JP3169581U - Hardened product for seaweed formation - Google Patents

Abstract

The present invention provides a hardened product for creating seaweed beds that can efficiently supply divalent iron ions to living organisms. Cement, steel slag ground to 40 mm or less, spoiled hardwood chips of about 20 to 80 mm, and water are mixed, and the resulting mixture is driven into a mold. And it is made to cure in a mold until it hardens | cures. Next, the concrete obtained by curing in the mold is crushed so that the unit volume mass is 2 to 3 ton / m 3, thereby obtaining the concrete for building a seaweed bed whose surface shape is a natural stone shape. [Selection] Figure 1

Description

  The present invention relates to a cured product for creating seaweed beds. Specifically, the present invention relates to a cured product for seaweed bed construction that is dropped into the sea and is useful for the creation of seaweed bed.

  In recent years, seaweeds such as kelp and seaweed that grow in shallow waters have decreased, and seaweed like a thin pink shell called coral (lime algae) has covered the surface of rocks on the seabed. The phenomenon called is having a big impact on fisheries.

  That is, corals that cover the sea bottom secrete substances that interfere with the attachment of other seaweeds from the surface, or peel off surface cells so that other seaweeds do not grow on their bodies. When burned, it is difficult to recover large algae (disappearance of algae beds). And the disappearance of small fish hideouts and spawning grounds makes it impossible for small fish and large fish that eat small fish to come close, and landings are decreasing year by year.

  Also, the disappearance of the seaweed bed not only loses the place of life and spawning for marine animals, including many fish, but also a plant that has become a very important part of the marine ecosystem for photosynthesis. The loss of flocks will greatly affect the marine ecosystem.

As one of the causes of firewood burning, “bivalent iron ions (Fe ²⁺ )”, which are easily absorbed by seaweeds, have been supplied from forests to the sea through rivers. It is mentioned that the supply amount of divalent iron ions has decreased due to the creation.

On the other hand, for example, in Patent Document 1, a groove-shaped recess having a large ridge corner is formed on the surface of the block body, and one or more relatively small grooves are provided adjacent to the groove-shaped recess. A settling block is described in which a plate-like breeding material formed by mixing and curing a vitreous material containing cemented iron containing valent iron and cement mortar is disposed in a groove-like recess.
Patent Document 2 describes a block obtained by mixing 10 to 60% by mass of molten sulfur with 70 to 30% by mass of blast furnace slag and 20 to 10% by mass of coal ash and molding and solidifying the block.

Japanese Patent No. 2640926 Japanese Patent Laid-Open No. 2002-45078

However, as in the inventions of Patent Document 1 and Patent Document 2, even when divalent iron ions that can be ingested by photosynthetic organisms such as seaweed are eluted, the divalent iron ions are easily oxidized by oxygen in water. It becomes iron ions and immediately precipitates as Fe ₂ O ₃ , making it impossible for organisms to ingest.

  The present invention has been made in view of the above points, and an object of the present invention is to provide a cured product for seaweed formation that can efficiently supply divalent iron ions to living organisms.

  In order to achieve the above object, the hardened product for seaweed bed creation of the present invention is a hardened product of a composition containing a solidifying material, steel slag, wood chips, and water.

  Here, fulvic acid is released from wood chips, and divalent iron ions released from steel slag combine with fulvic acid to produce stable iron fulvic acid that is water-soluble and has a long life and is not easily oxidized in seawater. it can.

Also, if the unit volume weight of the seaweed Construction for the cured product of the present invention is 2-3 tons / m ^3, even if the wave becomes hard to roll is cured for seaweed Construction preferable.

  Furthermore, when the surface shape of the hardened material for creating seaweed beds of the present invention is a natural stone shape, voids are likely to be formed when the hardened materials for creating seaweed beds are stacked, so that fish tend to bite.

  Moreover, in the hardened material for creating seaweed beds of the present invention, when the composition contains manure, since manure contains protein, amino acids, urea, uric acid, etc., ammonia is generated during decomposition and released from steel slag. Bivalent iron ions and ammonia can be complexed to produce a substance that is difficult to oxidize like iron fulvic acid.

