JP5677379B2 - Dredging method - Google Patents

Description

  The present invention relates to a dredging method for dredging sediments such as sea bottom, lake bottom, river bed, etc. using a grab bucket.

  In dredging work to increase the depth of the maintenance dredging in the port and the channel and anchorage, the excavated earth and sand are unloaded. As one of such dredging methods, there is known a method for dredging using a grab bucket suspended on a crane installed in a grab dredger or the like.

  Patent Document 1 uses a normal grab bucket and a wide grab bucket for finishing digging in order to efficiently perform dredging work, and after leaving a small finishing depth with a normal grab bucket, the wide grab bucket The method of wrinkling up to the finishing depth is disclosed. The wide grab bucket has a larger maximum opening area and a smaller maximum digging depth than a normal grab bucket. When a wide grab bucket is used for finishing digging, it is possible to excavate a large area at a time as compared with a normal grab bucket, and the number of finishing digging can be reduced. Furthermore, since a small finishing depth is excavated with a wide grab bucket having a small excavation depth, the moisture content of the excavated earth and sand can be reduced.

JP 2010-159545 A

In important ports, factories are scattered in the area behind the coastal area. A large amount of waste liquid treated to below the environmental standard value is discharged from the factory group. As a result of the discharge of this waste liquid over several years, a sludge layer mixed with heavy metals and dioxins may accumulate on the seabed of important ports and anchorage. If such a port is dredged, sludge in the sludge layer will be landed.
For this reason, landed sludge must be solidified to prevent harmful substances from flowing back into the seawater. If the amount of sludge is large, the cost of solidification will be enormous.

  An object of this invention is to provide the dredging method which can carry out dredging work by landing only the earth and sand under a sludge layer, without landing sludge using a grab bucket.

In order to solve the above-described problems,
A scissor method that divides a scissors portion into a plurality of columns and sequentially scissors each adjacent column,
Sludge excavation process for excavating sludge contained in the sludge layer of the surface layer of the dredging area using the grab bucket;
Using a grab bucket, temporarily placing a part or all of the sludge excavated by the sludge excavation step in water;
Using a grab bucket, a replacement tank is created that traps the soil contained in the ground beneath the sludge layer excavated by the sludge excavation process, and creates a replacement tank that is a container for placing sludge excavated in the sludge excavation process. Process,
Using a grab bucket, the sludge charging step of charging the sludge temporarily placed in the temporary placement step and / or the sludge excavated in the sludge excavation step into the replacement vessel created in the replacement vessel creation step;
Equipped with a,
In the temporary placement step, the sludge in the first row excavated by the sludge excavation step is temporarily placed in water,
In the replacement tank creation process, when the first row of sludge temporarily placed in the temporary placement step and the second row of sludge dug in the sludge excavation step are introduced for the first row, the size becomes the planned water depth. The replacement tanks having a size that will become the planned water depth for each row after the first row are created for each row. ,
In the sludge charging step, the first row of sludge temporarily placed in the temporary placement step and the second row of sludge digged in the sludge digging step are placed in the first row of replacement tanks, and the second row and thereafter. A sludge of a row adjacent to the replacement tank of each row of
It is characterized by that.

Preferably, the construction method of the present invention is:
In the replacement tank creation step, a retaining wall is created by leaving a part of the earth and sand without excavation at the end of each of the replacement tanks in the second and subsequent rows.

Preferably, the construction method of the present invention is:
In the sludge excavation step, even if a sludge accumulated on the ground having a width wider than a normal grab bucket, a maximum opening area, a maximum digging depth, and an N value of 15 to 30, is excavated The sludge contained in the sludge layer is excavated by using a thick and wide grab bucket having a nail at the blade edge without being deformed.

Preferably, the construction method of the present invention is:
In the sludge charging step, the sludge temporarily placed in the temporary placing step is excavated using the thick and wide grab bucket, and is put into a replacement tank.

  According to the present invention, it is possible to carry out dredging work by using the grab bucket to land only the earth and sand under the sludge layer without landing the sludge.

