LT5201B - Process and device for reducing biogenes amount and "flowering" in fresh-water - Google Patents

Abstract

The present invention relates to biotechnology and environment protection. The invention claimed is devoted to reduce the amount of biogenes in waters and may be applied to inhibit propagation of algae, i.e., to inhibit so called "flowering" of waters. The process covers planting the biological sorbent in appropriate area of waters. As an area of bearing for biological sorbent the mineral sorbent is immersed and fixed in the superficial layer of waters in a manner to be suitable to plant the biological sorbent at least one vegetation period and to be suitable to displace and fix the mineral sorbent in any other area of waters. After the vegetation of biological sorbent the upper part of mineral sorbent is removed. The process is realised by device comprising a float containing means for placing mineral sorbent and planting biological sorbent in the appropriate area of waters.

Description

The invention relates to the field of biotechnology and environmental protection. It is designed to reduce the amount of biogenic elements in a water body and can be used to inhibit the growth of microalgae - "water blooms".

Of course, when a body of water (pond, lake, river, lagoon) increases nitrogen, phosphorus, potassium, etc. unicellular algae - cyanobacteria, diatomaceous earth, green algae (or phytoplankton) are rapidly growing. Single-cell algae have a short life span of several days. The body of water becomes multidimensional - eutrophic or even supereutrophic, because when algae die, their cellular destruction - mineralization - begins. It is carried out by aerobic bacteria that need a lot of oxygen. These bacteria consume much or almost all of the oxygen dissolved in water. There is a lack of oxygen in fish, zooplankton, v V, benthos (fish food). These organisms kill to a greater or lesser extent. The fish farm is suffering heavy losses. Addressing the causes of this "bloom" is an important issue that has not yet been overcome.

Known methods for reducing the intensity of "water bloom" are chemical preparations - algicides, copper preparations - copper sulphate and various derivatives thereof (Application US 2003/0022793 A1, International Application Publication WO 02/098231 Al), 3- (3indolyl) butter or butanoic acid (EP 1166631 A1, U.S. Pat. No. 6,524,999 B2), pyrimidinocarboxamide compounds (International Application Publication No. WO 03/061387 A1), peroxyhydrate and peroxygenating agents (EP 1256278 A1, US 2003/0110689).

The disadvantage of known solutions is that microalgae adapt to, and become resistant to, these compounds, and aquatic animals such as zooplankton, benthos and fish are far more sensitive to these compounds than microalgae. Higher concentrations of these chemicals are poisonous to animals and kill. Deposits of these substances are sorbed by the soil, increasing the concentration of these chemicals and killing benthic organisms. In addition, these chemicals are expensive. Their use, as mentioned, is not only ecologically viable but also economically viable.

A known method for reducing the growth of microalgae by inhibiting their photosynthesis process (EP 0320084 A1) is by adding the fluorescein dye (C20H10O5) to water. Fluorescein absorbs the light required for photosynthesis and supposedly reduces the growth rate of microalgae.

The disadvantage of this method is that it is ineffective for several reasons. The microalgae that cause "water blooms" belong to the cyanobacteria (Cyanophyta). These algae provide the main nutritional component - carbon C - not only during photosynthesis, but also in the form of CO ₂ . They are mycotrophs - the representatives of a mixed diet. These algae, like bacteria, take carbon from the soluble organic compounds present in the water of the body. Fluorescein Triphenylmethane organic dye has fluorescence properties. Not only does it absorb that part of the electromagnetic spectrum - solar radiation - which we call visible light - required for photosynthesis of microalgae, it also glows, emitting wavelengths of 380 to 750 nanometers. Violet, blue and red light are included in this electromagnetic spectrum. Microalgae pigments - chlorophyll a and chlorophyll b, as well as orange-colored carotenoids absorb light at these wavelengths and undergo photosynthetic reactions. Fluorescein is poorly water soluble. Its particles settle and clog the filtering apparatus of the aquatic inhabitants, causing them to die. Due to the above disadvantages, fluorescein is not used for these purposes.

