RU2723401C1 - Method of adding organomineral additive into soil - Google Patents

Abstract

FIELD: agriculture.SUBSTANCE: invention relates to the agriculture. Method of adding to soil an organomineral additive is characterized by that it is added at ratio of organomineral additive and soil of 1:1, then dispersing and priming are carried out, wherein mineral component of additive used is phosphogypsum, organic component is lignin sludge, wherein components are used at following ratio of components by weight (wt. %): phosphogypsum - 20–25, lignin sludge - 75–80.EFFECT: invention allows to increase growth of grass mixtures, as well as to ensure transfer of heavy metals and rare-earth metals into plants.1 cl, 3 tbl, 1 ex

Description

The invention relates to the field of agriculture and can be used as an organomineral additive of prolonged action for the purpose of cultivating forest areas, reclaiming slopes of roads and landfills of solid municipal waste (MSW).

A known method of increasing soil fertility (US Pat. RU No. 2178964, publ. 10.02.2002), which consists in introducing phosphorus-containing raw materials into the soil together with an acidifying additive, using phosphorite flour as phosphorus-containing raw materials, and phosphogypsum is used as an acidifying additive in the ratio components in physical weight 1: 1.

The disadvantage of this method is the presence of an exclusively mineral component, the presence of which does not provide the fertile properties of the soil and the localization of the possible negative effects of unwanted impurities in the components of the mixture, in particular rare-earth metals in phosphogypsum, on the soil.

A known method of reclamation of agricultural land (US Pat. RU No. 2516468, publ. 05/20/2014), implying the introduction of soil fertilizing material, which is used as organomineral compost containing pig manure and cattle manure, sewage sludge and phosphogypsum in the following component ratio (wt.%): phosphogypsum with a pH of 5.0-5.5 - 10-13, pig manure - 11-13, sewage sludge - 6-8, cattle manure - the rest, which are composted in the summer for 3 months at high average daily temperatures of compost from 35 to 45 ° C, stirring monthly until maturing. Then, the resulting compost is applied to the soil once for 5 years at a dose of 60 t / ha, closing it at a depth of 14-18 cm in late summer and early autumn.

The disadvantage of this method is that in order to activate biochemical processes and at the same time neutralize harmful microflora in the resulting organomineral mixture, it is necessary to ensure conditions of high average daily compost temperatures, as well as monthly compost mixing throughout the summer period, which increases the complexity of the technology for producing soil-fertilization material.

A known method of producing a complex organic fertilizer based on natural aluminosilicates (US Pat. RU No. 2607600, publ. 10.01.2017), including the simultaneous mixing and grinding of organic and mineral components, moreover, the grinding of aluminosilicate raw materials and phosphogypsum lead to particle sizes of less than 30 microns, after of which subsequent mixing with vermicompost occurs in the following ratio of components (wt.%): aluminosilicates - 50-60, phosphogypsum - 10-20, vermicompost - 20-40.

The disadvantages of the method is the need to provide fine grinding aluminosilicate sorption raw materials and phosphogypsum to obtain a fraction of less than 30 microns, which implies additional energy costs. In addition, the use of vermicompost, including manure, litter, plant debris, etc., does not provide a complete microbiological purity of the fertilizer.

There is a method of improving the agrophysical properties of the soil (US Pat. RU No. 2423812, publ. 07.20.2011), adopted for the prototype, which consists in the introduction of phosphogypsum into the soil, its incorporation and sowing of agricultural crops. At the same time, compost is introduced into the soil to a depth of 10-14 cm, including animal waste - humus, phosphorus fertilizer production - dihydrate phosphogypsum and the woodworking industry - sawdust in a ratio of components of 50: 5: 1, respectively, after which the soil mixture is mixed to a homogeneous mass.

The disadvantage of this method is that livestock waste included in the compost is an additional factor in soil contamination by pathogenic microorganisms. Thus, in the case of unreasonable dosing of the organic component, there is a high probability of a violation of the physico-chemical balance of the soil due to the accumulation of the following metabolic products of microorganisms - ammonia, hydrogen sulfide and carbon dioxide.