It is a figure which shows an example of the flow of the construction method which concerns on the 1st Embodiment of this invention. It is a figure which shows an example of the outline of excavation by the dredging method which concerns on the 1st Embodiment of this invention. It is a figure which shows an example of the flow of the construction method which concerns on the 2nd Embodiment of this invention. It is a figure which shows an example of the outline of excavation by the dredging method which concerns on the 2nd Embodiment of this invention. It is a figure which shows the specific example of the dredging method which concerns on the 2nd Embodiment of this invention. FIG. 6 is a continuation of FIG. 5. It is the BB sectional view taken on the line of FIG. FIG. 7 is a continuation of FIG. 6. It is CC sectional view taken on the line of FIG. FIG. 9 is a continuation of FIG. 8. It is the DD sectional view taken on the line of FIG. FIG. 11 is a continuation of FIG. 10. It is the EE sectional view taken on the line of FIG. FIG. 13 is a continuation of FIG. 12. It is the FF sectional view taken on the line of FIG. FIG. 15 is a continuation of FIG. 14. It is the GG sectional view taken on the line of FIG.

Hereinafter, the construction method according to an embodiment of the present invention will be described in detail with reference to the drawings.
In all the drawings for explaining the embodiments, common constituent elements are denoted by the same reference numerals, and repeated explanation is omitted. Moreover, in this specification and a claim, dredging means excavating earth and sand and landing the earth and sand.

FIG. 1 shows an example of the flow of the dredging method according to the first embodiment of the present invention.
FIG. 2A shows an example of the seabed that is the target of dredging. A sand repellent layer 20 exists under the sludge layer 10 on the seabed. The sand repellent layer 20 is an example of a hard ground. The seabed shall be dredged to the planned depth of 30.
In the scissors method according to the first embodiment, scissors are scooped together at one time, or adjacent rows are scissored in two or more rows.
First, enter the wrinkle location in the first row. As shown in FIG. 2 (A) and FIG. 2 (B), the surface sludge 11 in the first row is excavated using a grab bucket suspended from a crane installed in a grab dredger and temporarily placed on the seabed. (S11). Next, as shown in FIG. 2 (B) and FIG. 2 (C), a grab bucket is used to crush the sand scoop 21 under the sludge 11 to create a replacement tank 41 that is a container for placing the sludge 11 ( S12). Then, as shown in FIG. 2C and FIG. 2D, the sludge 11 temporarily placed in the replacement tank 41 is introduced (S13).
And it is discriminate | determined whether it is the last row | line (S14), and when it is the last row | line | column (S14: Yes), a dredging operation | work is complete | finished. In addition, when wrinkling a wrinkle place at once, since step S14 is Yes, a wrinkle operation | work is complete | finished here.

If it is determined in step S14 that it is not the last column (S14: No), the next column is selected. As shown in FIGS. 2D and 2E, the sludge 12 on the surface layer is excavated using a grab bucket and temporarily placed on the seabed (S15). Next, as shown in FIG. 2 (E) and FIG. 2 (F), the gravel bucket is used to crush the sand scoop 22 under the sludge 12 to create the replacement tank 42 and the earth retaining wall 50 (S16). . If there is no earth barrier between the replacement tank 41 and the replacement tank 42, the sludge 11 placed in the replacement tank 41 easily flows out to the newly excavated replacement tank 42. For this reason, the sand retaining wall 50 is created by leaving a portion of the sand rub 22 without being excavated at the end of the replacement tank 42. In addition, the sludge and sand repel excavated or dredged from the second row to the last row are referred to as sludge 12 and sand repel 22, respectively. Then, as shown in FIG. 2F, the temporarily placed sludge 12 is put into the replacement tank 42 (S17), and the process returns to step S14.
In addition, the sand reki 21 and the sand reki 22 are examples of earth and sand.

Here, the replacement tank 41 and the replacement tank 42 are sized so as to have a planned water depth 30 when the sludge 11 and the sludge 12 are respectively charged and the inside thereof is filled with the sludge 11 and the sludge 12.
According to the first embodiment, not only when the planned water depth 30 is deeper than the thickness of the sludge layer 10, but also when the planned water depth 30 is shallower than the thickness of the sludge layer 10, it is included in the surface sludge layer 10. It is possible to land the sand repel contained in the sand repel layer 20 while leaving the sludge remaining on the seabed.