It is also known when artificially bred breeding Pseudomonas aeruginosa, Ps., Is introduced into the water body to reduce microalgae development. stutzeri, Ps. putida bacteria and products of their metabolism (U.S. Pat. No. 4,872,986) or micromycetes of the genus Saccharomyces (U.S. Pat. No. 6,391,619).

The disadvantage of these solutions is that although all of these specified microorganisms reside in all water bodies, they cannot be used to inhibit microalgae growth due to the component composition of the aquatic ecosystem. This system consists of producers - microalgae and macrophytes, consortiums - zooplankton, benthos, fish and reducing agents - microorganisms (bacteria, micromycetes). The water mass also contains various organic matter in a soluble and suspended state. These include lipids, pigments, proteins and their degradation products, carbohydrates, hydrocarbons and other compounds. Normally, the weight ratio of aquatic organisms to organic matter (dissolved and suspended) is 1: 5 to 1:11. Microalgae predominate in the aquatic medium. Normally, their biomass is 1.0 - 5.0 mg / l, in eutrophic water bodies - about 50 - 60 mg / l, in hypertrophic - microalgae biomass reaches 70 - 80 mg / l and more, sometimes even higher than 200 mg / l. . The biomass of the main components, zooplankton, is 10 times lower than that of microalgae, while the biomass of the reducing agent, bacterioplankton, is only 50% of the zooplankton biomass. Only bacterioplankton - microorganisms multiply extremely rapidly. Their generation time (the time it takes for the bacterioplankton biomass to double) reaches a few minutes or even a few minutes under favorable conditions.

Cyanobacteria (now called cyanobacteria), which form colonies, predominate during the "flowering of water". Some, such as Aphanizomenon flos aquae, form a needle-like structure. Zooplankton is unable to absorb these microalgae. It feeds on bacteria and micromycetes, including Pseudomonas and Saccharomyces microorganisms. Thus, the artificial use of these microorganisms to reduce "water blooms" is not viable. All the more so as this instrument would be extremely expensive.

The closest proposed technical point of view and the results obtained are the solution of Thomas A. DeBusk and David L. Haselow in US 2002/0023876 A1 and its further development in US 2003/0116502 Al. According to this solution, water biogenic elements, in particular nitrogen and phosphorus compounds required for microalgal nutrition, are sorbed by macrophytes floating on the surface of the water. Water hyacinths (Eichhornia crassipes) and duckweed (Lemna spp.) Are used as macrophytes. They are placed on a special buoy. The coating around it traps the light needed for photosynthesis of microalgae. The device, in the form of a column, reaches the bottom of the body of water. Pumps are used to remove and purify purified water from the column.

The disadvantage of this solution is that the aforementioned method and device are complex in design and operation, and the plants used have a poorly developed root system. Watermelons are small plants, several millimeters in diameter, which are submerged under water or floating on the surface of the water. These plants are mostly unicellular. Their root is a few millimeters long and their surface area is small and their ability to absorb water's biogenic elements is small. Water hyacinth, a much larger perennial herbaceous plant, up to 50 mm in height, compared to watercress. It dies when the water temperature drops to 1 ° C. Due to its size and physiological properties, it is unsuitable for reducing the nutritional value of water bodies.

The purpose of the invention is to increase the collection (absorption and adsorption) of biogenic substances in water bodies, to reduce the eutrophication processes of these water bodies and to eliminate the "water bloom" phenomena caused by microalgae.

The essence of the solution is to reduce the amount of biogens and "water bloom" in freshwater bodies in a method that involves the introduction and cultivation of a biological sorbent at a selected site, new by immersing and fixing the biological sorbent at a selected site in its surface layer. as a support substrate for mineral sorbent suitable for introduction and cultivation of biological sorbent for at least one vegetation period, fixes the mineral sorbent in the field with the ability to move and fix it anywhere else in the field and upon completion of vegetation of biological sorbent applied on said mineral sorbent, removes the upper part of it.