  Moreover, in the hardened | cured material for seaweed bed construction of this invention, when a solidification material is cement, the intensity | strength of hardened | cured material can be made high compared with another solidification material.

  In addition, in the cured product for creating a seaweed bed of the present invention, when at least a part of the wood chip rots, fulvic acid is easily released, and the wood chip rots and disappears, so that a hole is formed at the position of the wood chip. As a result, the cured product becomes porous, and irregularities are formed on the surface of the cured product, which makes it easier for seaweed seeds to adhere.

  Moreover, in the hardened | cured material for seaweed bed construction of this invention, when a composition contains humus, fulvic acid is also released from humus and can produce more fulvic acid iron.

  Moreover, in the hardened | cured material for seaweed bed creation of this invention, when a composition contains charcoal, fulvic acid is discharge | released also from charcoal and it can produce | generate more fulvic acid iron.

  The cured product for seaweed formation according to the present invention can efficiently supply divalent iron ions to living organisms.

It is the schematic which shows the construction example which used the hardened | cured material for seaweed bed construction of this invention as a covering stone in the sea. It is the schematic which shows the construction example which used the hardened | cured material for seaweed bed construction of this invention as a construction material in the sea.

The cured product for creating seaweed beds of the present invention is a cured product of a composition containing a solidifying material, steel slag, wood chips, and water.
Here, as the solidifying material, a general solidifying material can be used, but cement is preferable because the strength of the cured product can be made relatively high.

In addition, steel slag is a steel by-product generated in the steel manufacturing process. Secondary refining slag, ingot slag, etc. are included. These can be used as one kind or a mixture of two or more kinds.
Moreover, steel slag stably contains divalent iron (FeO or Fe ₃ O ₄ ) that is easily oxidized and unstable. In particular, the converter slag contains 20% divalent iron, and the amount generated is large, so that the supply is easy and the solubility of iron ions is high. Therefore, it is preferable as a material for eluting divalent iron ions.
Although divalent iron is easily eluted during oxidation in water and is absorbed by living organisms in the form of divalent iron ions, divalent iron is a very unstable substance.

The wood chip is a chip made of waste wood or the like, and decays to release fulvic acid. Since fulvic acid is water-soluble, has a carbol group and a carbonyl group, and has a function of binding iron, iron ions bind to fulvic acid, and stable fulvic acid iron is generated even in water.
Further, since rotates and releases fulvic acid, it is preferable to use wood chips that are at least partially rotten.
Moreover, said composition can also contain humus and charcoal (for example, charcoal).

  The mixing ratio of the solidified material, the steel slag, the wood chip, and the water may be any ratio. For example, the ratio of the solidified material: steel slag: wood chip: water is 1: 10: 4: 1.5. In this case, a cured product having a certain amount of voids and a high compressive strength can be obtained.

FIG. 1 is a schematic view showing a construction example in which the hardened material for creating a seaweed bed of the present invention is used as a covering stone in the sea. Moreover, FIG. 2 is the schematic which shows the construction example which used the hardened | cured material for seaweed bed creation of this invention as a construction material in the sea.
Cement, steel slag crushed to 40 mm or less, spoiled hardwood chips (an example of wood chips) of about 20 to 80 mm, and water were mixed, and the resulting mixture was poured into a mold. And it was made to cure in a mold until it hardened. Next, the concrete obtained by hardening in the formwork is crushed so that the unit volume mass is 2 to 3 ton / m ^3, and the concrete for surface seaweed formation with a natural stone shape (algae bed) This is an example of a cured product for preparation.) 1 was obtained.
In addition, as long as the mixture can be cured, it is not always necessary to drive the mixture into the mold and cure it in the mold.
As shown in FIG. 1, the obtained concrete 1 for constructing a seaweed bed was dropped into seawater 2 and spread over so as to cover rubble and the like to form a covering stone. About 1 to 2 months after spreading, the growth of seaweed 3 could be confirmed on the concrete 1 for building the seaweed beds.

