JP2017158435A - Growth promoting fertilizer and growth promotion method of phytophagy bivalve - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a growth promoting fertilizer and a growth promotion method of a phytophagy bivalve that can promote growth of the phytophagy bivalve.SOLUTION: A growth promoting fertilizer of a phytophagy bivalve contains coal ashes, nitrogen compounds, phosphorus compounds, iron powder and citrate. A ratio of a nitrogen element: a phosphorus element: an iron element in the nitrogen compound, the phosphorus compound and the iron powder is 10-20:1:0.002-0.1. Also, a growth promotion method of the phytophagy bivalve comprises: a step of interposing the growth promoting fertilizer of the phytophagy bivalve in sediment of a tidal area; a step of disposing an anti-feeding damage network so as to cover the sediment plowing the growth promoting fertilizer of the phytophagy bivalve; and a step of disposing an anti-feeding damage plate so as to enclose a circumference of the sediment plowing the growth promoting fertilizer of the phytophagy bivalve.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a growth promoting fertilizer and a growth promoting method for herbivorous bivalves.

  Herbivorous bivalves that live in sand mud areas such as tidal flats and feed on microalgae (phytoplankton and attached microalgae), such as clams and clams, are important aquatic products. However, in recent years, the catch has decreased. For example, the domestic self-sufficiency of clams has dropped to about 40%. The main causes are considered as follows.

  Tidal flats are formed by the accumulation of sand, but organic particles also accumulate in the same manner, so that they fill the gaps between the sand particles, so that the exchange of water in the mud deteriorates and a sufficient amount of oxygen is not supplied. In this state, anaerobic decomposition that does not require oxygen is the mainstream for decomposition of organic substances, and hydrogen sulfide is generated by sulfuric acid reduction. Hydrogen sulfide is extremely toxic to living organisms, and this can reduce the number of bivalve molluscs.

  In addition, due to the recent restrictions on the total amount of nitrogen and phosphorus, oligotrophic progress has occurred especially in the Seto Inland Sea, and there are few microalgae (phytoplankton and attached microalgae) that feed on clams.

  In addition to this, it can be said that the clams are eaten before they become large due to predation by predatory organisms such as fish such as naruto ray and carnivorous snails such as mussels and crab.

  Conventionally, civil engineering methods such as tillage, aeration, dredging, and covering sand have been implemented as countermeasures for suppressing hydrogen sulfide, but there are problems of diffusion of pollutants, treatment of sludge after dredging, and high costs. In addition, as countermeasures for eutrophication, in recent years, in consideration of promoting the growth of laver, attempts have been made to release water from dams and relax sewage treatment water, but the growth of herbivorous bivalves in tidal flats such as clams There are no measures for promotion.

  Moreover, there exists a fertilizer which supplies the iron sulfide, nitrogen, and phosphorus which melt | dissolve in water as a countermeasure against hydrogen sulfide and poor nutrition (for example, patent document 1, patent document 2).

  In addition, as countermeasures against pests, attempts have been made to keep naruto rays and the like away by putting nets on tidal flats and hitting piles such as bamboo at narrow intervals.

JP2015-226511A JP 2006-345738 A

  In the fertilizers of Patent Documents 1 and 2, the compounding ratio for eluting iron, nitrogen and phosphorus is not clear, and it cannot be said that phytoplankton serving as a food for herbivorous bivalves can be effectively propagated, and as a result There is a problem that the growth of herbivorous bivalves cannot be promoted.

  Installation of nets, piles, etc. can suppress the predation of vegetative bivalves by nuisance organisms such as naruto ray, but cannot suppress nuisance organisms that move in the bottom mud.

  This invention is made | formed in view of the said matter, The place made into the objective is to provide the growth promotion fertilizer and growth promotion method of a vegetative bivalve which can promote the growth of a vegetative bivalve.

The growth promoting fertilizer for herbivorous bivalves according to the first aspect of the present invention,
Contains coal ash, nitrogen compounds, phosphorus compounds, iron powder, and citric acid,
The nitrogen compound, the phosphorus compound, and the ratio of nitrogen element: phosphorus element: iron element in the iron powder is 10-20: 1: 0.002-0.1,
It is characterized by that.

  The vegetative bivalve is preferably a clam.

The method for promoting the growth of herbivorous bivalves according to the second aspect of the present invention,
A step of interposing the growth promoting fertilizer of the herbivorous bivalve shell according to the first aspect of the present invention in the bottom mud of the tidal flat,
A step of disposing a net for preventing damage to cover the bottom mud in which the growth promoting fertilizer of the vegetative bivalve is spread;
Arranging a plate for preventing damage to surround the bottom mud in which the growth promoting fertilizer of the vegetative bivalve is placed,
It is characterized by that.

  Moreover, it is preferable to drive and arrange | position the said board for corrosion damage to the depth of 10 cm or more from the surface of bottom mud.