The proposed method for reducing the amount of biogens and "water blooms" in freshwater bodies is good because it fixes the mineral sorbent used as a support substrate for biological sorbent breeding and cultivation at any selected location in the freshwater body in the surface water layer with the ability to move and fix it site and can be used to clean eutrophic water bodies of various sizes (fishponds, reservoirs, lakes).

It uses the rhizome and root of the calyx (Acorus calamus) as a biological sorbent.

Aries placed in a water body improve its water quality and perform water protection functions in case of anthropogenic eutrophication. Balinese is an extremely valuable perennial plant. It is large, up to 1 m high. Rhizome thick, up to 30 mm in diameter. Long overhead roots grow out of it. The rhizome with roots has well-expressed sorption properties of biogenic elements. Its biomass (especially rhizomes) is rich in essential oils (more than 5%). It is used in soap, perfumery industry, soft drinks industry. It is used to flavor various food products. In addition, balsa ajer is a medicinal plant. Used to treat various human and animal diseases.

The mineral sorbent uses a mixture of aluminosilicate zeolite and penoplast in which the volume ratio of aluminosilicate zeolite to penoplast is approximately 3: 1 with a zeolite fraction size of at least 10 mm.

Zeolite is a crystalline aluminosilicate. Its main active components are clinoptilolite and montmorillonite. Ecologically clean, inert, non-toxic material. Good sorbability of macro- and micro-nutrients.

To reduce the amount of biogens and "water bloom" in freshwater bodies, the unit includes a raft device having means for introducing and cultivating a biological sorbent at the selected site, new is that the unit has at least one container for depositing and fixing the mineral sorbent in the surface water. to accommodate the introduction and cultivation of the biological sorbent, said container has means for attaching the mineral and biological sorbent, and the raft device is adapted to fix it at the desired location in the body.

The proposed device is good in that the raft device can contain mineral sorbent and biological sorbent, and the device prepared for the above method can be fixed not only at any location of choice for the freshwater body, but also at the required depth in the surface water can be captured anywhere in the body of water so it can be used to clean eutrophic water bodies of all sizes.

The mineral sorbent used to reduce the amount of biogens and "water bloom" in freshwater bodies is embedded in a porous synthetic fabric, giving the said structure a spatially geometric shape suitable for planting and cultivating a biological sorbent.

The log-shaped mineral sorbent structure is convenient to place and fix in a raft unit, and to fix and grow baler aero rhizomes on a fixed distance from each other.

The container for depositing the mineral sorbent is made of a rigid thin-mesh mesh and has a shape similar to that of a formed mineral sorbent and is suitable for containing and fixing said mineral and biological sorbents.

The open top of such rigid thin-mesh ducts allows for the convenient placement of sorbent zeolite mixed with lumps of foam and synthetic porous tissue into a log-like structure and baler-aster rhizomes attached thereto. The mesh does not interfere with the contact of the aero rhizomes and roots with water and the surface of the zeolite · sorbent duck, maintains them in the water surface and allows unhindered intensive use of water-soluble mineral compounds (N, P, K, Ca, Na, Si, Mo, Cu, Zn et al.) And to grow rapidly the rhizomes, roots and leaves of said plant. The raft device of said device has at least two spaced apart and interconnected longitudinal raft members, including at least one container for placing a synthetic sorbent between adjacent raft members, which is attached to the raft members so as to immerse the mineral sorbent in the surface water of the body. layer enough to apply and grow a biological sorbent on it.

The device used to implement the method for reducing the amount of biogens and "water bloom" in freshwater bodies is schematically illustrated in a drawing in which longitudinal parallel raft members 1 are reinforced with elements perpendicular to them 2 and channeled rigid thin wire mesh 3 is inserted between and attaching mineral sorbent structures 4, on which the biological sorbent blanks are positioned and fixed 5. The anchor 7 held by a synthetic rope 6, which is lowered into the ground, fixes the location of the buoyancy unit at a fixed location (aquatorium) of the water body.

