JP2000287602A - Prevention of growth of aquatic life on submerged structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for preventing aquatic life from growing on a submerged structure by a convenient operation at a low cost without landing the submerged structure. SOLUTION: This method comprises covering the whole part of the draft of a submerged structure to be moored with a polyolefin sheet having the area of each of openings of 1-60 mm2, the ratio of the total areas of openings to the whole plain surface area of 20-80% and the thickness of <1 mm.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an underwater structure, for example, a method for preventing aquatic organisms from adhering to a ship. The present invention relates to an effective method for preventing aquatic organisms from adhering to underwater structures.

[0002]

2. Description of the Related Art Larvae, eggs, or species of aquatic organisms such as barnacles, shellfish, seaweeds, and algae are floating in seawater. The larvae of the aquatic organisms adhere to the creatures, and the aquatic organisms start to grow in this attached state. If the mooring period is long, the shellfish and the like become large clumps, and if left unattended, the vessel may be damaged by these aquatic organisms, and the life of the vessel may be significantly shortened. In addition, if the aquatic organisms travel in a state where they are attached to the draft, there is a problem in that fuel efficiency is degraded due to an increase in navigation resistance, and navigation safety is caused by the occurrence of rolling.

When removing aquatic organisms attached to the draft of a ship by mechanical scraping or the like, it is practically impossible to perform this operation in water. Will be. At this time, a lifting device such as a crane, a space, and the like are required, which is large and increases the cost. In addition, a great deal of labor is required for the scraping operation.

[0004] Therefore, it is necessary to prevent aquatic organisms from adhering to ships, and methods for this purpose have been considered.

[0005] There is a method of applying a special paint for preventing aquatic organisms from adhering to a ship, but the application of the special paint requires the landing of the ship in the same manner as in the above-mentioned case, and is not effective. It has the disadvantage of short duration. Furthermore, some of the specialty paints have been shown to be toxic to fish and shellfish and the human body, so it is difficult to apply the specialty paints from an environmental point of view.

[0006] As a method of preventing aquatic organisms from adhering to a ship without having to land the ship, a draft portion of the ship is surrounded by a waterproof sheet, lifted up by a buoyancy material, and cut off from outside seawater. A method of killing shellfish eggs by diluting the concentration of seawater (Japanese Patent Laid-Open No. 7-96891), by covering the outer periphery of a ship with an opaque sheet material to shield light,
Method for suppressing the growth of aquatic organisms (Japanese Patent Laid-Open No. 60-9489)
No. 2) and a method of preventing airborne organisms from adhering by injecting air into a floating bag poured into the bottom of a ship and bringing the floating bag into close contact with the ship (Japanese Patent Application Laid-Open No. 4-50598). However, any method has the disadvantage that it is necessary to form the member into a special shape by suturing, fusing, or the like, or the handling procedure for installation is complicated, and the human cost is large. Absent.

[0007] Japanese Patent Application Laid-Open No. 63-22908 discloses a method for preventing the adhesion of underwater organisms. This method for preventing the attachment of underwater organisms is described as follows: "a cloth having a surface portion of an underwater structure having a thickness of 1 mm or more and having a void portion in which water replacement easily occurs;
It is characterized by being covered with a net or a porous sheet. "
(See claims in the above publication).

[0008] According to this publication, it is described that "if the porous sheet is thinner than 1 mm, it is difficult to prevent underwater organisms from adhering thereto" (the third publication in the publication).
(From the lower right column of the page to the third line to the upper left column of the fourth page to the second line). In fact, according to the comparative example in this publication, when a cloth having a thickness of 0.5 mm is employed, a large amount of underwater organisms adhere.

Further, this publication states that "porous sheets include, for example, urethane foam, expanded polystyrene, expanded polyethylene and the like, and these are preferably 5 to 20 cells / 25 mm in standard cells". (See page 12, lower right column, lines 12 to 17 of the publication).
Referring to the examples in the publication, a 10-mm-thick polyurethane foam sheet is used as a porous sheet in Example 1, a polypropylene net is used in Example 7, and a synthetic fiber yarn is used in Example 8. The perforated net structure to be used is adopted.

As described above, the porous sheet described in the above publication is extremely thick, and a plate is more appropriate than a sheet. It is practically difficult to cover large underwater structures with thick sheets.

[0011]

SUMMARY OF THE INVENTION The present invention eliminates the disadvantages of the prior art, eliminates the need to land underwater structures such as ships, is simple to operate, and can be performed at low cost. An object of the present invention is to provide a method for preventing aquatic organisms from attaching to a draft portion of a ship such as an underwater structure.

