PL240190B1 - Carrier granulate, organic fertilizer containing this granulate, method of producing the organic fertilizer and method of delivering this fertilizer to the soil - Google Patents

Description

PL 240 190 B1

Description of the invention

The invention relates to a biochar-based carrier pellet, an organic fertilizer containing such a carrier pellet inoculated with an organic additive selected from mycorrhizal fungi, bacteria and marine algae, as well as a method for producing such a fertilizer and a method for delivering it to the soil.

Contemporary fertilizers have significantly increased the level of agricultural productivity, but their excessive and improper use can have negative and sometimes irreversible effects on soil health and the environment. Therefore, safe and sustainable alternatives are currently being searched for that would ensure a high level of productivity without harming the environment. One such approach that current research in the agricultural sector is focusing on is the use of organic fertilizers. One of the goals of research in this field is to identify, develop and manipulate unique combinations of microorganisms to achieve the desired properties of products.

For example, from the document EA 201100400 A1 a bacterial fertilizer is known which contains cells of the strains: Bacillus subtillis B-1, Bacillus megaterium BM-1, Azotobacter chroococcum A-2, Pseudomonas putida PP-1, Streptomyces atratus UZGIT-1, and a sorbent in in the form of a mixture of biohumus and carboxymethylcellulose (CMC), in a weight ratio of 4: 1, respectively. of bacterial strains, preparation of the sorbent by mixing vermicompost and CMC in a mass ratio of 4: 1, mixing the medium obtained after culturing the cells of the bacterial strain with the sorbent and granulating them.

In turn, the document CN 102442846 A discloses a method of producing a bio-organic fertilizer by means of spray granulation, which includes the following steps: preparation of a solid inoculant, granulation of the lignin liquor into organic granules, mixing organic granules with a solid powder, in which the powdered inoculant is added in an amount of 5 -15% by weight, based on the total weight of the finished composite microbial fertilizer, and mixing, granulating and drying, provided that the temperature of the material in the drying drum is not higher than 80 ° C.

On the other hand, document CN 104211519 A describes a granular microbial fertilizer, a carrier for the fertilizer and a method for producing granular microbial fertilizer. A microbial granular fertilizer comprises a core and a coating layer, the core containing the following components in parts by weight: 4-8 parts of shredded straw, 2-6 parts of wood chips, 10-12 parts of clay, and two strains of cellulose-degrading bacteria selected from the group of nitrobacteria and phosphate-solubilizing bacteria, which are evenly mixed, while the coating layer is formed by drying 3-6 wt.%. gelatin solution covering the outside of the core.

The basis of organic fertilizers can be, among others biochar, which has been known for many years as a soil enhancer. It is produced by the pyrolysis of biomass, a process essentially involving the heating and / or combustion of organic matter in an oxygen depleted environment at a predetermined rate. Combustion stops when the matter reaches a stage similar to charcoal. As a highly porous material, biochar is suitable for inoculating various additives, such as beneficial microorganisms, nutrients, and water. High porosity biochar acts as a delivery system for a range of beneficial compounds and additives suitable for specific applications.

Exemplary additives include compositions based on various strains of bacteria and fungi. They can act in one or more ways including: competition, antagonism, stimulation of systemic immune responses, and attack and consumption of fungal resting structures. Plant bioprotectants are used to treat crops in commercial conditions because of their antifungal, antiviral and antibacterial properties.

Despite advances in the field of organic fertilizers, there is still a need for compositions and methods that allow plant bioprotection, e.g., protection of plants against microbial pathogens, while not using agrochemicals. Solving these problems was one of the aims of the present invention.

The aim of the invention was primarily to develop a carrier granulate and an organic fertilizer containing it in the form of granules for use in the cultivation of vegetables, ornamental plants and field plants, which would improve the microbiological and physicochemical properties of the soil and increase the yield possibilities and improve the morphological characteristics of plants. It turned out an organic fertilizer

PL 240 190 B1 containing a biochar-based carrier granulate inoculated with microorganisms and / or algae meets these requirements and is therefore an attractive alternative to the previously used mineral fertilizers and plant protection products. Moreover, it was observed that the role of the biochar-based carrier granulate is not limited only to providing a developed support surface for microorganisms and / or algae, as the positive effect of the granulate itself on limiting the development of pathogenic organisms, increasing yields and soil fertility index (BIF) was noted. ). In a first aspect, the invention relates to an organic fertilizer carrier granulate comprising:

- porous biochar in an amount from 10 to 35 wt.%.

