RU2815050C1 - Method of producing biologically active biohumus - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to agriculture and can be used in processing various organic wastes, including manure and droppings, into high-quality biologically active organic fertilizer. Method of producing biologically active biohumus involves fermentation of organic wastes and vermicomposting of the fermented product. Fermentation is carried out by introducing saprophytic bacteria under aerobic conditions at temperature not higher than 50 °C. After passing through the thermophilic phase, liquid nettle wash prepared with addition of liquid biohumus in an anaerobic medium is added to the prepared substrate. After 72 hours, the ready substrate is subjected to vermicomposting with earthworms to obtain biologically active biohumus.

EFFECT: improved quality of the ready product with simultaneous more accelerated growth of the worm population.

4 cl, 1 tbl

Description

The invention relates to agriculture and can be used in the processing of various organic wastes, including manure and droppings, into high-quality biologically active organic fertilizer.

There is a known method for the production of vermicompost, including preliminary mixing and biothermal composting of a substrate, including organic cultivators, colonization of moistened compost with red Californian worms of the species Esenia foetida for processing the compost and separation of worms from moistened to 60-65% vermicompost. As a substrate, a mixture of non-production waste from slaughter animals is used, for example technical slaughterhouse blood, bones, skins, the contents of the proventriculus of the gastrointestinal tract, for example cane, with organic leavening agents, for example sawdust, paper and residual brewer's or baker's yeast. Biothermal composting is carried out in an open boiler by three-stage hydrolysis, the first stage of which is carried out by stirring the mixture at a temperature of 40°C for 2-3 hours, boiling at a temperature of 120°C for 2-3 hours and cooling the mixture to a temperature of 40°C. The second stage is carried out by stirring the resulting mixture at a temperature of 40°C for 2-3 hours with the addition of an equal volume of unused brewer's or baker's yeast and organic leavening agents, an aqueous-alcoholic extract of enzymes from the pancreas of slaughtered animals, such as pigs, is added, and/or alkaline protease Bas.subtilis in a ratio of 1:100 or 1:500 with further stirring of the mixture for 2-3 hours at a temperature of 40°C. The third stage is carried out by sterilizing the resulting mixture for 2-3 hours at a temperature of 120°C, sifting and further evaporation to a residual moisture content of 40-60%. The resulting compost is populated with red Californian worms at a rate of 10-15 pcs. mature worms per 10 kg of processed compost in a separate container, the bottom of which is covered with a bedding of sawdust and sand in a 1:1 ratio, followed by exposure for 2-3 months until vermicompost is formed with a stable pH value of 6.0-8.0 . Separation of worms from moistened vermicompost is carried out by using bait in the form of a mixture of paper dust, finely ground sawdust, urea and starch paste, and the resulting vermicompost is dried to a moisture content of 5-15% and used for its intended purpose [patent RU 2274628, publ. 04/20/2006]. The disadvantage of this method is the complexity of this production.

There is a known method and device for processing composted material, described in patent EP 1094048, C 05 F 17/00, published in 2001, in which the final processing of freshly prepared compost is accelerated by vermicomposting, and the population of earthworms constantly migrates in the substrate following fresh food The process is continuous, since the substrate with worms is on a moving base, which has an annular, oval or linear shape. Recycled vermicompost is removed at the end of the cycle, and fresh compost is fed continuously into the original area where the worm population is located. In this method, compost processing occurs continuously in automatic mode. Control of the migration of worm biomass is carried out using sensors. The disadvantage of this method is the complexity and high cost of this production.

There is a known method for producing vermicompost, characterized in that the substrate from buckwheat seed husks is moistened, infested with worms and composted. When preparing the substrate, the components of organic raw materials are mixed until homogeneous, moistened, then the prepared substrate is placed in a container in which it is kept for 15-20 days. The mature substrate is colonized with worms and moistened to 70%, composting is carried out for 4-4.5 months. Pork manure is additionally added to the buckwheat seed husk substrate in a 1:1 ratio [patent RU 2363689, publ. August 10, 2009].

The disadvantage of the known solution is the limited availability of raw materials (buckwheat seed husks) for producing vermicompost on an industrial scale due to their high ratio in the substrate.

There is a known method for processing organic waste into compost (EP4177237, published 05/10/2023). The method includes fermenting organic waste, including adding at least one or more lactic acid bacteria to the organic waste, the step being carried out under anaerobic conditions and at an acidic pH, resulting in fermented organic material; maturation of fermented organic material under aerobic conditions; vermicomposting of mature organic material.

