KR20120056394A - Method for under-seabed seawater pipe using dredged soil - Google Patents

Abstract

PURPOSE: A burying method of a seawater pipe using dredged soil is provided to improve the structural stability of a buried seawater pipe by using sand having a uniform size. CONSTITUTION: A burying method of a seawater pipe using dredged soil is as follows. A trench(1) is formed by excavating a sea bottom. Sand, in which organic materials are removed, is prepared by re-treating soil dredged from the trench. An aggregate layer(2) is formed on the bottom of the trench. One or more seawater pipes(5) are buried in the aggregate layer at a specific depth. A sand layer(3) is formed on the aggregate layer using the re-treated soil, and the seawater pipes are completely buried in the sand layer. A dredged soil layer(4) is formed in the residual space of the trench.

Description

Method for under-seabed seawater pipe using dredged soil}

The present invention relates to a seawater pipe laying method using dredged soil, and in detail, the pipe top is buried more than 2m from the sea bottom after excavating the sea bottom so that the seawater pipe does not influence the erosion due to current on the top. It is related to the buried method of reducing the amount of aggregate by reprocessing the dredged soil when buried.

Seawater desalination plants, nuclear power plants, or other large-scale seawater-use plants built near the coast use large amounts of seawater for heat exchange purposes, such as cooling of generators.

For this inflow of seawater, seawater pipes with a diameter of several tens of centimeters are buried over the length of hundreds of m to several kilometers. These seawater pipes are buried under the sea floor for safety.

3 is an exemplary view showing a buried cross section of a conventional seawater pipe. As shown, in the conventional seawater pipe buried section, a trench is formed at the bottom of the sea bottom, and an aggregate layer and a dredging soil layer of backfilling soil form a multi-level upper and lower layers in the lower aggregate layer. It can be seen that the seawater pipe is located.

The aggregate layer is a uniform layer for installing a stable seawater pipe. In addition, the dredged soil layer refers to the non-uniform soil, that is, dredged soil formed during the trench formation.

Looking at the conventional seawater pipe laying method having the above-described buried structure through Figure 4, first excavating the sea floor to form a trench (arche); Filling the aggregate with a predetermined height under the trench to form an aggregate layer; Then arranging at least one subsea pipe at regular intervals and burying the aggregate layer at a predetermined depth; Thereafter, the seawater pipe is filled with the aggregate using the aggregate, and then the remaining trench spaces which are not buried are filled with dredged soil.

However, the problem of the conventional seawater pipe laying method as described above is excessive construction cost due to the aggregate used to be brought in from the outside, and there is a problem of processing a large amount of dredging soil often leads to an increase in construction cost and environmental problems.

An object of the present invention for solving the above problems is to reduce the amount of aggregates by reprocessing the dredged soil from the trench formation when the seawater pipe with a pipe top buried 2m or more in the seabed to refill the seabed In addition, it is to provide an economical embedding method that maintains the stability of the installation structure of the seawater pipe.

The present invention to achieve the object as described above and to perform the problem for eliminating the conventional defects comprises the steps of forming a trench by excavating the sea floor;

Reprocessing some of the dredged soil dredged in the trench to prepare sand from which organic matter is removed;

Filling the aggregate with a predetermined height under the trench to form an aggregate layer;

Then arranging at least one subsea pipe in the aggregate layer at regular intervals and burying at a predetermined depth;

Thereafter, the seawater pipe is buried in the reprocessed sand to form a sand layer;

Thereafter, a dredged soil layer forming step of filling the remaining unfilled trench spaces with untreated dredged soil is achieved by providing a seawater pipe embedding method using dredged soil.

As described above, the present invention has the advantage of significantly lowering the construction cost by reducing the amount of aggregate used in the seawater pipe buried construction so that the pipe top is buried more than 2m from the seabed below the sea bottom,

The use of sand reduces the aggregate material cost, but the uniform size of sand makes the seawater pipes structurally stable.

By reusing the dredged sand, which removes only the organic material of dredged soil, it has prevented the environmental pollution caused by landfill of dredged soil as before.

It is a useful invention with the advantage that it does not need to secure additional landfill space of dredged soil is an invention that is expected to be used in industry.