[0012]

SUMMARY OF THE INVENTION The present invention has been made to achieve the above-mentioned object, and has a thickness of less than 1 mm, an opening having an area of 1 to 60 mm ² ,
And the total plane area of all openings is 20 to 8 with respect to the total plane area.
A method for preventing aquatic organisms from adhering to underwater structures by covering the entire draft portion of the underwater structures with a 0% polyolefin sheet. In a preferred embodiment, the polyolefin sheets are JIS L1096.
The tensile elongation measured according to A is 15 to 37%, the tear strength measured according to JIS L1096A-1 is 3 to 9 kg, and long strips are arranged in a grid. , And the intersections are fused.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION The present invention is a method for preventing aquatic organisms from adhering to an underwater structure, which covers the entire draft portion of the underwater structure with a sheet having the following structure. Note that the following description is made by taking a ship that is an underwater structure as an example.

The sheet used in the present invention has a large number of openings (through holes) on the entire surface.

The openings each have an area of 1 to 60 mm ² . When the area of each of the openings is within the range, the larvae of aquatic organisms exclusively adhere to the sheet and grow on the sheet, so that they do not pass through the sheet and do not adhere to the ship. . In addition, since the sheet has good water permeability, the sheet receives a small resistance to water when the sheet is coated on a ship, and the workability is improved. If the opening area exceeds the upper limit of the above range, the larvae of aquatic organisms pass through the sheet and adhere to the surface of the ship, and the adhesion preventing effect cannot be obtained. On the other hand, if the opening area is smaller than the lower limit of the above range, the water permeability of the sheet is reduced, so that the resistance of water received by the sheet during the sheet coating operation is increased, and the workability is undesirably deteriorated. The area of each of the openings is more preferably 5 to 30 mm ² .

The opening has a total plane area of 20 to 80% of the total plane area. If the total plane area of the entire opening exceeds the upper limit of the range, the strength of the sheet is reduced, there is a possibility of breakage in seawater, and the sheet is sufficient for aquatic organisms attached to the sheet to grow. It is not preferable because the surface area cannot be secured. On the other hand, if the total plane area of all the openings is smaller than the lower limit of the range, water permeability becomes insufficient, and workability is deteriorated due to an increase in water resistance, which is not preferable. The total plane area of all the openings of the sheet is more preferably 35 to 65% of the total plane area.

The sheet has a thickness of less than 1 mm;
Preferably, it has a thickness of 0.05 or more and less than 1 mm. When the thickness of the sheet is larger than the upper limit of the above range, it becomes difficult to handle at the time of coating work on a ship, and when the thickness of the sheet is smaller than the lower limit of the above range, sufficient sheet strength required in the practice of the present invention is obtained. I can't get it. The thickness of the sheet is more preferably 0.2 to 0.5 mm.

[0018] The sheet has a tensile elongation of 15 to 37% measured according to JIS L1096A,
The tear strength measured according to SL1096A-1 is 3 to 9 kg. When the tensile elongation and tear strength are each smaller than the lower limit of the above range, when the sheet is coated on a ship,
Alternatively, aquatic organisms can grow on the sheet and break when their weight increases. On the other hand, tensile elongation,
Use of a sheet having a tear strength greater than the upper limit of the above range is disadvantageous in terms of cost.

The material of the sheet is polyethylene, polypropylene because it is excellent in water resistance and weather resistance, is inexpensive, is easy to process, has a predetermined strength, and is flexible and easy to handle. And polyolefins such as polyvinyl chloride are preferably used.

The polyolefin sheet having the above properties can be obtained by perforating a sheet produced by a usual method with a suitable means.

Further, a polyolefin sheet obtained by arranging long strips of polyolefin in a lattice pattern and fusing the intersections thereof is also more preferable. Examples of the long strip include a thread, a string, and a sheet having a length necessary and sufficient for producing the polyolefin sheet according to the present invention.

As the polyolefin sheet, one sheet in which long strips of polyolefin are arranged in a lattice pattern and each intersection is fused, and the other sheet having the same structure are used as long sheets of each sheet. A sheet formed by superposing the strips obliquely and fusing and integrating one sheet and the other sheet is also preferably used.

There is no particular limitation on the method of combining the long strips as long as the long strips are arranged in a lattice pattern. For example, a combination as shown in FIG. 1 can be mentioned. FIG.
1A is a plain weave, FIG. 1B is a twill weave, and FIG.
Is a narrow long sheet 1 which is an example of a long strip in a satin weave shape.
Are combined.