The disadvantage of the known solution is the lower quality of the resulting organic fertilizer.

The technical objective of the invention is to develop a method for recycling organic waste into a highly effective, biologically active, environmentally friendly microbiological humus fertilizer of increased efficiency and earthworm biomass.

The technical result of the invention is to improve the quality of the finished product with a simultaneous positive effect on the worm population.

The technical result is achieved by the fact that the method for producing biologically active vermicompost includes fermentation of organic waste and vermicomposting of the fermented product, while fermentation is carried out by introducing saprophytic bacteria under aerobic conditions at a temperature not exceeding 50°C, after passing the thermophilic phase, liquid nettle mash is added to the prepared substrate, pre-prepared with the addition of liquid vermicompost in an anaerobic environment, after 72 hours the finished substrate is subjected to vermicomposting with earthworms to obtain biologically active vermicompost.

The proposed method for producing vermicompost is used for processing organic waste, such as horse, goat, cattle manure, etc.

The method is carried out as follows.

Organic waste is pre-composted by periodic loosening with the addition of aerobic bacteria obtained by aerating liquid vermicompost (the so-called aerated vermicelli). After passing through the thermophilic phase of composting at a temperature not exceeding 50 ° C, nettle mash, previously prepared in an anaerobic environment with the addition of liquid vermicompost, is added to the compost ready for the worm. After 72 hours or more, the resulting finished substrate is colonized with a worm in order to subsequently obtain biologically active vermicompost.

The difference between this method of obtaining vermicompost and others is a special approach to obtaining the substrate. Before colonization by the worm, the substrate is oversaturated with aerobic and anaerobic soil-forming microorganisms, which are obtained in advance from liquid vermicompost, mushrooms, as well as useful micro- and macroelements, vitamins (PP, A, C, E, K, B2, B6), organic acids, etc. ., contained in nettle mash, which, in turn, have an extremely positive effect on both the worm population and the quality of the final product.

At the same time, the resulting biologically active vermicompost has a low cost, since agricultural waste and nettle are used as raw materials, the production of which in large volumes is an easily feasible task.

Example of implementation of the invention

Vermicea is pre-prepared from liquid vermicompost. To obtain it, water is used that is pre-purified through a reverse osmosis system. Liquid vermicompost is obtained from ordinary pure high-quality vermicompost and clean water in a 1:1 ratio by volume using a homogenizer (RPA). 10% liquid vermicompost and 2-3% beet molasses by volume are added to purified water. Next, using a fine-bubble bottom aerator, the resulting composition is aerated for 24 hours at a temperature not lower than 15 °C.

Prepared vermi tea contains a nutrient medium, including humic acids, fulvic acids, amino acids, vitamins, micro- and macroelements, hormones, as well as spores of soil saprophytic bacteria.

Organic waste is loaded into a container or piles are formed and the previously obtained vermicelli is introduced in the amount necessary to moisten the substrate to a humidity of 50-60%, necessary to begin the exothermic process of biological oxidation (composting). The introduction of vermicha allows you to obtain higher quality (saturated with beneficial microbiota) compost at this stage.

To saturate the compost with oxygen and speed up the composting process, periodically loosen the waste. Thus, at the first stage, the raw material is fermented with saprophytic bacteria with the addition of nutrients, as a result of which the raw material loses its aggressive properties and pathogenic microorganisms, which are often present in animal excrement, die.

The duration of the first stage of composting depends on a number of factors, mainly such as the type of feedstock, its volume and humidity. For this reason, the degree of readiness of the substrate is considered to be a decrease in temperature below 40 degrees.

To obtain nettle mash in an anaerobic environment, the main raw material is young nettle tops (without seeds). Preliminary mechanical grinding is carried out using a knife chopper. Next, the crushed nettle is poured into the container 80% by volume without pressing, and the container is filled 90% with water purified by the reverse osmosis system. Next, 1% of the volume of the beet molasses container and 4% of liquid vermicompost, obtained mechanically using a cavitation dispersant (rotary-pulsation apparatus), are added. Next, the container is hermetically sealed, a water seal is installed, and the contents are infused at a temperature of 15-25 degrees for at least 10 days until the fermentation process is completely completed. In this case, the contents are mixed twice a day without access to atmospheric air. Afterwards, the contents are pumped into storage containers. The most important point is to prevent oxygen from entering the containers during storage. When taking the mash into the storage tank, carbon dioxide (CO2) is pumped under a pressure of no more than 0.5 bar to avoid the entry of atmospheric air and, as a consequence, the penetration of bacteria, fungi and protozoa from the environment (contamination), which will inevitably spoil it. The suitability of mash for use is easily determined by the organoleptic method - suitable mash has a bright yellow color and a very tart, but pleasant smell; spoiled mash is black, with a strong unpleasant odor and an abundance of various molds on the surface.