The technical result is the creation of a method of increasing the growth efficiency of the grass mixture, as well as ensuring the transfer of heavy metals and rare-earth metals to plants in acceptable quantities.

The technical result is achieved by adding an organomineral additive at a ratio of organomineral additive and soil of 1: 1, then scattering and plowing, while phosphogypsum is used as a mineral component, lignin sludge is used as an organic component and the components are used in the following ratio of components by weight (wt.%):

phosphogypsum - 20-25;

lignin sludge - 75-80.

The method is as follows. As a mineral component of the organic-mineral mixture providing a high content of nutrients in the mixture - nitrogen, potassium and phosphorus (NKP), the waste from the production plant for the production of extraction phosphoric acid - phosphogypsum is used, as well as the organic component of the mixture, which is a source of organic compounds and nutrients, a dehydrated sludge of biological wastewater treatment of sulphite cellulose production is used - lignin sludge. Despite this, the presence of traces of heavy metals and rare-earth metals in the organomineral mixture of phosphogypsum and lignin sludge necessitates fractional application of the components to the soil. Lignin sludge is not carcinogenic, does not form toxic products in the environment that can accumulate in trophic chains, does not have mutagenic properties, and also does not contain pathogenic microflora and weed seeds.

Phosphogypsum acts as a mineral component, and lignin sludge, taken in ratios by weight (wt.%), Is phosphogypsum: phosphogypsum - 20-25, lignin sludge - 75-80. Mixing the components and their simultaneous introduction into the soil of sod-podzolic type with a mass ratio of the components of the organomineral additive and soil of 1: 1 is carried out using fertilizer spreaders, followed by plowing the additive to a depth of 15 to 20 cm and further cultivation of the soil thickness.

As a result of mixing phosphogypsum with an organic component, a complex granulometric fertilizer is obtained with the formation of insoluble calcium humate, cementing the structure of aggregates and increasing the stability of the organomineral complex with heavy metals and rare-earth metals included in it to leach from the soil and transfer elements to plant organisms. The introduction of a significant proportion of calcium ions into the soil with both phosphogypsum and the organic component causes the use of excess calcium, which is no longer used to displace metabolic sodium in the soil structure, in the biochemical mechanisms of the influx of heavy metals and strontium into plant organisms, thereby replacing them.

An example of a practical implementation of the method. Modeling of the process of growth of plant organisms with the inclusion of the proposed organomineral additives was carried out in laboratory conditions with the identification of the most suitable share composition of the soil mixture.

To simulate the process of growth of plant organisms on a three-component soil mixture, the ratio of the mass of the soil and the organic-mineral mixture of 50/50 was chosen with the ratios of sludge of lignin and phosphogypsum 0/100, 25/75, 50/50, 75/25, 100/0. To compare the simulated growth processes with conditions similar to natural conditions, a model was selected with a ratio of soil and organic-mineral mixture of 100/0 (control).

The selected ratios of the components of the soil mixture and the content in each of the systems of nutrient components, as well as stable strontium, CaO and heavy metals before planting, are presented in tables 1-2.

As plant organisms for their growth on soil mixtures of various components, we selected cereal grasses, which are widespread in the zone of mixed forests of the Northwestern region of the Russian Federation on sod-podzolic and podzolic soils: meadow bluegrass (Roa pratensis) 15%, festulolium (Festulolium) 30 %, Thin woodland (Agrostis capillaris) 5%, pasture ryegrass (Lolium perenne) 10%, annual ryegrass (Loliym multiflorum) 10%, meadow fescue (Festuca pratensis) 30%. A mixture of herbs was applied in an amount of 3 g / box.

Based on the norm of water consumption of annual herbs in the growing season, while growing on sod-podzolic soils, the herbs were irrigated 2 times a week with 150 ml of water per box.

For the efficient growth of plant organisms, 2 Osram L 18W / 77 T8 Fluora luminescent phytolamps were selected, which ensure the generation of a luminous flux of appropriate power and with a predominance of red and blue spectra that is suitable for intensifying photochemical processes. To simulate daylight hours of the natural conditions of plant growth, the lamps were turned on in the interval from 9:00 a.m. to 5:00 p.m.

