CN111018624A - Mineral base fertilizer synergist with soil improvement effect and preparation method thereof - Google Patents

Abstract

The invention discloses a mineral base fertilizer synergist with a soil improvement effect, which comprises the following components in parts by weight: 12-24 parts of volcanic ash, 13-28 parts of coal residues, 14-27 parts of rare earth, 1.8-3.5 parts of lime, 1.7-2.7 parts of urease, 2.5-6 parts of phosphatase, 1-3 parts of dehydrogenase, 2-6 parts of ammonifying bacteria, 3.5-6 parts of actinomycetes, 4-7 parts of azotobacter chroococcum, 1.5-4 parts of azotobacter chroococcum, 3-8 parts of streptomyces jingyangensis, 2-3 parts of bacillus licheniformis, 0.6-1.5 parts of bacillus subtilis, 0.5-1.2 parts of trichoderma harzianum, 0.6-1.4 parts of bacillus mucilaginosus, 1-2 parts of bacillus coagulans, 2-4 parts of bacillus megaterium, 4.5-5.5 parts of polyglutamic acid, 1.7-3 parts of polyacrylamide, 4-6 parts of urease inhibitor and 1.5-3 parts of ammonia stabilizer. According to the invention, various ores are combined, so that the mineral content is improved, meanwhile, the decomposition of fertilizers in soil can be accelerated by various microbial enzymes of the celestial body, meanwhile, various biological fungi are added, the activity of soil can be enhanced, the urease activity in soil can be integrally inhibited, the urea hydrolysis is delayed, and the environment is protected.

Description

Mineral base fertilizer synergist with soil improvement effect and preparation method thereof

Technical Field

The invention relates to the technical field of pesticides, in particular to a mineral base fertilizer synergist with a soil improvement effect and a preparation method thereof.

Background

Soil is originally a natural accommodation place and a purification treatment place of various wastes, soil accepts pollutants, does not indicate that the soil is polluted, and indicates that the soil is polluted only when various pollutants accommodated in the soil are excessive and influence and exceed the self-purification capacity of the soil, so that the soil has harmful influence on hygiene and epidemiology. Causes of soil pollution, such as industrial sludge, garbage agriculture, sewage irrigation, pollutant sedimentation in the atmosphere, and the use of heavy metal-containing mineral fertilizers and pesticides in large quantities.

A synergist is generally a substance which does not have a specific activity or has a low activity, but when the synergist is mixed with a substance with the activity, the performance of the active substance can be greatly improved. The common synergist comprises pesticide synergist, fertilizer synergist, concrete synergist, antibacterial synergist, desulfurization synergist, etc., wherein the fertilizer synergist is prepared by mainly taking medium and trace elements essential for crops, compounding urease inhibitor and ammonia stabilizer, and then compounding biological agent, pesticide and plant production promoter. The microbial organic fertilizer synergist is applied with various organic fertilizers, farmyard manure and the like, so that the utilization rate of the fertilizer is obviously improved, the requirement of nutrients of crops in various growth periods is met, the soil environment is fundamentally improved, and the microbial organic fertilizer synergist is an optimal fertilizer synergistic product.

Aiming at the problems that the conventional fertilizer synergist is lack of minerals, the acid-base balance of soil is insufficient due to long-term use, the mineral absorption of crops is low, and the yield is reduced, a mineral base fertilizer synergist with a soil improvement effect and a preparation method thereof are provided.

Disclosure of Invention

The invention aims to provide a mineral-based fertilizer synergist with a soil improvement effect, and solves the problems in the background art.

In order to solve the above problems, the present invention provides the following technical solutions: a mineral substance base fertilizer synergist with a soil improvement effect is characterized in that: the weight ratio of the components is as follows: 12-24 parts of volcanic ash, 13-28 parts of coal residues, 14-27 parts of rare earth, 1.8-3.5 parts of lime, 1.7-2.7 parts of urease, 2.5-6 parts of phosphatase, 1-3 parts of dehydrogenase, 2-6 parts of ammonifying bacteria, 3.5-6 parts of actinomycetes, 4-7 parts of azotobacter chroococcum, 1.5-4 parts of azotobacter chroococcum, 3-8 parts of streptomyces jingyangensis, 2-3 parts of bacillus licheniformis, 0.6-1.5 parts of bacillus subtilis, 0.5-1.2 parts of trichoderma harzianum, 0.6-1.4 parts of bacillus mucilaginosus, 1-2 parts of bacillus coagulans, 2-4 parts of bacillus megaterium, 4.5-5.5 parts of polyglutamic acid, 1.7-3 parts of polyacrylamide, 4-6 parts of urease inhibitor and 1.5-3 parts of ammonia stabilizer.

As a further preferable mode of the invention, the paint also comprises the following components in percentage by weight: 24 parts of volcanic ash, 28 parts of coal residues, 27 parts of rare earth, 3.5 parts of lime, 2.7 parts of urease, 6 parts of phosphatase, 3 parts of dehydrogenase, 6 parts of ammonifying bacteria, 6 parts of actinomycetes, 7 parts of azotobacter chroococcum, 4 parts of azotobacter chroococcum, 8 parts of streptomyces jingyangensis, 3 parts of bacillus licheniformis, 1.5 parts of bacillus subtilis, 1.2 parts of trichoderma harzianum, 1.4 parts of bacillus mucilaginosus, 2 parts of bacillus coagulans, 4 parts of bacillus megaterium, 5.5 parts of polyglutamic acid, 3 parts of polyacrylamide, 6 parts of urease inhibitor and 3 parts of ammonia stabilizer.