- lignocellulosic substrate in an amount of 61 to 89 wt.

molasses in an amount of 1 to 4 wt.%

In a second aspect, the invention relates to an organic fertilizer containing a carrier granulate as defined above and at least one organic additive selected from mycorrhizal fungi, sea algae extracts and bacteria.

Preferably, the organic fertilizer according to the invention contains bacteria of the genus Bacillus subtilis, Bacillus licheniformis, Bacillus nitrogenofixans, Bacillus megaterium and / or an extract of marine algae of the genus Ascophyllum nodosum.

Preferably, at least one organic additive is inoculated in the pores of the biochar.

In a third aspect, the invention also relates to a method of producing an organic fertilizer comprising the following steps:

a) mixing a porous biochar in an amount of 10 to 35 wt%, a lignocellulosic substrate in an amount of 61 to 89 wt%. and molasses in an amount of 1 to 4 wt.%,

b) granulating the mixture from step (a) until the carrier granulate is obtained,

c) preparing a suspension of at least one organic additive selected from mycorrhizal fungi, sea algae extracts and bacteria in peptone water with the addition of poly (vinylpyrrolidone) (PVP),

d) incubating the suspension obtained in step (c)

e) applying the incubated suspension obtained in step (d) in an amount of 5 to 10% by weight to the carrier granulate obtained in step (b).

Preferably, in step (a), a porous biochar and a particulate lignocellulosic substrate with a particle size of not more than 3 mm are used.

Preferably, step (b) comprises a two-step granulation.

Preferably, the suspension obtained in step (c) is lyophilized prior to incubation.

Preferably, in step (d), the suspension is incubated for 24 hours on a shaker.

Preferably, in step (e), the incubated suspension is applied to the carrier granulate by spraying or dusting.

Preferably, step (e) is followed by an additional step (f): incubating and drying the carrier granulate covered with the suspension.

In a fourth aspect, the invention relates to a method of delivering an organic fertilizer as defined above to the soil in a substrate in an amount of 400 to 800 kg / ha by means of a precision seed drill when sowing seeds into the soil, by placing the fertilizer pellets at a distance not more than 5 cm below the seed line or within the soil. side to the seed row.

The organic fertilizer based on biochar inoculated with the microorganisms according to the invention is used in the cultivation of plants of commercial interest. It contributes to limiting the development of pathogenic mold fungi in the soil and / or increasing its fertility, as well as positively influencing the yield of the tested plants and their chemical composition (Examples II and III). The responses of plants and pathogens are varied and depend on the species of the plant being grown. Therefore, depending on the type of plant, it is important to select additives (microorganisms) introduced with biocarbon into the soil. The advantage of using the fertilizer according to the invention is its broad spectrum of action, regardless of the type of crop or soil. Moreover, it makes it possible to increase the efficiency of organic farming, which increases its competitiveness in relation to conventional agriculture. Another aspect of the benefits of the fertilizer according to the invention is its method of application. The fertilizer is supplied to the soil in the under-sowing, directly in the vicinity of the seeds, which results in easy availability of ingredients from the very beginning of plant vegetation (Example IV). The fertilizer according to the invention, apart from the agronomic aspect (integrated crop cultivation - Directive 2009/128 / EC), is an attractive alternative from the environmental protection point of view to the use of mineral fertilizers and chemical plant protection.

