JP2002281860A - Artificial seaweed bed and fish bank - Google Patents

Abstract

PROBLEM TO BE SOLVED: To protect seaweeds and marine algae from feeding damage and thereby increase fish gathering effect and make them easily fixable. SOLUTION: An artificial seaweed bed and fish bank comprises a three- dimensional spring structure formed by mutually contacting, entangling and gathering adjacent filaments which are thermoplastic resin-made continuous filaments and/or short filaments, and randomly looped or curled. Iron pieces are included in the three-dimensional spring structure.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an artificial seaweed bed and a fish reef, which can be used for a long period of time without causing marine pollution, and also exhibit an excellent fish collecting effect. It relates to the manufacturing method.

At present, in all parts of the world, a phenomenon has occurred in which seaweeds and seaweeds die and become barren, and fish and shellfishes that feed on them disappear. The so-called rocky shores, where the seaweeds were overgrown and the seaweeds died for some reason,
It is a phenomenon that the seabed is occupied by the red alga Coralaceae Ezoisogoromo called lime algae instead of lime, and the bedrock shows a white or yellow / pink color. Despite the progress, it has not yet been determined the cause.

[0003] Until now, the cause of this has been,
Freshwater injection theory, river flooding theory, nutrient deficiency theory, extreme weather theory,
Various theories, such as the theory of water pollution, deforestation, and algae-eating animals, have been cited.

[0004] Iron ions are components necessary for seaweed to take in nutrients into the body and for biosynthesis of pigments for photosynthesis. Feeding damage means that the young leaves of seaweed and seaweed are eaten by seafood such as shellfish and sea urchins.

[0005]

2. Description of the Related Art Concrete and steel artificial fishing reefs are mainly used as measures to prevent the death of seagrass and seaweeds, but there are few examples in which they function effectively.

[0006] Currently existing fishing reefs are mainly made of concrete and steel.

[0007]

Problems to be solved by the present invention The following problems remain in the concrete and steel seaweed beds and fish reefs.

Concrete reefs made of concrete Concrete is strongly alkaline, having a pH of 10 to 13, so it takes 2 to 3 years for seaweeds to form, and no immediate effect can be expected. In addition, the roots of the set seaweeds and seaweeds may be attacked by alkali and fall off, and the young leaves from the algae-eating fish and shellfish may be so damaged that seaweed, seaweed and the like cannot be seeded.

Since the surface of a steel reef is smooth, the rate of settlement is low and the effect of collecting fish is low. In addition, there is a problem that seaweed, seaweed and the like cannot be seeded.

[0010] The present invention provides an inexpensive and easy-to-install algae artificial algal bed / fishing reef.

In the present invention, since iron ions can be supplied to seaweeds and phytoplankton growing in the sea from cast iron contained in the three-dimensional spring structure, it is effective for the propagation of seaweeds. Moreover, it is easy to compound with concrete or iron, and the construction is easy. Furthermore, since the three-dimensional spring structure is three-dimensional, it is possible to protect the young leaves rooted inside the three-dimensional spring structure from damage caused by algivorous fish and shellfish. Further, since the fishway can be manufactured freely, the effect of collecting fish can be enhanced, and spores such as laver and seaweed can be formed.

[0012]

The artificial seaweed bed and fish reef of the present invention are formed by contacting and intertwining adjacent filaments of a random loop or curl of continuous filaments and / or short filaments of thermoplastic resin. A three-dimensional spring structure is formed, and an iron piece is included in the three-dimensional spring structure.

Further, in the three-dimensional spring structure, a dense part formed with a high porosity and a dense part formed with a lower porosity than the dense part are provided. When the porosity is included and the average porosity of the dense and dense portions is 30% to 98%, the rate of formation of seaweed and seaweed can be made effective.

The average porosity is preferably 50%.
When the content is in the range of% to 95%, more preferably in the range of 70% to 80%, a more efficient formation rate can be obtained.

[0015] A space is formed in the outer periphery of the three-dimensional spring structure where the filaments are not formed, and iron, preferably cast iron, is inserted into this space to supply iron ions to seagrass. Therefore, the three-dimensional spring structure can be fixed to an underwater construction facility such as an existing artificial reef, a breakwater or a wave-dissipating block or a caisson, and can be easily constructed.

A high-density portion or a sheet portion is formed on an outer edge or a bottom side of the three-dimensional spring structure, and for example, mortar or mortar and concrete are filled and solidified in the three-dimensional spring structure. Can be installed.

[0017]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, embodiments of the present invention will be described below with reference to the accompanying drawings.

