RU2808835C1 - Method of combating filamental algae - Google Patents

Abstract

FIELD: fishing industry.

SUBSTANCE: method of combating filamentous algae is characterized by adding the following to water for filamentous algae Cladophora glomerata (L.): a mixture of crushed shungite in an amount of 10.0 g and an organic algaecide monuron in an amount of 0.1 g or a crushed mixture of muscovite, phlogopite and glauconite in an amount of 10.0 g with the addition of an algaecide of the quinone class — the organotin compound dichloron 2,3-dichloro-1,4-naphtho-quinone in an amount of 0.1 g for filamentous algae of Oedogonium genus, or a mixture of crushed vermiculite in an amount of 0.5 kg and clinoptilolite in an amount of 0.5 kg with the addition of CuC₂ in an amount of 10 g and triethanolamine in an amount of 10 g for filamentous algae of Spirogyra genus.

EFFECT: increasing the efficiency and environmental friendliness of cleaning a reservoir from plant formations using long-acting algaecide compositions.

1 cl, 3 ex

Description

Field of technology to which the invention relates

The invention relates to the field of fisheries and water reclamation, namely to methods for suppressing the growth of plant formations and can be used in the fight against filamentous algae in fish ponds (including decorative ones), canals, reservoirs and cooling ponds.

State of the art

In practice, various chemicals are used to combat algae - algaecides, which include various substances and compositions.

A method for destroying filamentous algae is known from the prior art (No. SU1524865, IPC A01N59/00, A01P13/00, C02F1/50, published 11/30/1989). by treating canal water with nitrogen fertilizer containing ammonium salts and leading to inhibition of algae.

There is a known method (No. SU180017, A01N29/10, A01N33/18, 02/28/1966) to combat filamentous algae using the active algaecide benzotrichloride, which is an organochlorine compound. This is an effective means of combating filamentous algae and at the same time stimulating the development of green algae in water bodies.

Algaecides used in known methods are more or less toxic to fish and other aquatic organisms, and their use is associated with the creation of fairly high concentrations in the water of a reservoir. At the same time, their long-term repeated use causes a cumulative effect and negatively affects the general condition of the reservoir ecosystem.

A known composition containing peroxyhydrates of alkali metal carbonates and bicarbonates of alkali metals (No. RU2406698, A01N59/00, A01N59/04, C01B15/103, C02F1/50, C02F1/66, C02F1/722, C02F2103/20, publ. 20.1 2.2010) . This composition is known as an environmentally friendly means for destroying filamentous algae. However, to completely destroy the filament, it is necessary to add peroxide in an amount of 0.4-0.5 ml/l for at least 10 days, which is twice the safe concentration for fish and plants. At the same time, the application of peroxide in an amount of 0.25 ml/l for more than 20 days causes severe suppression of the filament, but it does not die and is restored quite quickly.

There is a known method of combating the proliferation of filamentous algae (publication No. CN115119854 A, IPC A01N25/10, A01N25/26, A01N59/20, A01P13/00, C02F1/50, 09/30/2022) using a complex algaecide, which includes a degradable copolymer, methyl cinnamate, a fungicide for nitrifying bacteria, sodium acetate and ferrite particles capable of adsorbing heavy metal ions. The complexing agent has relatively weak acute toxicity, but at the same time effectively destroys filamentous algae.

There is a known method of combating filamentous algae, where phosphogypsum is used as an algaecide (patent No. BY 9885, IPC A01P13/00, published 10/30/2007). However, this algaecide acts very slowly. A suspension applied to places where algae accumulate in an amount of 0.20 g/l destroys (by increasing acidity) 90.9% of the filament within two weeks. In addition, phosphogypsum is a fertilizer containing water-soluble phosphates. Therefore, at the end of the two-week period, its stimulating effect on the development of filamentous algae begins to appear.

The closest in technical essence to the proposed solution is a method of combating filamentous algae using a composite environmental agent to suppress the growth of filamentous algae in a reservoir (No. CN 114314858, IPC C02F3/28; C02F3/34; C12N11/10; C12N15/03), publ. . 04/12/2022), which is obtained by mixing inorganic flocculants (aluminum-potassium sulfate, sodium alginate and calcium chloride), sorbent (kaolin) with bacteria that can suppress the growth of algae (denitrifying and phosphate-accumulating bacteria).