A simple structure buoy - a raft - is installed to grow aquatic plants and deposit sorbent zeolite. It consists of longitudinal parallel elements 1, which can be 13 boards 15 cm wide, 2 - 3 cm thick, 2.0 - 2.5 m long. The distance between the boards - not less than 35 cm. The boards are joined at 3 locations (ends and middle) by transverse fasteners 2, which may also be boards, and are perpendicular to the longitudinal members of the raft. A thin-mesh wire mesh 3 is fastened along the boards between the boards so as to form a channel with the top open and the sides height and bottom width 35 cm. The mesh size shall be at least 2x2 cm. A sorbent zeolite is mixed into the canal and mixed with a 3: 1 volume of foam plastic. The size of the zeolite fraction is at least 10 mm. The mixture of zeolite and penoplast is encapsulated in a synthetic porous fabric with a mesh size of not more than 10 mm and a log-like structure 4 with a diameter of 20 cm is formed corresponding to the length of the raft. It is fitted with a synthetic ribbon of rhizome 5, approximately 30 cm long and a distance of 15-20 cm between the rhizomes. An anchor 7 is attached to the corners of the raft by synthetic ropes 6, which is lowered to the ground during exposure.

The design of the unit, where the longitudinal members of the raft and the cross members supporting them, are wooden boards or plastic hoses with closed ends or polyethylene pipes with closed ends, allow the biological and mineral sorbents sorbing biogens to be maintained at 5 to 35 cm depth, that is, where photosynthesis of microalgae and "flowering of water" are most intensive. In the water body, rafts are placed at the beginning of the vegetation period in areas most contaminated with biogenic elements and where "water blooms" are expected. During the vegetation period, the raft can be repositioned as needed, and at the end of the vegetation period, the upper part of the balaclava above water is removed and disposed of. It can be removed from the ice when the water is frozen.

The groove-like elements used between the raft's longitudinal members are formed of fine-mesh wire mesh with a mesh size of at least 2x2 cm, the height of the side walls being greater than the thickness of the raft members, the bottom width not exceeding the distance between two adjacent longitudinal raft members. preferably the mesh wall height and bottom width are not more than 35 cm and the length does not exceed the length of the longitudinal members of the raft.

There are several options for raft production. Their construction depends on the type of water body, its size, the material used for the production of the raft, the technology of raft production, the mechanization of work and similar possibilities. The raft is made of polyethylene hollow tubes of various diameters, which form floats of various capacities at their ends.

Mallard (Acorus calamus)

Morphological features. Plant 60-100 cm tall. The stem is curved on one side and curved on the other. The foot of the inflorescence at the site of the inflorescence forms a continuation of the stem. Leaves stalkless, long, swordlike, hugging each other mainly in the lower parts. Their fringes are often wavy. The flowers are small, twin, clustered in green cobs. Their petals are also green, similar to leaves. The cob is cylindrical, tilted to the side 4.5 to 9.5 cm long. It blooms in June and July. Rhizomes greenish-pink, thick, 15-30 mm in diameter, creeping, articulated, branched, with pronounced fallen leaves, with long overlying roots, white-gray in cross section, slightly porous.

Physiological - biochemical properties. The most important product produced by the plant is essential oils. Their content in the plant biomass is 4.3 - 4.5% and more. Essential oils contain terpenoids: a - pinene, camphene, calameon, camphor, a - calamene, β-calamene, calamone, acoroxide, acorone, isoacarone, calamenol, calamenenol, calamenene, calorene, calarene, selinene, caryophyllene, humulene, myrcene. Essential oils contain aromatic compounds: azarone, eugenol, parazarone. Also acids: vinegar, palmitine, n - heptane. Sesquiterpenoids were found: acolamone, acoragermacron, isoacolamone, shiobunone, episiobunone, isosiobunone. The rhizome contains 0.2% maltose,

20.7% glucose, fructose.

