 200 in the correct position by using the anti-tarcrane device according to any one of claims 1 to 3 so that the casing pipe is not bent by the algae of the seabed. Reinforcement method.

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