Inorganic flocculants (aluminum-potassium sulfate, sodium alginate and calcium chloride), as well as kaolin sorbent, do not have a pronounced algicidal effect, since they are very inert substances. Therefore, their effectiveness against filamentous algae is low. In addition, denitrifying and phosphate-accumulating bacteria will deprive the filament of food - nitrogen and phosphorus compounds. However, the main condition for denitrification is the presence of anaerobic conditions (i.e., the absence of oxygen). The basic principle of biological phosphorus removal is the alternation of anaerobic conditions, with the presence of readily available organic matter (mainly volatile fatty acids) and aerobic conditions without easily accessible organic matter. The creation of such conditions will destroy not only algae, but also the entire ecosystem of the reservoir.

Disclosure of the Invention

The objective of the present invention is to create an effective and environmentally friendly method of combating filamentous algae, aimed at improving the environmental situation in a reservoir.

The technical result is to increase the efficiency and environmental friendliness of cleaning a reservoir from plant formations using long-acting algaecide compositions.

The technical result is achieved by introducing compositions containing various algaecides and/or their chelates into the reservoir to combat filamentous algae. Natural sorbents are used as carriers of algaecides - vermiculite, and/or biotite, and/or muscovite, and/or phlogopite, and/or glauconite, and/or kaolinite, and/or montmorilonite, and/or clinoptilolite, and/or shungite, and/or serpentine.

These mineral sorbents are usually found in the form of fine-grained aggregates consisting of particles about one micron in size. Therefore, they have well-defined properties of ion exchange and sorption, that is, they are able to both absorb from solutions and release various inorganic and organic substances, including algaecides.

The composition is formed taking into account the sorption activity of the sorbent in relation to a specific algaecide and the sorption capacity indicators. The sorbent selected in this way absorbs the maximum amount of algaecide.

When used as part of algaecide compositions, the concentration of active substances in the solution is reduced by an order of magnitude, and therefore becomes environmentally safe for fish and plants. At the same time, the concentration of algaecides on the surface of the sorbent particles increases many times, and they acquire a positive electrical charge. As a result of contact of such particles with negatively charged algae cells, the latter receive a lethal concentration of algaecide and die. The sorbent particles that have sunk to the bottom continue to release algaecides in small quantities, thereby slowing down the growth of algae for a long time. In addition, sorbents absorb soluble phosphates, which also has a suppressive effect on the development of algae.

Carrying out the invention

The selection of active ingredients for the preparation of compositions is carried out taking into account their effectiveness and selectivity of various algaecides, and/or their chelates, as well as their mixtures, in relation to various types of filamentous algae, or communities of different types of filamentous algae. In this case, substances are selected that most effectively destroy algae and are least toxic to fish and plants.

The use of each of the above sorbents takes into account their sorption activity. In this case, the most effective ones against a particular algaecide in pure form or in chelated form are selected.

Sorbents can be used in various combinations and proportions, and the amount of algaecides in the mixture should not exceed the absorption capacity of the sorbents. The amount of algaecides is determined in accordance with the sorption capacity indicators and the coefficients of sorption activity of the sobrents. The sorption activity of the sorbent and its sorption capacity in relation to a specific algaecide are determined experimentally or by any known method.

The selected algaecide or mixture of algaecides and the selected sorbent are thoroughly mixed, with the addition of water, until a homogeneous mass is obtained. Then the prepared composition, in the form of a thick suspension, is introduced into the reservoir in places where algae accumulate. In this case, sorbent particles carrying algaecides slowly settle, stick to the filament and destroy it. With the appropriate selection of algaecides that are most active against a particular type of filamentous algae, a composition is obtained that is effective in combating filamentous algae. On the other hand, when choosing a sorbent depending on its sorption activity, a composition of prolonged action is obtained, which gradually releases the active substance into the reservoir environment.

Some time after applying the algaecide composition, filamentous algae begin to decompose. Therefore, they are removed from the reservoir.

In addition, when selecting the granulometric composition of the sorbents, which determines the hydraulic size of the particles and the rate of their sedimentation, the composition can be used to combat planktonic algae, as well as cyanobacteria.

The prolonged action of the algaecide composition is ensured by the sorbent that settles to the bottom, gradually releasing the algaecide and maintaining its low concentration in the water.

Examples of method implementation.

When developing the claimed invention, experiments were carried out with various algaecide compositions, including natural sorbents.