Applied Value. Rhizomes are used in scientific medicine for digestive disorders, to stimulate the excretion of bile in order to improve appetite against nerve diseases, hair loss, and aromatic baths that strengthen the body. The rhizome is rich in essential oils, which is why they are used in perfumery, in the production of liqueurs and as a spice. Official ayuric raw material is included in many pharmacopoeias of the world - a set of standards and regulations for the preservation and dosing of medicines.

Arable cultivation of Ayer. Not rare in our country. Common in itself. In the Nemunas Delta, in the floodplain, stony valleys of the Ignalina and Zarasai districts, it grows in dense shoals and occupies considerable areas. We can find small shoals on the edges of pond lakes in unpolluted rivers, in swampy areas. Ballerina - a gaious plant. Widely spread. It is found in Central Europe, Scandinavia, Balkan Peninsula, Russian part of Russia, Siberia, Caucasus, Far East, Asia Minor, China, Japan, India, North America. Considered an asiatic element of the flora.

Experiments have shown that the aisle is characterized by high cumulative sorption of mineral elements important for the vital activity of all aquatic organisms. Aeri has a high coefficient of accumulation (CC) of these biogenic elements. By this coefficient is understood the plant's ability to accumulate mineral compounds. It is expressed as the ratio of the amount of mineral or otherwise ash elements in the dry weight of the plant to the amount of those elements in the water. Ajer accumulates about 6.45% to 11.30% of its phytomass and about 10% of ash elements in rhizomes. This strong aberration sorption property, as well as its ability to produce highly valuable chemicals, opens up opportunities for the use of ayere to regulate the nutritional status of multidimensional - eutrophic and hyperereutrophic bodies of water. Biogenic elements are abundant in multidimensional water bodies. Microalgae develop rapidly in July - August and September - October. They cause "water blooms". This results in the disruption of the water's gaseous regime (vigorous destruction of organic matter below the critical limit reduces the soluble oxygen content in the water), deteriorates water quality, kills fish and their food source, zooplankton and zoobenthos.

In order to protect water bodies from surface runoff (cultivated and fertilized land), it is advisable to use Aryan plantations as a biological filter for artificial insertion in coastal areas.

Aers are used for regulating the quality of water discharged by fish farming ponds into open water bodies and for other similar purposes.

Tests have shown that the ball aisle is suitable for use not only in the waterfront but also in the water body itself. Ajer is buoyant due to its aerenchyma in the phytomass. The rafters formed by rafts, by intense sorption of nutrients in the field, suppress the growth of microalgae - the "flowering of water".

Ajer is propagated exclusively by vegetative means, rhizomes. Seeds do not mature in our climate. Aster's rhizome grows in a monopodic fashion, with its inflorescence-bearing stem emerging from its apical bud. It is surrounded by leaves at the base. The following year, in spring, the rhizome begins to grow again, but from the side buds - in a sympathetic manner.

Planting Ayer is simple. Planting material - rhizomes. They are 30 - 35 cm long and 20 - 30 mm thick. The source of the rhizomes is the existing Aryan shoal. Acres grow best on the shores of water bodies where the water reaches 0.3 - 0.5 m. In aquariums we have found that this depth is optimal for germination of the aero rhizome. Due to their light weight, the Aryan rhizomes protrude to the water surface. The rhizomes must be attached to the soil. Rootstocks are best planted in May. in the mid to last decade when the water warms up. They release long dense roots, which take root in the soil and intensively absorb nutrients. The rhizomes are planted - fixed to the soil at a distance of 25 - 35 cm. The distance between rows - 35 - 45 cm. Annual growth of rhizomes up to 25 cm and more. Leaf length about 100 cm. Their width - 10 - 20 mm.