FIG. 3 shows an example of the flow of the dredging method according to the second embodiment of the present invention.
In the second embodiment, the wrinkle location is divided into two or more columns, and adjacent columns are wrinkled in order.
First, enter the wrinkle location in the first row. As shown in FIG. 4 (A) and FIG. 4 (B), the surface sludge 11 in the first row is excavated using a grab bucket suspended by a crane installed in the grab dredger and temporarily placed on the seabed. (S21). Next, as shown in FIG. 4 (B) and FIG. 4 (C), the sand tank 23 under the sludge 11 is crushed using a grab bucket, and a replacement tank 43 that is a container for placing the sludge 11 is created ( S22). Then, as shown in FIGS. 4C and 4D, the sludge 11 temporarily placed in the replacement tank 43 is introduced (S23).

Next, check the adjacent second row of wrinkles. As shown in FIG. 4D and FIG. 4E, the sludge 12 on the surface layer is excavated using a grab bucket and placed in the replacement tank 43 into which the sludge 11 is placed in step S23 (S24). It should be noted that step S23 and step S24 may be reversed, and the first row of sludge 11 temporarily placed after the second row of sludge 12 is placed in the replacement tank 43. Then, as shown in FIG. 4E, the gravel bucket is used to crush the sand scoop 22 under the sludge 12 to create the replacement tank 42 and the earth retaining wall 50 (S25). In addition, the sludge and sand repel excavated or dredged from the second row to the last row are referred to as sludge 12 and sand repel 22, respectively.
Next, move from the third column to the last column. Using the grab bucket, the sludge 12 on the surface layer is excavated and put into the replacement tank 42 (S26). If it is not the last column (S27: No), the process returns to step S25, and the next column is selected. On the other hand, if it is the last row (S27: Yes), the sand scoop 22 is dredged to the planned water depth 30 (S28), and the dredging operation is finished.
The sand repel 23 is also an example of earth and sand.

Here, sludge 11 and sludge 12 are put into the replacement tank 43. For this reason, the replacement tank 43 is sized to have the planned water depth 30 when the inside is filled with the sludge 11 and the sludge 12. On the other hand, only the sludge 12 is put into the replacement tank 42. For this reason, the replacement tank 42 is smaller than the replacement tank 43 and has a size that becomes the planned water depth 30 when the inside thereof is filled with the sludge 12.
In the second embodiment, the sludge 12 is directly put into the replacement tank 43 or the replacement tank 42 without temporarily placing the sludge 12 when the second and subsequent rows are selected. In this respect, the second embodiment has higher working efficiency than the first embodiment. The second embodiment is particularly effective when the sludge layer 10 is deposited at a location shallower than the planned water depth 30.

The sludge layer deposited on the seabed is usually thin. For this reason, working efficiency can be improved by excavating the sludge layer using the wide grab bucket for finishing digging described in Patent Document 1. In particular, the closed wide grab bucket is optimal because the sludge of the sludge layer mainly composed of about 200% water content also has a pollution prevention effect.
However, a wide grab bucket is structurally weaker than a normal grab bucket because it is wider than a normal grab bucket and has a larger maximum opening area. The sludge layer is often soft, but there may be a solid ground under the sludge layer. When the N value of the ground is increased, the force applied to the end of the grab bucket when the grab bucket is closed is increased, so that the ground is easily damaged.
When excavating with a wide grab bucket, if you bite such hard ground, the wide grab bucket may be distorted, so you can only excavate a little above the hard ground so that it does not touch the hard ground under the sludge layer . In addition, even if the ground beneath the sludge layer is soft, harbors that have been used for many years may have fallen objects from navigating ships on the seabed, drifted wood, stones, etc. that have subsided naturally. If hit, the wide grab bucket may be distorted.
Ordinary grab buckets can be excavated without problems even if the N value is about 15-30, but if you try to reduce the amount of soil contained in the ground below the sludge layer, Since the area to be finished becomes small, the efficiency becomes worse. Moreover, since only a small amount of earth and sand can be excavated at a time, the moisture content of the earth and sand tends to increase.