Boxes were placed in a well-ventilated room with a constant temperature of 25 ° C and a relative humidity of 70%.

The duration of the experiment was 7 weeks after seed germination, in connection with the observation of the end of the growing season and the wilting of plants growing in box No. 6 (control).

According to the results of the experiment, it was revealed that the highest value of plant biomass belonged to box No. 2 (75 _{phosphogypsum} : 25 _{lignin sludge} ), and the lowest value to box No. 6 (control). The distribution of plant biomass values in the boxes relative to the control is presented as follows: the degree of biomass excess by 1.97 times relative to the control biomass was observed in box No. 2; 1.81 times - in box No. 3; 1.78 times in box No. 4; 1.49 times - in box No. 1; 1.47 times in box No. 5.

From the measurement results it is seen that the highest growth rate was observed in plants growing in boxes No. 3 and 6 (50 _{phosphogypsum} : 50 _{lignin sludge} , control), the lowest - in box No. 5 (0 _{phosphogypsum} : 100 _{lignin sludge} ). The plant growth rates in boxes No. 2, 4 and 1 had approximately the same values.

Similar distributions of biomass values and growth rates are associated with improved conditions for plant growth when an organic component, lignin sludge, is added to phosphogypsum with a ratio of 75 _{phosphogypsum} : 25 _{lignin sludge} and 50 _{phosphogypsum sludge} : 50 _{lignin sludge} .

If lignin sludge is included in a larger amount, it is possible to retain the slurry with an aqueous solution with nutrient components and the development of adverse microbiological processes.

As a result of determining the degree of distribution of strontium, CaO, and water-soluble forms of heavy metals in the plant-soil mixture system, the following contents of elements in plants were revealed (table 3).

Comparing the values of geochemical clarks of heavy metals in living matter and the revealed values of the content of water-soluble forms of heavy metals in plant organisms, there was no excess of copper and zinc in all the mixtures considered, however, an increased cadmium content was observed in samples No. 1 (100 _{phosphogypsum} : 0 _{lignin sludge} ) and 2 (75 _{phosphogypsum} : 25 _{lignin sludge} ) relative to clarke - 4 and 2.7 times. It should be taken into account that, in the case of consideration of the gross forms of the content of elements in plants, the indicators will be higher than those indicated by analysis.

When comparing the revealed values of strontium content in plant organisms with the average content of mobile forms of strontium in soil / plants — 0.002% — excesses were found in plants grown in boxes No. 1-3 — 6, 3, and 2 times.

An analysis of the obtained distributions of strontium in soil-plant-mixture systems after the experiment confirmed the fact that strontium is replaced by calcium ions when they are absorbed by plants (boxes No. 1 and 6 with a degree of transition of strontium of 85.7% and 61.0% and an excess of the number of calcium ions over stable strontium in 32 and 444 times), as well as the fact of the accumulative abilities of the organic component (a decrease in the degree of strontium absorption by plants with a decrease in calcium concentration and an increase in the proportion of lignin sludge in soil mixes in boxes No. 2-5).

According to the results of the experiment, it was found that the ratio of the components in the range of 25 _{phosphogypsum} : 75 _{sludge of lignin} -20 _{phosphogypsum} : 80 _{sludge of lignin} , taking into account a confidence interval of ± 5%, are optimal to ensure the fastest growth of plant organisms with the highest biomass relative to them control, as well as within the criterion of the absence of excess of absorbed strontium and heavy metals by plant organisms relative to their average content in plants. Moreover, the degree of transition of strontium varies from 33.3% to 35.7%, and the ratio of Sr: Ca in plants is 1: 130-1: 445.

Compared with the known solutions, the proposed method allows you to create a way to increase the growth efficiency of the grass mixture, as well as to ensure the transfer of heavy metals and rare-earth metals to plants in acceptable quantities.

Claims (3)

The method of applying organic-mineral additives to the soil, characterized in that it is applied at a ratio of organic-mineral additives to soil of 1: 1, then dispersion and plowing are carried out, while phosphogypsum is used as a mineral component, and lignin sludge is used as an organic component, and components are used in the following ratio of components by weight (wt.%): phosphogypsum - 20-25; lignin sludge - 75-80.