Aries in open water are bred using rafts of various designs and configurations. Rafts are made on shore. Flush into water. The anchor is fixed to the ground. Ayer rhizomes, placed in a raft metal zeolite-free canal, and more preferably on a 3: 1 mixture of zeolite and penoplast, placed in synthetic porous tissue, release their roots and shoots in contact with multidimensional (eutrophic) water. Ares, which develop on a float placed in the water, intensively absorb soluble nutrients from their roots. Nitrogen (N), phosphorus (P), calcium (Ca), sodium (Na), magnesium (Mg), silicon (Si), molybdenum (Mo), copper (Cu) are sorbed from water. By its functional activity, Ajer inhibits the growth of microalgae and normalizes the state of the freshwater ecosystem. Aries placed in a water body improve the water quality of that water body and perform water protection functions in case of anthropogenic eutrophication.

In Lithuania, ayer rhizome grows a few centimeters a year depending on the substrate. The rhizomes contain 1.5 - 5.4% of essential oil in our conditions. It contains 1% d-pinene, 7% d-strain, 8.7% d-camphor, 3% bomeol, eugenol, azarone, calamole, calamene, caloracene, caryophyllene, guaene, acorone, 29 mg% ascorbic acid, tanning substances .

Zeolite

Chemical composition of zeolite. Mineral. Aluminum silicate. High temperature resistant. Ecologically clean, inert, non-toxic material. It (%): S102 - 71.5; Al 2 O 3 - 13.1; Fe 2 O 3 - 0.9; CaO-2.1; MgO - 1.07; K 2 O + Na 2 O - 5.03; small amounts of other elements (T1O2, P2O5, F, As, Pb, Cu). Trace elements in it (mg / kg): Mn - 242; Zn = 45; Y = 22; Nb = 22; Ba 232; Th-12.

Physical properties. Porosity 34% (open zeolite interconnected voids, channel diameter 2.8 - 8.0 angstroms). Density - 270 kg / dcm ³ . Conditional surface - 0.4130 n

m / y. Ion exchange sensitivity is 1.5 mgeq / g. Adsorbent and absorbent. Absorbs mineral compounds and some organic compounds of appropriate size. Zeolite is suitable as a sorbent and support substrate for ridge growth in open water rafts.

The effectiveness of the raft, bio-sorbent-baller aerre and mineral sorbent used to reduce the amount of biogens and "water bloom" in freshwater is confirmed by the following test examples.

an example is the cultivation of a baller aster in an oligotrophic pond. On a specially prepared raft (shown in the drawing) were placed the spears of aisles. The volume of their underwater portion (rhizomes with roots) was estimated as follows. Water was poured into the first tank as far as its edge. This container was placed in the second larger container. When we put the underwater part of the aiser orb - the rhizome with the roots - into the first tank, the water pressed from this biomass drained into the second tank. The measured (cm ^{2 3} ) pressurized water equals the volume of biomass (ayere underwater). This data is needed for the quantification of biomass. A raft with aster spears was lowered into a pond. Pond water of oligotrophic type - small food. It is low in biogenic nutrients. The water is clear, translucent to the bottom - 150 - 180 cm. Well saturated with oxygen. Water temperature is low. Planktonic organisms and microalgae are low. Their reproduction is not intense.

There are 12 foliage with leaves in the raft. The weight of the kerosene after washing the soil ranged from 2080 to 8300 grams. Average - 4328g. Volume average of Aero kero rhizomes with roots, ml - 3545.

The exposure time of the acres in the pond is from 10.07.2003 to 25.09.2003, which is 77 days. During this time, the moose kept well in shallow water. It was found that during the vegetation period (July), the whole plant with roots, rhizomes and leaves was not transferred to the conditions of small-sized, fresh water, without soil, during the vegetation period (July). This indicates the high degree of viability of this plant.

an example is the cultivation of baller ais in eutrophic (multi-dimensional) water.

Eutrophic water and the water body of that nutritional type are rich in biogenic elements. They are rich in flora and fauna. Cyanobacteria (Cyanophyta) and the following species complexes are predominant: Aphanizomenon flos - auauae, Microcystis aeruginosa, Anabaena flos - auauae, Oscillatoria, Stephanodiscus hantzschii, Aulacosira granulata, Pandorina morum, Coelastrum microporum. In eutrophic waters, the maximum development of microalgae occurs in July - August and September - October. The long-lasting "flowering of water" is usually caused by the fast-growing species of Aphanizomenon flos-aąuae and Oscillatoria.