At the second stage of composting, prepared nettle mash is added to the substrate obtained at the first stage of composting. It has been noticed that nettle wash, even in high concentrations, does not have a negative effect on the worm. Therefore, you can add it as much as necessary to obtain the optimum humidity of the substrate for the worm when preparing it instead of water (that is, bring the humidity of the substrate to 70%). After mixing the substrate with nettle mash, the substrate is aged.

After 72 hours, the resulting finished substrate is loaded into a continuous vermireactor (or piles are formed) and colonized with an earthworm of the species Eisenia foetida for further production of vermicompost. It is recommended to use the above-mentioned ready-made substrate for worm colonization no later than 1 month from the date of receipt.

A series of practical tests and observations of the vermicomposting process of test and control samples was carried out. On 1 square meter of substrate prepared by the above method after vermicomposting, the total biomass of the worm is on average 20% higher than on 1 square meter of substrate prepared without the prior addition of aerobic saprophytic bacteria and nettle mash prepared in an anaerobic environment using liquid vermicompost. This fact indicates better processing of the substrate compared to conventional methods. Also, the nettle mash itself, with which the substrate was pre-impregnated instead of water, is itself a powerful organic fertilizer and plant growth stimulator, which, together with better vermicomposting, gives a total positive effect when used on plants. Also, since one of the tasks is waste disposal, the product was checked for the presence of pathogenic microorganisms: the product is safe for use, as evidenced by the conclusion of the veterinary laboratory about the absence of pathogenic and pathogenic microorganisms, cells, enterobacteria, viable eggs of helminth larvae and intestinal cysts pathogenic protozoa.

The finished product was examined for compliance with the requirements of GOST 34102-2017 “Organic fertilizers based on organic waste from crop production and enterprises processing crop products.” Table 1 shows the test results.

Table 1 - Test results of the finished product

No. Parameter name Name of the regulatory document for the test method Requirement GOST 34102-2017 Test result 1 Mass fraction of dry matter GOST26713-85 - 45.8% 2 Mass fraction of organic matter, per dry product GOST 27980-88 Not less than 25% 27.7% 3 Mass fraction of ash GOST 26714-85 - 72.3% 4 pH _kcl GOST 27979-88 5.5-8.0 units. 7.7 units Mass fraction in the product with initial moisture content 5 Ammonium nitrogen GOST 26716-85 - 0.39 6 Total nitrogen GOST 26715-85 Not less than 0.30% 1.2 7 Total phosphorus GOST 26717-85 Not less than 0.20% 1.3 8 Total potassium GOST 26718-85 Not less than 0.30% 1.0

Laboratory analyzes and practical tests have shown that the proposed method makes it possible to obtain completely natural, biologically active vermicompost of improved quality with a more pronounced positive effect on plants. A more accelerated dynamics of the growth of the worm population and its density was also observed compared to the conventional method of obtaining vermicompost.

Claims (4)

1. A method for producing biologically active vermicompost, including fermentation of organic waste and vermicomposting of the fermented product, characterized in that fermentation is carried out by introducing saprophytic bacteria under aerobic conditions at a temperature not exceeding 50°C; after passing through the thermophilic phase, liquid nettle mash is added to the prepared substrate, after prepared with the addition of liquid vermicompost in an anaerobic environment, after 72 hours the finished substrate is subjected to vermicomposting with earthworms to obtain biologically active vermicompost. 2. The method according to claim 1, characterized in that vermicelli containing saprophytic bacteria, humic acids, fulvic acids, amino acids, vitamins, micro-, macroelements and hormones is added to organic waste. 3. The method according to claim 1, characterized in that during the fermentation process periodic loosening of organic waste is carried out. 4. The method according to claim 1, characterized in that vermicomposting is carried out with earthworms of the species Eisenia foetida.