  Moreover, as shown in FIG. 2, the concrete 1 for seaweed bed construction obtained similarly was dropped and accumulated in the seawater 2, and it was set as the koji material. About 1 to 2 months after stacking, the growth of seaweed 3 could be confirmed on the concrete 1 for constructing the seaweed bed.

In addition, a seed string with seaweed spores attached is wrapped around the semi-cylindrical cured product of the seaweed bed creation of the present invention, and after about 10 cm of seaweed sprouts extend from the wound seed thread, the seed thread is wound. By placing the cured product for creating a seaweed bed of the present invention on the concrete 1 for creating a seaweed bed shown in FIGS. 1 and 2, seaweeds can be further increased.
Further, for example, by putting seawater containing spores of seaweed into a water tank and further putting a thread into the seawater, seed yarns with attached seaweed spores can be obtained.

Since fulvic acid iron is originally produced in humus soil in forests, humus soil and steel slag are also put into sandbags as needed to pass seawater, etc., and this sandbag containing humus soil is put into the sea. It is also possible to create a seaweed bed by dropping it, but as it is clear from the fact that it is used when building a dike, even if the sandbags are stacked, it is difficult to form a gap between the sandbags, and it is mixed into the humus soil temporarily. Even if the wood chip that rots down, the sandbag is not solidified, so the sandbag containing humus soil does not become porous like the woodchip in concrete decays.
In contrast, the seaweed bed building concrete of the present invention is solidified and the surface shape is a natural stone shape, so when stacked as shown in FIG. It is formed, and it becomes easy for fish to bite into the formed gap. In addition, the concrete for seaweed basin itself also decays and disappears due to the decay of the wood chips, so that holes are formed at the positions of the wood chips and the concrete for seaweed basin construction becomes porous. And seaweed seeds are more likely to adhere.

  As described above, the concrete for building a seaweed bed of the present invention is a cured product of a composition containing steel slag and hardwood chips, so that fulvic acid is released by hardwood chips and divalent iron ions released from steel slag. Combined with fulvic acid, water-soluble, long-lived and stable iron fluorate that is difficult to oxidize in seawater can be generated. Therefore, divalent iron ions are efficiently supplied to organisms in the form of stable iron fulvic acid. it can.

In addition, since the concrete for seaweed bed construction of the present invention has a unit volume mass of 2 to 3 ton / m ³ , when the concrete for seaweed bed construction is placed in the sea, the concrete for seaweed bed construction is difficult to roll even if there is a wave. .

  Furthermore, the concrete for building algae beds of the present invention is a cured product of a composition containing rotten hardwood chips, so that fulvic acid is easily released and the hardwood chips decay and disappear, so that the hardwood chips are positioned. The pores are formed to make the algae bed construction concrete porous, and irregularities are formed on the surface of the algae bed construction concrete so that the seeds of seaweed are easily attached.

1 Concrete for creating seaweed beds 2 Seawater 3 Seaweed

Claims (8)

Solidifying material,
Steel slag,
Wood chips,
Including water,
A cured product for seaweed formation, which is a cured product of a composition in which the blending ratio of solidified material, steel slag, wood chip, and water is 1: 10: 4: 1.5. The cured product for creating seaweed beds according to claim 1, wherein the unit volume mass is 2 to 3 ton / m ³ . The cured product for seaweed formation according to claim 1 or 2, wherein the surface shape is a natural stone shape. The hardened | cured material for seaweed bed creation as described in any one of Claims 1-3 in which the said composition contains manure. The hardened material for seaweed formation according to any one of claims 1 to 4, wherein the solidifying material is cement. The hardened | cured material for seaweed bed creation as described in any one of Claims 1-5 in which at least one part of the said wood chip was spoiled. The hardened material for seaweed formation according to any one of claims 1 to 6, wherein the composition includes humus. The said composition contains charcoal. Hardened | cured material for seaweed bed creation as described in any one of Claims 1-7.

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