In eutrophic waters, the maximum biomass of microalgae is more than 50 g / m ³ and the content of chlorophyll a is 45 mg / m ³ . In hypertrophins, biomass reaches several hundred g / m ³ and chlorophyll a content even 200 - 400 mg / m ³ .

Eutrophied water was modeled under experimental conditions in order to evaluate the ability of the balloon aster to adsorb biogenic elements and thereby reduce the intensity of microalgae development - their resulting "water bloom". It was achieved this way. A nutrient culture medium for microalgae is produced. Oligotrophic pond and tap water were used for this purpose. It is enriched (fertilized) with the following mineral compounds (g / 1):

NH4NO3 0.2 CaCl ₂ 0.1 K ₂ HPO ₄ 0.1 MgSO ₄ 0.1 FeCl ₃ Traces (1 drop of 1% solution)

This medium is used to fill 3 aquariums. Used after 30 l media / aquarium. The simulation scheme was as follows: pond water (enriched with mineral compounds), without aers; Trial 1 - Same as the control, except with the aers; Pilot 2 - Same as Option 1 with only 50% reduced fertilization. Cara weight (g) and volume of rhizomes with rootstocks of Variants 1 and 1543 respectively: 1544 and 1173. Variants of Variants (g) and Volume of rootstocks with rootstocks (ml) of variant 2: 1720 and 1255 respectively. The ares were placed in a surface (10 cm) water layer. Test duration: 15/07/2003 - 24/09/2003.

All test variants were fertilized with compounds of the specified composition on July 16 and July 25, August 11 and August 28 and September 12. In Trial 2, the amount of fertilizer was reduced by 2 times to 50% of the Trend 1 fertilizer.

The temperature of the test water was monitored. July 3 was characterized by high air temperatures. It was the same in the aquarium, the test water temperature was 30 ° C. Such high water temperatures are not conducive to ayur growth. It normalized to 25 ° C in the 2nd decade of August and around 20 ° C in the 3rd decade of this month. By the end of the test (September 2), the temperature of the test water had dropped to 16 ° C.

Water levels in aquariums were the same throughout the test period. The dripping water was supplemented with tap water. Already at the end of the 1st decade of August, differences in test variants became apparent. In the control (without ayer), the intensely proliferating microalgae colored all the water in green. In the test variants (with aers) the water was clear. Despite the high water temperature (when the water temperature is high, gas circulation in the water is impaired, oxygen is less soluble in it and it is more difficult for the roots of the plant to grow), new plants have been allowed to open.

At the end of the experiment (after 71 days), the concentration of microalgae reached its maximum in the control. This is illustrated by the chlorophyll a content indicator. Reached 1200 mg / m ³ . Significantly exceeded the values of this pigment in the hypertrophic water body (up to 250 mg / m ³ ). In the test variants, only traces of microalgae are observed in the aquariums (usually some of them are attached to the inner walls of the aquarium). Aquarium water is clear.

Ayer rhizomes with roots have been found to have high mineral sorption capacity. By intensively storing biogenic elements, Ajer overshadows the development of microalgae and eliminates the risk of "water blooms". The dry phytomass of Balter Ayer contains the following essential nutrients: carbon (C) - 45%, oxygen (O2) - about 40%, hydrogen (H) - up to 5%, nitrogen (N) - about 1%, ash - mineral elements - up to 10%. The test reaffirmed the extraordinary vitality of the aero The aisles used for the experiment were raised from their natural habitat during intensive vegetation, moved to abnormal water temperature conditions (pond, spring water, water temperature reached only 13-17 ° C at the end of August). .

an example is vegetative propagation of ayer and its cultivation in various aquifers.