1 is a buried cross-sectional view of a seawater pipe according to an embodiment of the present invention,
2 is a buried process diagram of the seawater pipe according to the present invention,
3 is a cross-sectional view of a conventional seawater pipe buried,
2 is a buried process diagram of the seawater pipe according to the conventional method.

Hereinafter, the configuration and the operation of the embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 is a buried cross-sectional view of a seawater pipe according to an embodiment of the present invention. As shown, when the seawater pipe buried section according to the present invention, a trench (1, Trench, arc) is formed at the bottom of the sea bottom, an aggregate layer (2, Crushed stone layer) from the bottom of the trench upwards , Sand layer (3, Sand layer) and dredged soil layer (4, dredged soil layer) is configured to be laminated, seawater pipe (5, Seawater pipe) is the bottom surface is embedded in the aggregate layer, the top surface is embedded in the sand layer.

The aggregate layer and the sand layer are uniform layers, and the dredged soil layer is a non-uniform layer of soil dug during trench formation. The preferred aggregate size should be between 19 and 25 mm in diameter and not exceed 40 mm. In addition, the preferred size of the sand is used 0.075 ~ 2mm.

The reason for embedding the seawater pipe in the aggregate layer and the sand layer is to maintain the structural stability by installing in the uniform layer for a long time. This is because when formed in a non-uniform layer, the sea level pipes connected with a plurality of unit pipes in the longitudinal direction may be different from each other, resulting in structural instability.

The sand layer is a reprocessed dredged soil from the trench formation. Reprocessing removes organic matter contained in dredged soil, which is only necessary to remove organic matter by washing with dredged soil on land. That is, the sand used in the present invention is intended to be buried in the salty sea floor rather than construction sand, so the level of washing (washing) surface is enough to remove only organic matters without the need for reprocessing to remove salt like construction sand. It is enough.

In the present invention, the reason for removing the organic material by reprocessing the dredged soil is that the organic material contained in the dredged soil is in a state where the uniform layer state is not uniform while the space occupied by the organic material is caused by biological decomposition or washed by sea water. This is because the stable installation structure of the seawater pipe installed in the uniform layer becomes unstable.

The trench has a wide upper portion and a narrower lower portion, and the width varies depending on the number of seawater pipes buried, but as shown in the illustrated embodiment, the lower width required for embedding four pipes of 24 cm in diameter is about 1.5 to 1.6. m or so. At this time, the spacing of the seawater pipes arranged is such that one pitch from the center to the center is about 36 cm. In this arrangement, the distance from the center of the two seawater pipes to the inner side wall of the trench is about 22 cm.

And the lower aggregate layer and the sand layer height is about 24cm, the remaining dredged soil layer is formed about 36 ~ 41cm, the height ratio between the lower aggregate layer and the sand layer is about 1: 1 as the center of the embedded individual seawater pipe.

Each numerical value given above is a description according to one embodiment for better understanding, and such a single numerical condition does not limit the present invention.

Looking at the seawater pipe embedding method according to the present invention having a buried structure in which the pipe top is embedded more than 2m in the sea floor as described above, first excavating the seabed to form a trench;

Reprocessing some of the dredged soil dredged in the trench to prepare sand from which organic matter is removed;

Filling the aggregate with a predetermined height under the trench to form an aggregate layer;

Then arranging at least one subsea pipe in the aggregate layer at regular intervals and burying at a predetermined depth;

Thereafter, the seawater pipe is buried in the reprocessed sand to form a sand layer;

Afterwards, the step of forming a dredged soil layer to fill the remaining unfilled trench space with dredged soil not reprocessed.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

<Explanation of symbols for the main parts of the drawings>
(1): trench (2): aggregate layer
(3): sand layer (4): dredged soil layer
(5): seawater pipe

Claims (1)

Excavating the sea bottom to form a trench;
Reprocessing some of the dredged soil dredged in the trench to prepare sand from which organic matter is removed;
Filling the aggregate with a predetermined height under the trench to form an aggregate layer;
Then arranging at least one subsea pipe in the aggregate layer at regular intervals and burying at a predetermined depth;
Thereafter, the seawater pipe is buried in the reprocessed sand to form a sand layer;
Later, the step of forming a dredged soil layer to fill the remaining unfilled trench space with unreprocessed dredged soil; seawater pipe laying method using dredged soil, characterized in that consisting of.

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