PL 240 190 B1

Brief description of the figures of the drawing

The invention is illustrated in the preferred embodiments of the drawing, in which:

Fig. 1 shows a plot of the values of selected soil parameters and plant-tomato (greenhouse experiment);

Fig. 2 shows a plot of the values of selected soil and plant parameters - beetroot (field experiments);

Fig. 3 shows a plot of selected soil and plant parameters - Chinese cabbage (field experiments);

Fig. 4 shows a plot of the values of selected soil and plant parameters - string beans (field experiments);

Fig. 5 is a graph of selected soil and plant parameters - maize (field experiments);

Fig. 6 shows a plot of the values of selected soil and plant parameters - potato (field experiments);

Fig. 7 is a graph of selected soil and plant parameters - soybean (greenhouse experiments);

Fig. 8 shows a plot of selected soil and plant parameters - rye (field experiments);

Fig. 9 shows a plot of the values of selected soil and plant parameters - wheat (field experiments);

Fig. 10 shows a plot of selected soil parameters and oat plant parameters (field experiments).

Embodiments of the invention

The following examples are provided merely to illustrate the invention and to explain its various aspects, not to limit it, and should not be construed as being within the scope as defined in the appended claims. In the following examples, unless otherwise indicated, standard materials and methods used in the art were used, or the recommendations of the manufacturers for specific reagents and methods were followed.

The bulk density of biochar used in the production was 160.56 g / l with a moisture content of 3.32%. The bulk density of the lignocellulosic substrate was 172.00 g / l with a moisture content of 13.70%. The following materials were used for the tests: biological preparation Nitragina by Biofood, in the form of peat, which contained bacteria of the genus Bradyrhizobium, organic preparation Bio-Algeen S90, as a natural extract of sea algae and seaweed, produced by the German company Schulze & Hermsen GmbH, Bradyrhizobium strain japonicum from the collection of the Department of General and Environmental Microbiology of the University of Life Sciences in Poznań, mycorrhizal fungi - Mykoflor, EM lactic acid bacteria - Greenland, strains of lactic bacteria, Bacillus bacteria from the collection of the Department of General and Environmental Microbiology of the University of Life Sciences in Poznań, biochar in pellet form: obtained from husked oat residues that could not be used as animal feed.

The studies on the analysis of the effectiveness of the fertilizer preparation were carried out in a greenhouse adapted to carry out a full process with appropriate conditions, in vases of various types and sizes, and in the open area (field and field experiments) so that many experimental series were carried out in a short time. The possibilities of using the new fertilizer in various plants, doses and methods of application (near the seeds, at an appropriate distance from the seeds) were assessed. A wide spectrum of research in greenhouse conditions was used to identify experimental variants for the stage of field research and cultivation of ornamental and vegetable plants, and consequently to formulate recommendations for fertilizer application for future recipients.

Metagenomic analysis of the gene encoding the 16S rRNA was performed on the basis of the hypervariable region V3-V4 of the 16S rRNA gene. Specific sequences of the 341F and 785R primers were used to amplify the selected region and prepare the library. The PCR reaction was performed using a Q5 Hotstart High-Fidelity DNA Polymerase (NEBNext), reaction conditions as recommended by the manufacturer.

EXAMPLE 1: A method for producing a carrier granulate according to the invention.

Preparation of the carrier granulate, consisting of:

a) biochar obtained from agricultural waste, mainly grain husks and chaff,

PL240 190 Β1

b) lignocellulosic substrates, which are a mixture of chaff, ears and husks left over from threshing cereals,

(c) beet molasses.

The carrier granulate ingredients were combined and mixed for 20 min, and then pelleted in a granulator equipped with a matrix of 4.8 mm in diameter. The granulate was then cooled down to ambient temperature in the rotary cooler. The final weight of the substrate has a biochar content of 10 to 35 wt.%, The molasses content of 1 to 4 wt.%, And the content of lignocellulosic substrate 61 to 89 wt.%.

According to the procedure described, the carrier granules were obtained with the compositions shown in Table 1 below:

Table 1: Compositions of the carrier granulates according to the invention

No. Biochar content [wt.%] Lignocellulosic substrate content [wt.%] Molasses content [wt.%] 1 10 86 4 2 15 81.5 3.5 3 twenty 78 2 4 25 73.5 1.5 5 thirty 67 3 6 30.93 65.98 3.09 7 30.61 66.33 3.06 8 31.58 65.26 3.16 9 33 64.5 2.5 10 35 64 1

EXAMPLE 2: The method of producing the Agriqultura organic fertilizer.