Iron can be included in the three-dimensional spring structure 30, and a part of the three-dimensional spring structure 30 can be attached to an existing structure such as concrete, or concrete and the three-dimensional spring structure 30 can be integrally formed. Seaweed bed breeding material and artificial reef.

This fishing reef comprises a three-dimensional spring structure 30 having a role of growing seaweed and seaweed, iron pieces 60 for releasing iron ions, and concrete 40 serving as a weight.

(Three-dimensional spring structure) The three-dimensional spring structure 30 of the present invention is formed with a porosity that does not hinder the growth of seaweed and seaweed, and is used in water for a long period of time and grows seaweed and seaweed. It has a strength that can withstand the weight, and a predetermined density of continuous linear and / or short linear random loops of thermoplastic resin or adjacent linear lines of curls, It is a resin molded product having a spring-like three-dimensional structure having a gap.

The three-dimensional spring structure 30 is, for example, melt-extruded from a plurality of nozzles at a predetermined extrusion speed, and is taken out by a take-up machine described later, for example, from 600 to 90,000 denier, preferably from 3,000 to 30,000.
Denier, more preferably form a solid or hollow continuous filament of 6,000 to 10,000 denier, in the molten wire, for example, to form a loop of 1 to 10 mm in diameter, preferably 1 to 5 mm in diameter, adjacent wires While forming a random loop by contact entanglement with the strip in the water, the take-up speed of the take-up machine is adjusted to a low speed at an arbitrary interval by the take-up machine 13 in the water, and the length in the longitudinal direction is 5 to 10 cm. A portion having a large bulk density at the time of low-speed take-off, that is, a high-density portion B and other coarse portions, that is,
It can be manufactured by forming a three-dimensional spring structure of up to 30 cm and width of 1,000 mm (FIG. 1). At least a portion of the contact entangled portions of the filaments formed in this way are melt-bonded to each other.

The continuous filaments and / or short filaments have a solid or hollow cross-sectional shape, and a wire diameter of (solid) 0.5.
~ 3 mm, preferably 0.7-2 mm. (Hollow) 0.7-5 mm. Preferably it is 1-3 mm. Further, the hollow rate of the hollow wire is,
30-70%. Preferably it is 40 to 60%.

The continuous filament and / or the short filament may be a thermoplastic resin in general, but an olefin resin is preferred. More preferably, it is made of a thermoplastic elastomer, for example, an elastomer of polypropylene, polyester, nylon, or PVC.

The bulk density of the three-dimensional spring structure is 0.009 to 0.280 g / cm ³ , preferably 0.027 to 0.2
10, in particular 0.045~0.09, 0.45~1.25g / cm ³ at the portion of the dense,
Preferably it is 0.54 to 1.17, especially 0.63 to 1.10.

The porosity of the three-dimensional spring structure is 80 to 99%, preferably 85 to 97%, particularly 90 to 95% in a rough portion.
%, 40-90% in the dense part, preferably 70-90%, especially
75-85%. The average porosity of the entire seaweed epiphytic area is 30 to 98%, preferably 50 to 95%, and more preferably 70 to 80%.

(Manufacturing Method of Three-Dimensional Spring Structure) As shown in FIG. 1, the three-dimensional spring structure is prepared by introducing, for example, a polypropylene elastomer as a raw material resin from a hopper 11 of an extruder 10 and melt-kneading the same. And extruded from a number of injection ports having a predetermined diameter provided in the molding die 12, and a take-up roll 1 of a take-up machine 13 in a bus 15 is provided.
A three-dimensional spring structure which is a resin molded product having a thickness and a bulk density set between 4, 14 and being solidified in water while being randomly formed into a curl or a loop, and having a spring structure by winding rolls 16, 16. It is taken out as 30. An example of the molding die 12 used for extruding the filament forming the three-dimensional spring structure 30 is shown in FIGS.
As shown in FIG.

As shown in FIG. 2, a forming die 12 for extruding a filament forming the three-dimensional spring structure 30 is provided.
Is provided with a number of nozzles 21 through which a filament of synthetic resin is extruded, and the resin material extruded from the nozzle 21 is solidified to form a filament.

In this embodiment, the molding die 12
A core 22 having a rectangular cross-section in the width direction protruding in the injection direction is provided. In the core 22, a portion of an iron piece such as an iron pipe or a wire having a role as a fishway is provided. The space 31 that does not exist is configured to be formed in the three-dimensional spring structure 30.

When the three-dimensional spring structure 30 is disposed in a river or the like, the space 31 having no filament formed by the core 22 in this way becomes a place for living things such as fish or a fishway. And so on.