  In the growth promotion fertilizer and the growth promotion method of the vegetative bivalve according to the present invention, it is possible to promote the growth of vegetative bivalve such as clams.

It is a graph which shows transition of ammonium ion concentration in pore water. It is a graph which shows transition of the phosphate ion concentration in pore water. It is a graph which shows transition of the total dissolved iron ion concentration in pore water. It is a graph which shows transition of the weight per unit area of a clam. It is a graph which shows the relationship between the weight of a clam and the number of individuals. It is a graph which shows the average individual weight of a clam.

  The vegetative bivalve growth promoting fertilizer according to the present embodiment (hereinafter also simply referred to as growth promoting fertilizer) contains coal ash, nitrogen compounds, phosphorus compounds, iron powder, citric acid, manganese, and the like.

  By containing coal ash, iron powder, and citric acid, iron ions are eluted in water, which becomes chelated iron by citric acid, and the concentration of dissolved iron in water is significantly increased.

  Since this iron (II) ion chemically reacts with hydrogen sulfide to produce iron sulfide, the production of hydrogen sulfide due to sulfuric acid reduction that occurs in a reducing environment in a tidal flat is suppressed. Thereby, the production | generation of the hydrogen sulfide which is very toxic with respect to a vegetative bivalve etc. is suppressed, and one factor which inhibits the growth of a vegetative bivalve can be suppressed.

  Further, nitrogen sources such as ammonium ions and phosphorus sources such as phosphate ions are eluted from the nitrogen compounds and phosphorus compounds.

  Nitrogen and phosphorus are essential nutrients essential for the growth of microalgae that feed on bivalves. In addition, as described above, the growth-promoting fertilizer elutes iron (iron (II) ions) indispensable for the growth of microalgae. For this reason, the microalgae which are bivalve bait ingest these, and the growth and proliferation of microalgae are promoted.

  As the coal ash contained in the growth promoting fertilizer, so-called fly ash discharged from a coal-fired power plant is used. Since fly ash is produced in large quantities when coal is burned and its reuse is desired, it can be effectively reused as a raw material for coal ash granules.

  About a nitrogen compound and a phosphorus compound, if it is a compound which produces phosphate ion etc., such as ammonium ion in water, it will not specifically limit, For example, ammonium sulfate, sodium phosphate, etc. are mentioned.

  Further, the iron powder may be an alloy or an oxide as long as it contains iron atoms. Therefore, scrap iron or the like can also be used.

  The elemental ratio of nitrogen, phosphorus, and iron in the nitrogen compound, phosphorus compound, and iron powder is 16: 1: 0.005, and more preferably 10-20: 1: 0.002-0.1. This is because the average element ratio of microalgae is 16: 1: 0.005. Therefore, in the waters of tidal flats, there is an eutrophication situation in which nitrogen and phosphorus are deficient, and in a reducing environment, iron. Is suitable for the growth and proliferation of microalgae, which are the food necessary for the growth of herbivorous bivalves, even in the situation where hydrogen sulfide is spent on the oxidation of hydrogen sulfide.

  Thereby, the growth and proliferation of microalgae are promoted, and the growth of herbivorous bivalve molluscs that feed on this is promoted.

  The growth promoting fertilizer described above is manufactured by, for example, mixing coal ash, ammonium sulfate, sodium phosphate, iron powder, citric acid, adding gypsum and water to this, and bread granulation method, kneading granulation method, etc. can do. The kneading granulation method yields growth-promoting fertilizers with non-uniform sizes, and iron ions, ammonium ions, phosphate ions, etc. are quickly eluted from the small-size growth-promoting fertilizers, and large-size growth promotion. From the fertilizer, the above ions are continuously eluted, and it has excellent immediate effect and sustainability. Moreover, in the kneading granulation method, the growth promoting fertilizer can be manufactured in one step, which leads to a reduction in manufacturing cost.

  Then, the growth promotion method (henceforth a growth promotion method only) of the herbivory bivalve using the growth promotion fertilizer mentioned above is demonstrated.

  The growth promotion method includes the step of pouring the growth promoting fertilizer described above into the bottom mud of the tidal flat, the step of arranging a net for preventing damage to cover the bottom mud filled with the growth promoting fertilizer, And a step of arranging an anti-corrosion plate so as to surround the bottom mud containing the accelerated fertilizer.

  Bivalves such as clams live in the bottom mud such as tidal flats, and in order to improve the reducing environment of the bottom mud as described above, the growth promoting fertilizer is poured into the bottom mud.

  And the part where the growth-promoting fertilizer is sown is covered with a net for preventing damage so that the harmful organisms such as naruto ray will not eat the bivalves. The mesh size of the net for preventing damage is set to a size that does not allow the pests that inhabit the surrounding area to enter, for example, 5 to 10 mm.