Example 1. Collected filamentous algae (Cladophora glomerata (L.) Kütz) were placed in two liter crystallizers with settled tap water. Then a mixture of crushed shungite (10.0 g) and organic algaecide monuron (0.1 g) in an amount of 0.2 g/l was added to the experimental vessel. The second vessel was a control (the mixture was not added to it). Then the vessels were exposed at a temperature of 18-20°C and illumination of 2-3 thousand lux with alternating light and dark periods of 12/12 hours. The choice of components and their ratio was selected experimentally, taking into account the sorption activity of crushed shungite in relation to the organic algaecide Monuron.

During the exposure period, the experimental and control vessels were periodically examined. Visual inspection took into account the change in color, the tensile strength of the threads, the degree of mucus and the position of the lump in the water (suspended or bottom), as well as its condition (crowded, sparse, mushy, lysis, etc.). An external sign of algae poisoning - a change in color to pale yellowish - was observed within one hour. Then, within 3 days, the threads settled to the bottom and became slimy, which indicated their destruction by 90%.

Example 2. Collected filamentous algae from the genus Oedogonium were also placed in two liter crystallizers with settled tap water. Then a crushed mixture of muscovite, phlogopite and glauconite (10.0 g) was added to the experimental vessel with the addition of an algaecide of the quinone class - the organotin compound dichlon (2,3-dichloro-1,4-naphtho-quinone 0.1 g) in an amount of 0. 2 g/l. The second vessel was a control (the mixture was not added to it). The ratio of components was selected experimentally. Next, the vessels were placed in the same conditions as described in example 1. An external sign of algae poisoning - a color change to pale yellowish - was observed within a few minutes. Then, over the course of two days, the threads settled to the bottom and became mucus and lysed, which indicated their destruction by 100%. The ratio of components was selected experimentally, taking into account the sorption activity of crushed shungite in relation to the organic algaecide - the organotin compound dichlon.

Example 3. In a decorative pond, as a result of rapid development, algae from the genus Spirogyra covered 80% of the water surface. To combat them, a mixture of crushed vermiculite (0.5 kg) and clinoptilolite (0.5 kg) with the addition of CuC12 (10 g) and triethanolamine (10 g) was used. The ratio of sorbent and algicide in accordance with the indicators of sorption capacity and coefficients of sorption activity was determined using a well-known method for determining sorption activity.

This mixture was poured into a bucket of water (10 l) and mixed thoroughly. Then the resulting suspension was added to the reservoir in an amount of 1 liter per square meter. A sign of algae poisoning - a change in their color to pale yellowish - was observed already in the first seconds after adding the composition. Then, within one hour, the threads settled to the bottom and became slimy. After removing the dead mass, the reservoir was almost completely free of filamentous algae.

Further experiments carried out in various reservoirs showed that careful single treatment usually suppresses the development of filament throughout the season. The need for re-processing arose only in isolated cases. The suppressive effect of the algaecide composition (i.e., the absence of rapid development of filament), after twice application, was observed for up to three years. At the same time, no negative effects on the condition of fish and plants were noted.

Thus, the technical result from the use of the proposed method is to increase the efficiency and environmental friendliness of water purification from filamentous algae due to the effectiveness of the algaecides used in relation to certain types of filamentous algae, as well as reducing their toxicity to fish and plants, through the use of natural sorbents that provide gradual release of algaecides in small doses. In addition, the frequency of treatments is reduced several times, which reduces the cost of purchasing and applying algaecides, as well as the level of toxic effects on the reservoir ecosystem.

The proposed method, with the appropriate selection of individual components (algaecides, their chelates, as well as sorbents and their mixtures), which can be carried out not only using calculations, but also experimentally, can also be applied to the fight against planktonic algae and cyanobacteria.

Claims (1)

A method of combating filamentous algae, characterized in that it includes adding a mixture of crushed shungite in an amount of 10.0 g and an organic algaecide monuron in an amount of 0.1 g to the water for filamentous algae Cladophora glomerata (L.) , or a crushed mixture of muscovite, phlogopite and glauconite in an amount of 10.0 g with the addition of an algaecide of the quinone class - the organotin compound dichloron 2,3-dichloro-1,4-naphtho-quinone in an amount of 0.1 g for filamentous algae of the genus Oedogonium, or a mixture of crushed vermiculite in an amount of 0.5 kg and clinoptilolite in an amount of 0.5 kg with the addition of CuCl ₂ in an amount of 10 g and triethanolamine in an amount of 10 g for filamentous algae of the genus Spirogyra.