Therefore, in the grab bucket dredging method according to the first embodiment and the second embodiment described above, when the sludge layer deposited on the seabed is thin, even if it touches a hard object, it encounters a certain amount of hard ground. Even so, use a thick and wide grab bucket that does not warp the sludge layer. A thick and wide grab bucket is wider than a normal grab bucket, has a large maximum opening area, and a small maximum digging depth. The thick and wide grab bucket has higher strength than the generally used wide grab bucket, and does not deform even when excavating hard ground with N value = 15-30. In addition, the blade edge has a claw so that the blade edge of the bucket can enter the ground even when the accumulated sludge is on the ground of N value = 15-30.
By excavating a thin sludge layer using a thick and wide grab bucket, sludge and its N value = 15 while the ground below the sludge layer has a certain excavation area to some extent even if the N value = 15-30. A part of -30 earth and sand can be excavated at once.
Since the total upper limit value of the weight of earth and sand that can be secured inside the grab bucket and the weight of the grab bucket is determined by the ability of the grab ship to be used, the thick and wide grab bucket has a grab bucket capacity corresponding to this.
The thick and wide grab bucket is desirably a hermetically sealed type to prevent the sludge from diffusing. In addition, when releasing the excavated sludge from the thick and wide grab bucket in water, it is desirable to open slowly the thick and wide grab bucket so that the sludge does not diffuse.
Further, in the grab bucket dredging method according to the first embodiment and the second embodiment, a thick and wide grab bucket may be used when excavating sludge temporarily placed on the seabed.

5 to 18 show specific examples of the dredging method according to the second embodiment described above.
FIG. 5A is a top view of the heel portion, and FIG. 5B is a cross-sectional view taken along line AA in FIG. In this example, the dredging area is divided into a total of 5 rows from 1st work area to 5th work area. The dredging width of each work area is approximately 25 m, which is equivalent to the hull width of grab dredgers. A sand repellent layer 20 exists under the sludge layer 10 on the seabed. The seabed at a water depth of 60 is dredged to the planned water depth of 30.
Use thick and wide grab buckets for sludge dredging (excavation, horizontal holding, and soiling), and use normal grab buckets for dredging clay and sandy soil and sludge leveling. The capacity of both thick and wide grab buckets and normal grab buckets is 23 m ³ .

6 and 7 show a state where the sludge 11 has been excavated and temporarily placed on the seabed in the first section to be dredged (S21). The sludge 11 on the surface layer is excavated by using a thick and wide grab bucket 71 suspended from a crane installed in the grab dredger 70, and is temporarily held and temporarily placed in the adjacent left and right work zones. At this time, the sludge in the wrinkle range 80 is wrinkled.
FIG. 8 and FIG. 9 show a state in which a replacement tank 43 which is a container for placing the sludge 11 is created by dripping the sand scoop 23 under the sludge 11 in one work area (S22). When the sludge 11 in one work area has been removed, the sand repel 23 is excavated using a normal grab bucket 72 and placed on the earth transport ship 73. The sand squirrel 23 placed on the soil carrier 73 is landed and used for landfill. The trace of the sand repelling 23 becomes a replacement tank 43. By this time, the crumpled range is the heel range 81.

FIG. 10 and FIG. 11 show a state where the sludge 11 temporarily placed in the replacement tank 43 is put in one work area (S23). The sludge 11 that is temporarily placed after being distributed to the left and right is horizontally held and placed in the replacement tank 43 in one work area by a thick and wide grab bucket 71.
Moreover, FIG. 12 and FIG. 13 show the state where the sludge 12 in the second work area is excavated and put into the replacement tank 43 in the first work area (S24). The sludge 12 in the second section is held and placed in the replacement tank 43 in the first section with the thick and wide grab bucket 71. After removing the sludge 12 in the second section, the replacement tank 43 in the first section is leveled with a normal grab bucket 72. By this time, the crumpled range is the heel range 82.

FIG. 14 and FIG. 15 show a state in which the sand burrs 22 under the sludge 12 are crawled and the replacement tank 42 and the earth retaining wall 50 are created in the two work zones (S25). After removing the sludge 12 in the second work area, the sand gravel 22 is excavated by using a normal grab bucket 72 and placed on the soil transporting ship 73. The sand repel 22 placed on the earth transport ship 73 is landed and used for landfill. A trace of the sand repelling 22 becomes a replacement tank 42. By this time, the crumpled range is the heel range 83.
16 and 17 show a state where the sludge 12 in the third work area is excavated and put into the replacement tank 42 in the second work area (S26). The sludge 12 in the third work area is excavated by a thick and wide grab bucket 71 and held and placed in the replacement tank 42 in the second work area. After removing the sludge 12 in the third section, the replacement tank 42 in the second section is leveled with a normal grab bucket 72. By this time, the crumpled range is the heel range 84.
Steps S25 and S26 are repeated up to 5 zones (S27: No), and when the sludge 12 in 5 zones is removed, the sand layer of 5 zones is dredged to the planned water depth 30 (S28), and the dredging operation is completed.