In this embodiment, as shown in FIGS. 2 and 3, the core is formed in a rectangular shape in the cross section in the width direction. As described above, as long as the space 31 that can be a living place of a living thing or a fishway can be formed in the three-dimensional spring structure 30,
A part of the nozzle may be closed or, instead of the above-described rectangle, may be formed into a columnar shape or any other shape. When the space 31 is not provided, the core body 22 is not provided on the molding die 12, Alternatively, it is not necessary to close a part of the nozzle.

The three-dimensional spring structure 30 described above has the same three-dimensional spring structure and the following active parts coexist.

Epiphytic portion of seaweed / seaweed exposed in the sea (substantially the entirety) Inserting iron pieces or concrete, space 31 used as a fishway High density portion B for shielding concrete or sheet portion 43 Low density filled with concrete Part A The average porosity of the formation site is 30 to 98%. Preferably 50-95%. More preferably 70-80%. If it is less than 30%, the surface becomes smooth and the rate of formation of seaweed and seaweed decreases. At 98% or more, the surface area of the three-dimensional spring structure is small, and the deposition rate is reduced. In addition, the settled seaweed and seaweed cannot be protected from seafood such as sea urchins and shellfish.

The porosity of the high-density portion or sheet portion serving as a fresh concrete shielding portion is 0 to 70%. Preferably, 30
~ 50%. If it is more than 70%, ready-mixed concrete cannot be shielded. The porosity of the site where the ready-mixed concrete is filled and buried is 70-98%. At less than 70%, ready-mixed concrete is not filled. At 98% or more, there are few filaments, and the three-dimensional spring structure and concrete are not integrated.

Further, the three-dimensional spring structure 30
Are formed with different densities so that the high-density portion B shields the fresh concrete 40 when integrally molded with the concrete 40 and burying a part of the three-dimensional spring structure. That is, one portion is formed at a high density and the other portion is formed at a low density at the upper and lower different densities with respect to the thickness direction vertical surface.

The high-density portion can be manufactured by narrowing the interval between the nozzles 21, and the low-density portion can be manufactured by increasing the interval between the nozzles 12 (FIG. 5).

In the molding die 12, the sheet portion 4
3 is formed into a slit 41 having a slit width of 0.2 to 3 mm, preferably 0.7 to 1.5 mm (FIG. 6), so that it is integrally molded with concrete to bury a part of the three-dimensional spring structure. A vertical surface in the thickness direction can be formed in a sheet shape so that the ready-mixed concrete is shielded by the sheet portion 43 on the central surface.

And, in the three-dimensional spring structure,
The iron piece 60 is included. The iron piece 60 contains silicon, calcium, and manganese, which are one kind of minerals, and is advantageous for the growth of seaweeds and seaweeds. In addition, the iron piece 60 has a large carbon content and has advantages such as reduced corrosion by seawater. Is preferred. The iron piece 60 such as a cylinder, a rectangle, or a pipe can be inserted into the space 31. In addition, in a three-dimensional spring structure forming apparatus, an input port of a parts feeder is provided between the forming die 12 and a take-off machine 13 provided in water. Provided,
Immediately before the molten wire is hardened, an iron block of an arbitrary shape is entangled with the wire (not shown), so that the iron piece can be sandwiched between the wires and included.

Alternatively, a method may be used in which the three-dimensional spring structure is formed into a multilayer structure, and iron is sandwiched between the three-dimensional spring structure and its intermediate part, upper part or lower part.

The concrete 40 serves as a weight for placing the three-dimensional spring structure 30 containing the iron 60 on the sea floor in the sea. As a method of integrating the three-dimensional spring structure and concrete, concrete is used. When creating a new one, the three-dimensional spring structure 3
0, a dense portion A is provided between adjacent dense portions B
Inject ready-mixed concrete into A and allow it to harden. Since the ready-mixed concrete is shielded in the high-density portion, a part of the three-dimensional spring structure can be embedded in the concrete 40.
(FIG. 7).

The forming die 12 having the slit 41
Part 43 inside the three-dimensional spring structure manufactured by
With concrete as a boundary, ready-mixed concrete is poured into one side and hardened. The concrete is shielded by the seat portion 43, and a part of the three-dimensional spring structure can be embedded in the concrete. (FIG. 8)

Further, a portion to be exposed on the surface is formed into a low density, air mortar is injected and hardened, and then fresh concrete is injected. In addition to the method of removing the air mortar after hardening of the ready-mixed concrete by high-pressure water jet washing, etc., a hole is made in the existing concrete body, a through hole is formed in the iron-containing three-dimensional spring structure, and it is fixed as a weight by fixing it with an anchor etc. Is also good.

In addition to the above-described embodiment, as an application example, a three-dimensional spring structure in which iron is included integrally with at least a part of an arbitrary-shaped wave-dissipating block can be applied.