  In addition, carnivorous snails such as tsumetagai and akanishi surround the area where the growth-promoting fertilizer is rubbed with a plate for preventing damage to prevent invasion of carnivorous organisms that move in the bottom mud. Since the above-mentioned tsumetamoai or the like usually does not dive 10 cm or more, it is preferable to drive and surround the plate for preventing damage to the depth of 10 cm or more from the surface of the bottom mud.

  Thus, in the growth promotion method, the bottom mud modification by the growth promotion fertilizer and the elution of nutrient components, and the prevention of the invasion of the pest by the damage prevention net and the damage prevention plate, Since growth is promoted and feeding of the herbivorous bivalve by pests is prevented, the growth of the bivalve can be effectively promoted.

In the Urasaki tidal flat in Urasaki-cho, Onomichi, we verified the promotion of clam growth. Four sections (1.44 m ² ) of 1.2 m × 1.2 m were formed on the tidal flat. About each division, in order to prevent the invasion of the pests moving under the bottom mud such as tsumetagai, the plate for damage prevention was driven and surrounded by 10 cm or more from the bottom mud.

In three of these sections, 0.69 kg (479 g / m ² ), 1.38 kg (958 g / m ² ), 2.76 kg (1917 g / m ² ) of the growth-promoting fertilizer was placed. These are referred to as 500 g, 1000 g and 2000 g, respectively. In addition, what was manufactured by the kneading | mixing granulation method (particle size of 2 mm-15 mm) was used for the fertilizer in the component and weight ratio shown in Table 1.

  Moreover, the growth promoting fertilizer was not sown in the remaining one section. This is referred to as the target ward.

For each of the four sections, clams (approximately 5 mm) were released on May 19, 2015. The discharge flow rate was 1,000 / m ² , respectively.

  And each division was covered with a net for preventing damage (9 mm mesh).

  And on May 19, 2015, July 30, 2015, September 27, 2015, and November 25, 2015, the bottom mud of each section was collected, and the ammonium ion concentration in the pore water The phosphate ion concentration and the iron (II) ion concentration were measured. 1, 2 and 3 show the measurement results of the ammonium ion concentration, phosphate ion concentration and iron (II) ion concentration, respectively.

Also, the clams that inhabit 1m per ^second each compartment was collected, the total weight of the clam, the number of clams, and were measured individual weight clams. 4, 5, and 6 show measurement results of the total weight of the clams, the number of clams, and the individual weight of the clams. In the 500 g section, the damage prevention net was damaged, so the total weight of clams, the number of clams, and the individual weight of clams were not measured in September and November.

  1, 2, and 3, the ammonium ion concentration, phosphate ion concentration, and iron (II) ion concentration tend to be high in the 1000 g section and the 2000 g section, but have a large relationship depending on the amount of the growth promoting fertilizer. Sex was not seen. Because these ions are ingested by microalgae, and because iron (II) ions are used for the oxidation of hydrogen sulfide, there is no significant relevance depending on the amount of growth-promoting fertilizer. Conceivable.

  The total weight of clams in FIG. 4 is larger in the 500 g, 1000 g, and 2000 g districts where the growth-promoting fertilizer is introduced, and the amount of the growth-promoting fertilizer is almost the same. It can be seen that the total weight is large. The total weight decreased in November compared to September. This is thought to be due to the natural death of clams.

  In addition, the number of clams in FIG. 5 is not significantly different in each section, but there is a tendency that the ratio of individuals having a large weight is large in the 2000 g section. In addition, the average solid weight of the clams in FIG. 6 varies from section to section, and the weight is the largest in the 2000 g section. From this result, it can be seen that the application of the growth-promoting fertilizer promotes the growth of clams and increases the clams.

  The growth promoting fertilizer for vegetative bivalves and the growth promoting method for vegetative bivalves can promote the growth of herbivorous bivalves such as clams and can be used for culturing vegetative bivalves.

Claims (4)

Contains coal ash, nitrogen compounds, phosphorus compounds, iron powder, and citric acid,
The nitrogen compound, the phosphorus compound, and the ratio of nitrogen element: phosphorus element: iron element in the iron powder is 10-20: 1: 0.002-0.1,
This is a fertilizer that promotes the growth of herbivorous bivalves. The vegetative bivalve is a clam,
The growth promoting fertilizer for herbivorous bivalve according to claim 1. A step of interposing the growth promoting fertilizer of the herbivorous bivalve according to claim 1 or 2 in the bottom mud of a tidal flat,
A step of disposing a net for preventing damage to cover the bottom mud in which the growth promoting fertilizer of the vegetative bivalve is spread;
Arranging a plate for preventing damage to surround the bottom mud in which the growth promoting fertilizer of the vegetative bivalve is placed,
A method for promoting the growth of herbivorous bivalves characterized by the above. Placing the plate for preventing damage to the depth from the surface of the bottom mud to a depth of 10 cm or more,
The method for promoting the growth of herbivorous bivalves according to claim 3.

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