In order to obtain an inoculum of bacteria of the genus Bacillus subtilis, Bacillus licheniformis, Bacillus megaterium and / or mycorrhizal fungi, ascophyllum nodosum sea algae extract for inoculation on a biochar base product (i.e. carrier granules), a suspension of microorganisms and / or mycorrhizal fungi ( depending on the fertilizer variant) in peptone water with the addition of poly (vinylpyrrolidone) (PVP).

Before the multiplication of the microorganisms in peptone water, with which the pellets were sprayed, cultures were carried out on solid substrates that were selective for a particular variant of the obtained pellet, in Petri dishes. This treatment was necessary to activate the metabolic activation of lyophilized microorganisms. Bacteria of the genus Bacillus were grown on Nutrient Agar with yeast extract, Aminobook and NaCl; fungi on PDA - Potato Dextrose Agar, algae on BO nutrient broth; Rhizobium bacteria on YMA medium. After passing the indicated microorganisms three times, the Petri dishes were flooded with 5 ml of physiological saline, and then the homogeneous suspension obtained by vortexing on a Vortex device, was sterile transferred to peptone water with or without PVP. The suspension in 1 ml contained ^{10 12-10 14 cfu} of microorganism cells, which was assessed by the serial dilution method and the Pelczer method (absorbance) on a spectrophotometer at a wavelength of 600 nm compared to the obtained standard curves for the tested strains. After 24 h of cultivation (incubation on a shaker at 90 rpm / minute) a suspension was obtained in which the tested microorganisms amounted to 10 ⁸ cfu in 1 ml (confirmed only by the Pelczer method). The pellet prepared in this way was inoculated in a ratio of 1:10, i.e. 1 ml of suspension per 10 g of pellet.

Spraying the previously obtained suspensions onto the carrier granules in an amount of 1 ml of suspension per 1 g of fertilizer 5-10% by weight (assuming that 1 ml = 1 g). After incubation (24 h) and drying of the obtained bio-fertilizer (in order to inhibit the metabolism of bacteria),

It was packaged and stored at 15 ° C. The high porosity of biochar combined with the high absorbency of lignocellulosic substrates guarantees good adhesion of the suspensions obtained in the previous stage to the product surface.

According to the above method, the following variants of organic fertilizers were obtained:

AgriQultura Nr 1 (BW) - reference fertilizer with the composition: 30% by weight active biochar, 67 wt. lignocellulosic substrates, 3 beet molasses [i.e. carrier granulate No. 5 of Example 1 without organic additive].

AgriQultura No. 2 (BWM) - organic fertilizer with the composition: 30% by weight. active biochar, 64 wt. lignocellulosic substrates, 3 wt. beet molasses, 3 wt. mycorrhizal fungi [i.e. carrier granulate No. 6 of Example 1 with an organic additive in the form of an inoculum of mycorrhizal fungi].

AgriQultura No. 3 (BWA) - organic fertilizer with the composition: 30% by weight. active biochar, 64 wt. lignocellulosic substrates, 3 wt. beet molasses, 3 wt. Ascophyllum nodosum seaweed extract [i.e. carrier granulate No. 6 of Example 1 with organic additive in the form of marine algae extract].

AgriQultura No. 4 (BWE11) - organic fertilizer with the composition: 30% by weight. active biochar, 65 wt. lignocellulosic substrates, 3 wt. beet molasses, selected active strains of bacteria: 1 wt. Bacillus subtilis 108 cfu / g, 1 wt. Bacillus licheniformis 108 cfu / g [i.e. carrier granulate No. 7 of Example 1 with an organic addition in the form of an inoculum of two bacterial strains].

AgriQultura No. 5 (BWAE11) - organic fertilizer with a composition of: 30% by weight. active biochar, 62 wt. lignocellulosic substrates, 3 wt. beet molasses, 3 wt. Ascophyllum nodosum seaweed extract, selected bacterial strains: 1 wt. Bacillus subtilis 108 cfu / g, 1 wt. Bacillus licheniformis 108 cfu / g [i.e. carrier granulate No. 8 of Example 1 with organic additive in the form of marine algae extract and inoculum of two bacterial strains].