In the case of manufacturing as a wave breaking / seawall block, a part of the three-dimensional spring structure can be obtained by arranging the three-dimensional spring structure in the formwork 42 and then injecting the ready-mixed concrete 40 into the mold. Is buried in concrete and can be integrally molded (Fig. 7).

It is also possible to join a three-dimensional spring structure to an existing artificial reef, a breakwater or an underwater construction facility such as a wave-dissipating block or caisson. In this case, a hole can be made in the surface of the wave-dissipating / seawall block or the like and the surface can be joined by anchoring or the like through a through hole in the dense part of the three-dimensional spring structure.

A hole formed in a dense part of a three-dimensional spring structure including iron is passed through a column standing on the sea floor.
At this time, the three-dimensional spring structure can be lifted and moved up and down in response to a change in water level so as to be balanced, or the spring structure can be fixed to a column.

According to the present invention, ions emitted from a casting inserted into a three-dimensional spring structure are useful for photosynthesis of kelp and can contribute to the growth of kelp. Provides plankton nutrition.

Oxygen is released by photosynthesis of seaweed, phytoplankton, and seaweed overgrown in the three-dimensional spring structure, and the ecosystem of seafood cultivation and the marine environment are prepared.
In addition, there is a resource increase and stabilization effect for all seafood grown in early spring.

In addition to absorbing nutrients that cause eutrophication, the cushion structure prevents invasion to the inner leaflets of sea urchins and shellfish, etc .. It has a feed effect, a fish collecting effect, and a protective effect for infants.

[Brief description of the drawings]

FIG. 1 is an explanatory view showing an apparatus for manufacturing a three-dimensional spring structure,

FIG. 2 is a front view of a molding die,

FIG. 3 is a bottom view of a molding die,

FIG. 4 is a left side view of a molding die,

FIG. 5 is an enlarged view of a main part of a nozzle portion showing a modified example of a molding die,

FIG. 6 is an enlarged view of a main part of a nozzle portion showing another modified example of a molding die;

FIG. 7 is an overall view showing an embodiment in which concrete is configured as a weight,

FIG. 8 is an overall view showing another embodiment in which concrete is configured as a weight.

[Explanation of symbols]

 REFERENCE SIGNS LIST 10 extruder 11 hopper 12 forming die 13 take-up machine 14 take-up roll 15 bus 16 take-up roll 30 three-dimensional spring structure (artificial seaweed bed / fish reef) A coarse / dense part B dense / dense part 40 concrete (mortar) 41 slit 42 formwork 43 Seat part 60 Iron piece

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Hiroshi Maruyama 8-3-3-401 Arima, Miyama-ku, Kawasaki City, Kanagawa Prefecture (72) Inventor Takashige Kondo 1-17-18 Minamiyukiya, Ota-ku, Tokyo F-term (reference) 2B003 AA01 BB00 BB03 DD02 DD03 EE04 2B026 AA05 AB05 AC05

Claims (7)

[Claims] 1. A three-dimensional spring structure formed by contacting and entangling adjacent filaments of random loops or curls of continuous filaments and / or short filaments of a thermoplastic resin,
An artificial seaweed bed / fish reef, wherein an iron piece is included in the three-dimensional spring structure. 2. A three-dimensional spring structure formed by contacting and intertwining adjacent filaments of random loops or curls of continuous filaments and / or short filaments of a thermoplastic resin,
The three-dimensional spring structure includes an iron piece in the three-dimensional spring structure, and includes a dense part formed with a high porosity and a dense part formed with a lower porosity than the dense part, and an average gap between the dense part and the dense part. An artificial seaweed bed / fish reef characterized by a rate of 30% to 98%. 3. The average porosity is preferably 50% to 9%.
The artificial algal bed / fish reef according to claim 2, wherein the content is 5%, more preferably 70% to 80%. 4. The artificial seaweed bed / fish reef according to claim 1 or 2, wherein the artificial seaweed bed / fish reef is provided with a space which is open at an outer periphery thereof and where the streak is not formed. 5. The artificial seaweed bed / fish reef according to claim 4, wherein an iron piece made of iron, preferably cast iron, is inserted into said space. 6. The artificial structure according to claim 1, wherein the three-dimensional spring structure is fixed to an existing underwater construction facility such as an artificial fishing reef, a breakwater or a wave-dissipating block / Caisson. Seaweed beds and fish reefs. 7. The three-dimensional spring structure according to claim 1, wherein a high-density part or a sheet part is formed on an outer edge or a bottom side of the three-dimensional spring structure, and concrete is filled and solidified in the three-dimensional spring structure. Artificial algae bed and fish reef.