RU2552064C1 - Bacterial fertiliser - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: bacterial fertiliser contains a bacterial association including stocks of microorganisms Bacillus mycoides var. B.A. VNIISKhM No. D138 and Azotobacter vinelandii var. NP VNIISKhM No. D24 and composite compound of components, at that association of stocks of the microorganisms Bacillus mycoides var. B.A. VNIISKhM No. D138 and Azotobacter vinelandii var. NP VNIISKhM No. D24 are taken in ratio (1.5-2.5): 0.8-1.4), and in composite compound potassium lingo-humate, microelements in chelate form based on EDTA and/or OEDF, amber and oxalic acids are used. All components are taken at definite ratio.

EFFECT: invention extended scope of application of the fertiliser for wide class of soils and different plant cultures.

9 cl, 3 ex

Description

The invention relates to agriculture and can be used for productive cultivation of various crops and plants, soil restoration and restoration of their fertility, as well as to activate the growth of seedlings in forestry.

Bacterial fertilizers are microbiological inoculants that contribute to improving plant nutrition. When these fertilizers are applied in the soil, biochemical processes are strengthened and the root nutrition of plants is improved, and the composition of soil microflora is normalized.

Known bioadditive to organic fertilizers (RF patent No. 2148571, IPC C05F 11/08, published. 05/10/2000) containing two associations of bacteria taken in the ratio (1-2) :( 0.5-1), the first association containing nitrogen-fixing bacteria Azotobacter chroococcum and Beijerinckia fluminensis taken in the ratio (1 - 0.5) :( 1 - 0.5), and the second association contains bacteria that decompose phosphorus and potassium-containing compounds of Bacillus megaterium and Bacillus mucilaginosus, taken in the ratio (1- 5) :( 0.5-2), a preservative, as well as micro and macro elements.

The disadvantage of this fertilizer is the use of trace elements in the form of mineral compounds, which can adversely change the pH of the soil and does not contribute to their effective absorption by plants, since the penetration of trace elements in this form through plant cell membranes is slow and ineffective.

Bacterial fertilizer is known (RF patent No. 2186049, IPC C05F 11/08, published. 07/27/2002), including a humic containing biohumus base and a bacterial additive having fungicidal activity, and it additionally contains ammonia water or urea, and as a humic containing base - peat in the following ratio of components, parts by weight:

Peat - 100

Biohumus - 10-50

Ammonia water or urea with a total nitrogen content of 2.0-10.0, while the bacterial additive is selected from the groups of spore-forming bacteria: Bacillus subtilis, Bacillus cereus, Bacillus polymyxa with viability in the ammonia medium at pH values of at least 9, in an amount 7.5 · 10 ⁴ -7.5 · 10 ⁸ cells / g of humic base.

The disadvantage of this bacterial fertilizer is the harmful effect on the human health of the component of this fertilizer - ammonia water, which requires special containers and special equipment and strict adherence to temperature and sanitary standards.

The closest analogue to the claimed invention is a preparation for stimulating the growth and protection of plants from diseases (RF patent No. 2302114, IPC A01N 63/00, published. 07/10/2007), including strains of microorganisms Bacillus mycoides var. V.A. VNIISCHM No. D138 and Azotobacter vinelandii var. NP VNIISKHM No. D24, taken in the ratio (1.8-2.2): 1, as well as humates with trace elements in the following composition of components, wt.%:

Bacillus microorganism strains mycoides var. V.A. and Azotobacter vinelandii var. NP 25-30 humates 8-12 trace elements 0.05-0.08 water rest

The disadvantage of the prototype is the lack of effectiveness and limited scope, due to the narrow class of possible soil types and a limited list of agricultural crops.

The aim of the invention is the creation of a new bacterial fertilizer based on bacterial association with strains of microorganisms Bacillus mycoides var. V.A. VNIISCHM No. D138 and Azotobacter vinelandii var. NP VNIISKHM No. D24, which has higher efficiency and expanded scope.