EXAMPLE 3: Analysis of the effectiveness of a fertilizer preparation enriched with microorganisms under controlled conditions (pot experiments) and in the field.

An analysis of the yield of plants, an analysis of their chemical composition and tests aimed at assessing the sanitary condition of the soil (Fusarium sp. Number, Alternaria sp.) Under their cultivation were carried out, after applying fertilizer prototypes based on biochar and microorganisms, as well as the soil fertility index ( BIF index).

In addition, genetic analyzes were carried out in soil samples taken at the time of submitting the experiment, before introducing fertilizers into the soil (variant "0") and during the harvest phase of the plants.

The conclusions from the conducted experiments are as follows:

1. As illustrated in Fig. 1, the introduction of biochar with the addition of preparation E11 (BWE11) contributed to an increase in the number of tomato fruits per plant, a reduction in the development of potentially pathogenic mold fungi and an increase in the soil fertility index (BIF), as well as contributed to an increase in biodiversity. soil. The use of the BWE11 product version significantly increased the fruit yield.

2. Three types of bacteria Actinobacteria, Firmicutes, and Proteobacteria dominated in the experimental variants used in tomato cultivation.

3. The innovative fertilizer prototype based on biochar increased soil biodiversity under tomato cultivation and contributed to the activation of many families of bacteria, the presence of which was not shown in the soil without the addition of fertilizer and plants. This tendency was most pronounced in the BWE11 facility.

4. As shown in Fig. 2, in the soil under beet cultivation, the reduction of the development of mold fungi of the genus Fusarium and Alternaria and the increase in the yield of plants was obtained after the use of biochar inoculated with the preparation E11 (BWE11).

5. According to the diagram presented in Fig. 3, the highest yield of Chinese cabbage, the highest nitrogen and protein content in plants was obtained after the application of the biochar composite inoculated simultaneously with algae and probiotic bacteria (variant BWAE). In this variant, the limiting effect of the fertilizing agent on the multiplication of pathogenic fungi of the genus Alternaria was also observed.

6. After the application of the BWER product, a clear tendency to increase the total yield of string bean pods was observed. The harvested crop was of high quality. It was found that all variants of the innovative composite used together with microorganisms

PL240 190 Β1 resulted in a higher content of nitrogen and protein in plant DM compared to traditional cultivation (control) and inhibited the development of pathogenic Fusarium fungi and increased the fertility index BIF. The results are illustrated in Fig. 4.

7. There was no effect of the research factor on the elements of maize yield (density, number of cobs per plant, mass of one thousand grains). However, the effect of the BWAE variant on the reduction of the development of Fusarium and Alternaria in the soil and an increase in the content of starch in plants was observed. The results are illustrated in Fig. 5.

8. In the case of potato cultivation, high efficacy of BWAE11 against pathogenic fungi of the genus Alternaria was noted. As well as its significant impact on the size of the crop yield and the value of the BIF index. The results are shown in Fig. 6.

9. As shown in Fig. 7, the application of the fertilizer variant based on biochar and symbiotic nodule bacteria (BWR) allowed to obtain the highest yield, high protein content in soybean plants and reduction of potentially pathogenic fungi in the soil, as well as an increase in soil fertility (value BIF indicator).

10. The research carried out in terms of the effect of the introduced innovative fertilizer on pathogenic fungi in rye cultivation shows that the preparation used significantly reduced the fungi of the genus Alternaria, influenced the yield of plants and the soil fertility index (in particular, the BWAE11 variant), which is illustrated in Fig. 8. BWE11 turned out to be the best for the root growth and the rye yield itself. After the application of the BWE11 product, the plant roots were the most developed, had the greatest volume, surface and thickness, and had the highest degree of mycorrhization.

11. The application of biochar (BWM) in the cultivation of wheat inhibited the development of pathogenic fungi of the genus Fusarium and Alternaria. Moreover, it allowed to obtain the highest yield of plants and the highest value of the BIF index. The results are shown in Fig. 9.