The width of the elongated strips and the spacing between the elongated strips satisfy the conditions of the opening area, the ratio of the total plane area of all the openings to the total plane area, the tensile elongation and the tear strength. There is no particular limitation as long as the width of the long strip is 2 to 4 mm, and the interval between the long strips is 1 to 5 mm for each of the length and width.
In addition, as long as the above conditions are satisfied, the width of the long strips and the interval between the long strips in one sheet may not be unified. In addition, the lattice-shaped arrangement is not limited to the mode in which the vertical elongated strips and the horizontal elongated strips are arranged orthogonally, and the vertical elongated strips and the horizontal elongated strips are Includes a mode that is arranged obliquely.

The present invention is a method for preventing aquatic organisms from adhering to a ship by covering the entire draft portion of the moored ship with a sheet satisfying the above requirements. In the present invention, the covering step is not particularly limited as long as the entire draft portion of the ship is finally covered with the sheet.

As a method of coating a ship, when the entire draft portion of the ship is covered with one sheet, for example,
It can be performed as follows. The end of the seat is placed on the opposite side of the ship so that the end of the seat is immersed in the water from the side of the ship or the tip of the bow, so that the seat slides on the bottom surface of the ship and the hull is wrapped by the seat. Pull in the side or stern direction. Then, the end of the seat is pulled up on the water surface from the opposite side surface or the rear side of the stern, thereby covering the entire draft portion of the ship.

If it is not possible to cover the entire draft portion of the ship with one sheet, the ship is covered by combining several sheets. As the coating method in this case, for example, the following method can be mentioned.
The strip-shaped sheet having a certain width is prepared, dive below the bottom of the ship from the side of the ship, and lift it up on the water surface from the opposite side of the ship. The same operation is repeated for another band-shaped sheet. Then, the two strip-shaped sheets are arranged so that the two strip-shaped sheets are in contact at one side or the peripheral portions are partially overlapped with each other, and no gap is generated using an adhesive tape, an adhesive, a string, or the like. To join. By repeating this operation, the entire draft portion of the boat is covered while the belt-like sheet is formed into one large sheet. Further, on land, several of the belt-shaped sheets are combined by the same operation as above to form one large sheet, and the formed sheet is used for the draft of a ship with the one sheet. The ship may be covered in the same manner as when covering the entire part.

Since the sheet used in the present invention is a highly water-permeable sheet having the above-described structure, the water resistance received by the sheet in the above-mentioned coating operation of a ship is less than that of a sheet having a low water-permeability. It is much smaller and the work of the coating operation is greatly reduced. This also has the same advantage during the sheet removing operation.

When the ship is covered with the seat, the periphery of the seat is fixed using a rope or a belt at a non-draft portion of the ship or at a position higher than the water surface of a structure other than the ship. At this time, the entire periphery of the sheet is maintained at a position higher than the water surface.

In the present invention, when the ship is covered with the sheet, it is not necessary to keep the sheet in close contact with the surface of the ship, and the sheet and the surface of the ship may cause inconvenience during work, mooring of the ship, and the like. It can take a distance that is not enough. The sheet rocks in the seawater due to the wave force, and it is desirable that the sheet be present at a distance of approximately 1 to 10 cm from the surface of the ship.

When a ship is moored for a long time in a state where the ship is covered with the sheet, as the aquatic organisms adhere to the sheet and the amount of affixed to the aquatic organism increases, the sheet tends to hang down due to the weight of the aquatic organism. Show. Then, it may be difficult to fix and support the sheet only at the peripheral portion of the sheet in view of the strength of the sheet. As a measure for reinforcing the sheet for this purpose, a method of reinforcing the sheet with a high-strength rope or belt at appropriate intervals,
A method of adjusting the buoyancy of the water-permeable sheet by attaching tubes of synthetic resin, rubber, or the like to the sheet at appropriate intervals and sending air to the tube. Further, before coating the ship, a double-sided tape may be attached to the sheet at an appropriate interval, and the sheet may be reinforced by performing the sheet covering operation while attaching the double-sided tape to the ship surface. it can.

When the ship leaves, the ship can be released by releasing the seats. Further, the sheet pulled up from seawater can be reused when the amount of attached aquatic organisms is small.

The aquatic organism adhesion preventing method of the present invention can also be applied to underwater structures other than ships. In the present invention, as an underwater structure, a floating pier, an underwater facility and a floating facility of a fish farm, a submarine oil field drilling well facility, a floating vessel guide light, a floating lighthouse, a buoy, a marine heliport facility, and a marine vessel are provided outside the ship. Or various ropes laid under the sea for various purposes can be mentioned. In these underwater structures, the entire surface of the draft portion is covered with the sheet in the same manner as in the case of a ship, and by fixing the sheet, the attachment of aquatic organisms can be prevented in the same manner as in the case of a ship.