The technical result, which consists in expanding the field of application of fertilizer for a wide class of soils and various plant crops, is achieved in the proposed bacterial fertilizer containing the bacterial association of microorganism strains Bacillus mycoides var. V.A. VNIISCHM No. D138 and Azotobacter vinelandii var. NP VNIISCHM No. D24 and the composite composition of the components, in that the association of microorganism strains Bacillus mycoides var. B.A. VNIISCHM No. D138 and Azotobacter vinelandii var. NP VNIISKHM No. D24 was taken in the ratio (1.5-2.5) :( 0.8-1.4), and the composite composition used potassium lignohumate, trace elements in the form of chelates based on EDTA and / or OEDP, amber and oxal acid in the following ratio of components in wt.%:

the association of the mentioned microorganism strains (0.1-0.15)%;

potassium lignohumate (1.0-1.5)%,

trace elements in the form of chelates (a total of 0.12-0.35)%,

succinic acid (0.1-0.15)%,

oxalic acid (0.1-0.15)%,

water the rest.

The technical result is also achieved by the fact that silicon and / or zinc and / or manganese and / or cobalt and / or nickel and / or molybdenum and / or boron are included in the combination of microelements in the form of chelates.

It was experimentally established that the range of the ratio of the used strains of microorganisms can be expanded in comparison with the range of this ratio in the prototype and is (1.5-2.5) :( 0.8-1.4), which provides a higher population density of the taken microorganisms , thereby creating the necessary conditions for their higher efficiency in the soil.

The influence of the components used in the proposed fertilizer is as follows.

Potassium lingohumate helps to increase productivity, improve the environmental quality of products, reduce the consumption of introduced mineral and organic substances, as well as reduce plant stress during transplantation, and increase soil fertility. Potassium lignohumate is highly soluble in water and combines with other components of the bacterial fertilizer.

The introduction of micronutrients in various combinations is necessary due to the fact that different crops differ in different requirements for individual micronutrients. It is also necessary to take into account the real state of the soil, as a rule, with a depleted complex of trace elements due to the long-term use of soils, which leads to a significant removal of nutrients along with the crop.

Trace elements contribute to the synthesis of enzymes in plants, allowing more efficient use of nutrients from fertilizers and soil.

Moreover, the introduction of microelements in the form of chelates in the proposed bacterial fertilizer contributes to their better absorption by plants (see, for example, http://www.bioinvest.com.ua/index.php? Ltemid = 38 & id = 77 & option = com_content & view = article).

The effectiveness of fertilizers and the degree of digestibility of trace elements by plants depends on the type of chelating agent (ligand) - a substance whose molecule is capable of forming several chemical bonds with one metal ion.

In the proposed fertilizer, organic acids are used as chelating agents: EDTA (ethylenediaminetetraacetic acid) and HEDP (hydroxyethylidene diphosphonic acid), as the most effective.

Chelates are formed on the basis of EDTA, which can be used on soils with a wide pH range, and for each element stable compounds can be formed only at certain pH values (for example, the iron complex with EDTA is effective in controlling chlorosis only on moderately acidic soils). In this case, EDTA exhibits antiviral activity.

Based on HEDP, stable individual metal chelates are formed, as well as compositions with different compositions and ratios. In its structure, it is closest to natural compounds based on polyphosphates (during its decomposition, chemical compounds are formed that are easily absorbed by plants). A distinctive feature of HEDP is its ability to form stable complexes with molybdenum and boron.

The composition of the proposed fertilizer has balanced and experimentally verified concentrations of elements Zn, Mn, Co, Ni, Mo, B, Si in the form of chelates.

The influence of the elements Zn, Mn, Co, Ni, B, Mo in agricultural technology is quite well understood.

As for the presence of silicon (Si) in the composite composition of the proposed fertilizer, then it should be noted specifically.

Silicon and silicon compounds increase plant resistance not only to stresses, but also to other adverse factors: low ambient temperature (frost resistance), diseases, insect pests, magnesium toxicity, ultraviolet radiation, wind, oxygen deficiency, etc. (Savantetal., 1997; Epstein, 1999; Korndorfer et al., 260T7 Ma, Takahachi, 2002).