In the above-described embodiment, an example of dredging using a grab bucket suspended on a crane installed in a grab dredger has been shown, but dredging using a grab bucket attached to an underwater backhoe instead of a grab dredger. You can also.
In the above-described embodiment, an example in which sludge is temporarily placed on the seabed has been described. However, the seabed is an example of underwater. For example, when dredging a lake bottom or a riverbed, the sludge is temporarily placed on a lake bottom or a riverbed. .

As described above, according to the present invention, the dredging work can be performed by landing only the sediment under the sludge layer while leaving the sludge on the surface layer on the sea floor without landing.
If the sludge layer contains harmful substances, the sludge must be solidified when it is landed, but in the present invention, solidification treatment is performed in order to land sand and sand, instead of sludge. You don't have to. When the landed soil is high quality soil, it is suitable for reuse of the soil, leading to effective use of dredged soil.
In addition, by using a thick and wide grab bucket, there is a solid ground under the sludge layer, or there are fallen objects from navigating ships, naturally drifted wood, stones, etc. on the sludge layer. Even if it exists, the sludge layer can be excavated efficiently.

  Although the embodiments of the present invention have been described above, various modifications and combinations necessary for design reasons and other factors are described in the inventions described in the claims and the specific embodiments described in the embodiments of the invention. It is intended to be included in the scope of the invention corresponding to the example.

DESCRIPTION OF SYMBOLS 10 ... Sludge layer, 11, 12 ... Sludge, 20 ... Sand repellent layer (hard ground), 21, 22, 23 ... Sand repellent, 30 ... Plan depth, 41, 42, 43 ... Replacement tank, 50 ... Earth retaining wall, 60 ... Depth of water, 70 ... Grab dredger, 71 ... Wide grab bucket, 72 ... Regular grab bucket, 73 ... Dirt carrier, 80, 81, 82, 83, 84 ... Sludge dredging range

Claims (4)

A scissor method that divides a scissors portion into a plurality of columns and sequentially scissors each adjacent column,
Sludge excavation process for excavating sludge contained in the sludge layer of the surface layer of the dredging area using the grab bucket;
Using a grab bucket, temporarily placing a part or all of the sludge excavated by the sludge excavation step in water;
Using a grab bucket, a replacement tank is created that traps the soil contained in the ground beneath the sludge layer excavated by the sludge excavation process, and creates a replacement tank that is a container for placing sludge excavated in the sludge excavation process. Process,
Using a grab bucket, the sludge charging step of charging the sludge temporarily placed in the temporary placement step and / or the sludge excavated in the sludge excavation step into the replacement vessel created in the replacement vessel creation step;
Equipped with a,
In the temporary placement step, the sludge in the first row excavated by the sludge excavation step is temporarily placed in water,
In the replacement tank creation process, when the first row of sludge temporarily placed in the temporary placement step and the second row of sludge dug in the sludge excavation step are introduced for the first row, the size becomes the planned water depth. The replacement tanks having a size that will become the planned water depth for each row after the first row are created for each row. ,
In the sludge charging step, the first row of sludge temporarily placed in the temporary placement step and the second row of sludge digged in the sludge digging step are placed in the first row of replacement tanks, and the second row and thereafter. A sludge of a row adjacent to the replacement tank of each row of
This is a method of construction. In the replacement tank creation process, leaving without drilling a portion of the sand for each said replacement tank after the second column at the end of each said replacement tank, to claim 1, characterized in that to create the facing wall The construction method described. In the sludge excavation process, even when excavating the ground having a width wider than a normal grab bucket, a large maximum opening area, a small maximum digging depth, and an N value of 15 to 30, it does not deform, The dredging method according to claim 1 or 2 , wherein a sludge contained in the sludge layer is excavated using a thick and wide grab bucket having claws. The dredging method according to claim 3 , wherein, in the sludge charging step, the sludge temporarily placed in the temporary placing step is excavated using the thick and wide grab buckets, and is put into a replacement tank.

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