Three aquariums with a capacity of 35-40 liters were used for the test. Make up to 30 liters with the following solution (g / l): NH4NO3 - 0,2; CaCl3 - 0.1; K 2 HPO 4 - 0.1; MgSO ₄ - 0.1; FeCE - Traces (1 drop of 1% solution). The aquariums contain 3 rhizomes of each aero 25-30 cm long. Aquarium 1 - in the buoyancy state (on the water surface), 2 - in the depth of 20 - 25 cm (mounted on a glass cylinder to avoid floating on the water surface), 3 - in the depth of 35 - 45 cm (rhizomes at this depth) are also anchored).

The test water is fertilized every 15 days with the specified fertilizer composition. Flushed water is supplemented with tap water. The duration of the test is 70 days. In all test variants, roots and leaves grew from rhizomes. The most intensive root and leaf growth occurs when the rhizomes are placed in a 20 - 25 cm water layer.

It has been found that in the artificial cultivation of balsa aera they need to be propagated by rhizomes 25-30 cm long, not by root and leafy seedlings. The rhizomes can be placed in various water layers, not exceeding 40 - 50 cm, but it is better to place them in the water depth of 20 - 25 cm.

This treatment method is advantageous for cleaning eutrophic water bodies of various sizes (fishponds, water reservoirs, lakes).

Arachnid cultivated in a body of water is seen as an environmental tool for improving water quality and as a (economically) very valuable crop (with a huge range of chemical compounds of practical value). This crop does not require expensive fertilizers (they are in the body of water), it does not require chemical maintenance (pesticides, etc.), it also uses high-value (under leaves) and underwater (rhizomes) parts of high value (the value of cereals is far from equal for the value of aero rhizomes).

After 3 - 4 years, up to 30% of the shrubbery is removed from the water every year in spring or autumn, the roots and leaves are cut, and the dried rhizomes are used in the production of essential oils, soap, perfumery, food, medical and veterinary.

Claims (9)

DEFINITION OF INVENTION 1. A method of reducing the amount of biogens and "flowering of water" in freshwater bodies, comprising the introduction and cultivation of a biological sorbent at a selected site, characterized by immersing and fixing a mineral sorbent in the surface water of the body as a support substrate for the biological sorbent. for the purpose of introducing and growing a biological sorbent on it for at least one growing season, the mineral sorbent in the body is fixed with the ability to be moved and fixed anywhere else in the body and removed after the vegetation of the biological sorbent on said mineral sorbent. 2. A method according to claim 1, wherein the biological sorbent is a rhizome of Acorus calamus and their roots. 3. A process according to claim 1 wherein the mineral sorbent is a mixture of aluminosilicate zeolite and penoplast. 4. A process according to claim 3 wherein the volume ratio of the aluminosilicate zeolite to penoplast components in the mixture is about 3: 1, wherein the zeolite fraction has a size of at least 10 mm. 5. A device comprising a raft device for introducing and cultivating a biological sorbent at a selected location in the body, characterized in that the raft device has at least one container for depositing and fixing a mineral sorbent in the surface water of the water to reduce the amount of biogens and "water bloom". so as to be suitable for the introduction and cultivation of a biological sorbent, said receptacle has means for attaching the mineral and biological sorbent, and the raft device is adapted to fix it at a desired location in the body. 6. Apparatus according to claim 5, characterized in that the mineral sorbent according to claims 3 and 4 is embedded in a porous synthetic fabric giving said structure a spatially geometric shape suitable for introduction and cultivation of a biological sorbent. 7. A device according to claim 6, wherein the mineral sorbent derivative is in the form of a log. 8. Apparatus according to claim 5, wherein the receptacle for depositing the mineral sorbent is made of a rigid thin-mesh web having a shape similar to that of a formed mineral sorbent and suitable for containing and fixing said mineral and biological sorbents. 9. A device according to claim 5, wherein the raft device has at least two spaced apart and mutually reinforced longitudinal raft members, including at least one container for placing a synthetic sorbent between adjacent raft members, which is fixed to the raft members. the mineral sorbent is submerged in the surface water of the body of water to the extent that it is suitable for the introduction and cultivation of a biological sorbent.