Monosilicic acid, silicic acid oligomers, low molecular weight polysilicic acids and high molecular weight polysilicic acids are formed in plant tissues and soils, which favorably affects plants. Plants are able to actively absorb monosilicic acid through the root system and leaf plates, and also have a mechanism for the rapid redistribution of silicon to stress-prone zones.

It has been experimentally proven that, with optimal silicon nutrition, the following factors increase: plant germination and DNA resistance of seeds obtained, plant resistance to salt toxicity, lack of water, low temperatures, the presence of heavy metals and other pollutants.

Succinic acid provides an increase in yield, increases the resistance of plants to adverse factors (frost, heat, drought, excessive humidity, etc.), reduces the incidence of plants, increases the content of chlorophyll in the leaves, which allows the plant to grow more intensively and give a higher yield . The use of succinic acid protects against excessive accumulation of nitrogenous substances in plants with their excessive content in the soil.

Oxalic acid heals the soil, suppressing pathogenic bacteria and contributing to the development of beneficial microflora. In the presence of oxalic acid, a powerful root system develops. Oxalic acid does not accumulate in the soil and in plants, preventing the leaching of lime from the soil.

Examples of the use of the proposed bacterial fertilizer

1. Saratov region. Peasant farm "Zelensky".

Bacterial fertilizer was used in growing crops. The yield increase in the experimental plot was 25%. Grain quality improvement was noted (protein content increased by 30%, gluten by 18%) compared with the control section of the field.

2. Krasnodar Territory, Economy IP Gribkova V.E.

Bacterial fertilizer was used in the cultivation of winter wheat and peas.

In the control plot, the yield was 53.5 kg / ha, in the experimental plot - 64.2 kg / ha, i.e. crop increase amounted to 10.7 c / ha.

3. Vladimir region. Fertilizer was tested to promote growth in the cultivation of seedlings of conifers.

Fertilizer was used both when planting seedlings, and during the growing season (1st year of growth) of the grown seedlings by watering the root zone of plants.

Compared with the control plot, the growth of seedlings increased over the year by 12-16%. An increase in the density of coniferous cover by 15-18% was noted.

Thus, the proposed complex bacterial fertilizer provides favorable conditions for stimulating the growth and development of plants, taking into account the influence of many factors due to the specific features of the area, climate, soil, variety and type of plant, and also increases resistance to disease.

Claims (9)

1. Bacterial fertilizer containing a bacterial association, including strains of microorganisms Bacillus mycoides var. V.A. VNIISCHM No. D138 and Azotobacter vinelandii var. NP VNIISCHM No. D24 and the composite composition of the components, characterized in that the association of microorganism strains Bacillus mycoides var. V.A. VNIISCHM No. D138 and Azotobacter vinelandii var. NP VNIISKHM No. D24 was taken in the ratio (1.5-2.5) :( 0.8-1.4), and the composite composition used potassium lignohumate, trace elements in chelate form based on EDTA and / or HEDP, amber and oxal acid in the following ratio of components in wt.%:
the association of the mentioned microorganism strains (0.1-0.15)%;
potassium lignohumate (1.0-1.5)%,
trace elements in chelate form (a total of 0.12-0.35)%,
succinic acid (0.1-0.15)%,
oxalic acid (0.1-0.15)%,
water the rest. 2. The bacterial fertilizer according to claim 1, characterized in that the combination of microelements includes silicon in chelated form. 3. The bacterial fertilizer according to claim 1, characterized in that the combination of trace elements includes zinc in a chelated form. 4. The bacterial fertilizer according to claim 1, characterized in that the combination of trace elements includes iron in chelated form. 5. The bacterial fertilizer according to claim 1, characterized in that the combination of trace elements includes manganese in chelated form. 6. The bacterial fertilizer according to claim 1, characterized in that cobalt in chelated form is included in the combination of microelements. 7. The bacterial fertilizer according to claim 1, characterized in that the combination of trace elements includes nickel in chelated form. 8. The bacterial fertilizer according to claim 1, characterized in that the combination of trace elements includes molybdenum in chelated form. 9. The bacterial fertilizer according to claim 1, characterized in that the combination of trace elements includes boron in a chelate form.