12. In the case of oat cultivation, high effectiveness of the BW variant was noted in relation to pathogenic fungi of the genus Alternaria and Fusarium. As well as its significant impact on the size of the grain yield and the value of the BIF index. The results are shown in Fig. 10.

EXAMPLE 4: Supplying fertilizer to the soil:

Organic fertilizer is supplied under the sowing in the amount of 25-50 g / plant by means of a point seeder when sowing seeds into the soil, by placing the fertilizer granules at a distance of no more than 3-5 cm under the seeds or roots, then it is covered with soil and watered with water. Table 3 below shows the amounts of the fertilizers according to the invention used in the cultivation of the various types of plants.

Table 3: Amounts of fertilizers according to the invention used in the cultivation of various types of plants

Carrier granules / Organic fertilizer Plants Amount of carrier granules / organic fertilizer AgriQultura No. 1 (BW) Red beets, bulbs, cruciferous vegetables and flowers of the Aster family 25 - 50 g / plant AgriQultura No. 2 (BWM) Potatoes, red beets, tomatoes, peppers, carrots, leeks, wheat and other grains 25 - 50 g / plant or 600 - 800 kg / ha AgriQultura No. 3 (BWA) cucurbits (pumpkin, zucchini, cucumber), lettuce, tomato, corn, cereal crops 25 - 50 g / plant or 600-800 kg / ha

Claims (11)

PL240 190 Β1 AgriQultura No. 4 (BWE11) production of seedlings, cultivation of potatoes, red beet, lettuce, paprika and shiny sage, petunia and other ornamental plants 25-50 g / plant AgriQultura No. 5 (BWAE11) kohlrabi, cabbage and other cruciferous vegetables, root vegetables, onions, cucurbits and pelargonium, petunia and other ornamental plants 25 - 50 g / plant Patent claims 1. Organic fertilizer carrier granulate, characterized in that it contains: - porous biochar in an amount from 10 to 35 wt.%. - lignocellulosic substrate in an amount of 61 to 89 wt. molasses in an amount of 1 to 4 wt.%. 2. An organic fertilizer containing the carrier granulate and at least one organic additive, characterized in that the carrier granulate comprises 10 to 35 wt. porous biochar, from 61 to 89 wt. % of the lignocellulosic substrate and from 1 to 4 wt. molasses and said at least one organic additive is selected from mycorrhizal fungi, sea algae extracts and bacteria. Organic fertilizer according to claim 2, characterized in that it contains bacteria of the genus Bacillus subtilis, Bacillus licheniformis, Bacillus nitofixans, Bacillus megaterium and / or an extract of marine algae of the genus Ascophyllum nodosum. 4. Organic fertilizer according to claim 2 or 3, characterized in that at least one organic additive is inoculated in the pores of the biochar. 5. A method of producing an organic fertilizer, characterized in that it comprises the steps of: a) mixing a porous biochar in an amount of 10 to 35 wt%, a lignocellulosic substrate in an amount of 61 to 89 wt%. and molasses in an amount of 1 to 4 wt.%, b) granulating the mixture from step (a) until the carrier granulate is obtained, c) preparing a suspension of at least one organic additive selected from mycorrhizal fungi, sea algae extracts and bacteria in peptone water with the addition of poly (vinylpyrrolidone) (PVP), d) incubating the suspension obtained in step (c), e) applying the incubated suspension obtained in step (d) in an amount of 5 to 10% by weight to the carrier granulate obtained in step (b). 6. The method according to claim 5, characterized in that in step (a) a porous biochar and a particulate lignocellulosic substrate with a particle size of not more than 3 mm are used. A method according to claim 5 or 6, characterized in that step (b) comprises a two-stage granulation. The method according to any one of claims 5-7, characterized in that the suspension obtained in step (c) is lyophilized prior to incubation. The method according to any one of claims 5-8, characterized in that in step (d) the incubation of the suspension is carried out for 24 hours on a shaker. Method according to one of the claims 5-9, characterized in that in step (e) the incubated suspension is applied to the carrier granulate by spraying or dusting. Method according to one of the claims 5-10, characterized in that, after step (e), an additional step (f) is carried out: incubating and drying the carrier granulate covered with the suspension.