[0034]

EXAMPLE A leisure boat with an outboard motor made of FRP having a total length of 11 m and a total width of 2 m was used for the test. The boat was moored on the coast of Kishiwada City, Osaka Prefecture, and long strips of polyolefin were arranged in a grid, and each intersection was heat-sealed. The area of each opening was 6 mm ² , The total plane area of the opening is 45% of the total plane area, the thickness is 0.3 mm, the tensile elongation measured according to JIS L1096A is 22%, and according to JIS L1096A-1. Then, the sheet was coated with a sheet having a measured tear strength of 7.5 kg. In addition, at this time, in order to compare the aquatic organism adhesion state of the portion covered with the sheet and the uncoated portion,
A part of the sheet covering the leisure boat was cut into a rectangular shape (20 cm × 60 cm). In this state, the boat was moored for about six months from March 1998. After the test, the sheet was removed, and the leisure boat was landed to check the state of attachment of aquatic organisms.

(Test Results) Regarding the sheet removed after the end of the test, no deposit was found on the sheet surface on the boat side, but many muddy substances and barnacles adhered on the sheet surface on the opposite side to the boat. Was.

In the boat hull, barnacles were densely attached to a part of the bottom of the boat in a rectangular shape. No other aquatic organisms were observed. The position and size of the part to which the barnacles adhered were the same as those of the part where the sheet was cut out for comparison. From this, it is determined that barnacles and the like did not adhere to the hull portion covered by the sheet, and that the barnacles adhered only to the hull portion not covered by the sheet.

[0037]

According to the present invention, it is possible to effectively prevent aquatic organisms from adhering to a draft portion of an underwater structure such as a ship by merely covering the underwater structure such as a ship with a sheet having a certain structure. Can be.

Since the present invention can be carried out without landing an underwater structure such as a ship, it is not necessary to secure a space necessary for landing and use a machine such as a crane. Therefore, it is possible to carry out the method of the present invention no matter where the underwater structure such as a ship is moored. Further, since the only work required in the present invention is to cover the sheet on the underwater structure such as a ship, a large number of personnel are not required for the work, and the labor cost can be reduced.

Since the sheet used in the present invention has a structure having a large number of openings, it has high water permeability. For this reason,
At the time of covering the sheet with the underwater structure and removing the sheet, the sheet receives little water resistance in the water. Therefore, compared with the method using a sheet having low water permeability, the method according to the present invention can greatly reduce the labor of the operation. Further, according to the present invention, it is not necessary to keep the coated sheet in close contact with an underwater structure such as a ship, so that the work is further facilitated.

The sheet used in the present invention has a large tensile elongation and tear strength because the long strips are arranged in a lattice. For this reason, even if the sheet thickness is reduced, it is possible to maintain a sufficient strength required when implementing the present invention. Therefore, the sheet used in the present invention has a small sheet thickness, is lightweight, is easy to handle, and does not require a large storage space because it does not have a large volume when folded. Further, the sheet used in the present invention has a simple structure, and can be formed only by heat-sealing the respective intersections of the long strips arranged in a lattice, so that the sheet can be manufactured at low cost. .

The polyolefin, which is the material of the sheet used in the present invention, contains only carbon and hydrogen as constituent elements, and does not generate toxic gas even when burned. Therefore, the used sheet can be incinerated, and the problem of waste disposal does not occur.

[Brief description of the drawings]

FIG. 1A is an explanatory view showing the structure of a sheet used in the present invention in which long strips of polyolefin are arranged in a plain weave. FIG. 1B is an explanatory view showing the structure of a sheet used in the present invention in which long strips of polyolefin are arranged in a twill pattern. FIG. 1C is an explanatory view showing the structure of a sheet used in the present invention in which long strips of polyolefin are arranged in a satin weave.

[Explanation of symbols]

 1: narrow narrow sheet

Claims (2)

[Claims] 1. A polyolefin sheet having a thickness of less than 1 mm, an area of each opening of 1 to 60 mm ² , and a total plane area of all the openings of 20 to 80% of the total plane area. A method for preventing aquatic organisms from adhering to underwater structures, comprising covering the entire draft portion of the underwater structures. 2. The polyolefin sheet according to JIS,
Tensile elongation measured according to L1096A is 15 to 3
The method for preventing aquatic organisms from adhering to underwater structures according to claim 1, wherein the aquatic structure has a tear strength of 3 to 9 kg as measured according to JIS L1096A-1.