As a further preferable mode of the invention, the paint also comprises the following components in percentage by weight: 2 parts of volcanic ash, 3 parts of coal residues, 4 parts of rare earth, 1.8 parts of lime, 1.7 parts of urease, 2.5 parts of phosphatase, 1 part of dehydrogenase, 2 parts of ammonifying bacteria, 3.5 parts of actinomycetes, 4 parts of azotobacter chroococcum, 1.5 parts of azotobacter vinelandii, 3 parts of streptomyces jingyangensis, 2 parts of bacillus licheniformis, 0.6 part of bacillus subtilis, 0.5 part of trichoderma harzianum, 0.6 part of bacillus mucilaginosus, 1 part of bacillus coagulans, 2 parts of bacillus megaterium, 4.5 parts of polyglutamic acid, 1.7 parts of polyacrylamide, 4 parts of urease inhibitor and 1.5 parts of ammonia stabilizer.

In a further preferred embodiment of the present invention, the manufacturing process comprises the following steps:

s1, crushing the mineral soil, namely pouring the volcanic ash, the coal residues, the rare earth and the lime into a crusher to be crushed fully, wherein the crushed particles are controlled to be 0.12-0.15 mm;

s2, preparing a culture medium, pouring ammoniated bacteria, actinomycetes, azotobacter chroococcum, streptomyces jingyangensis, bacillus licheniformis, bacillus subtilis, trichoderma harzianum, bacillus mucilaginosus, bacillus coagulans and bacillus megaterium into the culture medium according to parts, fully stirring for 25min, continuously injecting a mixture of oxygen and nitrogen in the stirring process, feeding at the speed of 85ml/min, keeping the operation at normal temperature, and fully mixing the mixture with the mineral soil;

s3, mixing the microorganisms, mixing urease, phosphatase and dehydrogenase with the raw materials in the step S2, and feeding the mixture into a heat preservation box, wherein the temperature is controlled to be 65-72 ℃ and lasts for 6 hours;

s4, mixing, stirring and processing, namely mixing and stirring the raw material obtained in the step S3, polyglutamic acid, polyacrylamide, urease inhibitor and ammonia stabilizer, and keeping the temperature at 60-72 ℃ for 25min in the stirring process;

and S5, sterilizing, mixing the strips, sterilizing the materials, and standing for 10min to finish the processing.

In a more preferred embodiment of the present invention, in step S2, the stirring speed is controlled to 150 to 280r/min during the stirring process.

In a more preferred embodiment of the present invention, in step S2, the culture medium is a mixture of distiller' S grains, vinegar residue, cassava residue, sugar residue, and furfural residue.

In a more preferred embodiment of the present invention, the mixing ratio of oxygen and nitrogen is set to 1:0.8 in step S2.

In a more preferred embodiment of the present invention, in step S5, the sterilization method is ultraviolet sterilization.

Compared with the prior art, the invention has the following beneficial effects:

according to the invention, various ores are combined, so that the mineral content is improved, meanwhile, various microbial enzymes of the celestial body can accelerate the decomposition of fertilizers in soil, and meanwhile, various biological fungi are added, so that the activity of the soil can be enhanced, the urease activity in the soil can be integrally inhibited, the urea hydrolysis is delayed, and the processing method is simple and relatively environment-friendly.

Drawings

FIG. 1 is a simplified schematic diagram of the overall process of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, the present invention provides a technical solution: a mineral substance base fertilizer synergist with a soil improvement effect is characterized in that: the weight ratio of the components is as follows: 12-24 parts of volcanic ash, 13-28 parts of coal residues, 14-27 parts of rare earth, 1.8-3.5 parts of lime, 1.7-2.7 parts of urease, 2.5-6 parts of phosphatase, 1-3 parts of dehydrogenase, 2-6 parts of ammonifying bacteria, 3.5-6 parts of actinomycetes, 4-7 parts of azotobacter chroococcum, 1.5-4 parts of azotobacter chroococcum, 3-8 parts of streptomyces jingyangensis, 2-3 parts of bacillus licheniformis, 0.6-1.5 parts of bacillus subtilis, 0.5-1.2 parts of trichoderma harzianum, 0.6-1.4 parts of bacillus mucilaginosus, 1-2 parts of bacillus coagulans, 2-4 parts of bacillus megaterium, 4.5-5.5 parts of polyglutamic acid, 1.7-3 parts of polyacrylamide, 4-6 parts of urease inhibitor and 1.5-3 parts of ammonia stabilizer.

The manufacturing process comprises the following steps:

s1, crushing the mineral soil, namely pouring the volcanic ash, the coal residues, the rare earth and the lime into a crusher to be crushed fully, wherein the crushed particles are controlled to be 0.12-0.15 mm;

s2, preparing a culture medium, pouring ammoniated bacteria, actinomycetes, azotobacter chroococcum, streptomyces jingyangensis, bacillus licheniformis, bacillus subtilis, trichoderma harzianum, bacillus mucilaginosus, bacillus coagulans and bacillus megaterium into the culture medium according to parts, fully stirring for 25min, continuously injecting a mixture of oxygen and nitrogen in the stirring process, feeding at the speed of 85ml/min, keeping the operation at normal temperature, and fully mixing the mixture with the mineral soil;

s3, mixing the microorganisms, mixing urease, phosphatase and dehydrogenase with the raw materials in the step S2, and feeding the mixture into a heat preservation box, wherein the temperature is controlled to be 65-72 ℃ and lasts for 6 hours;

s4, mixing, stirring and processing, namely mixing and stirring the raw material obtained in the step S3, polyglutamic acid, polyacrylamide, urease inhibitor and ammonia stabilizer, and keeping the temperature at 60-72 ℃ for 25min in the stirring process;

and S5, sterilizing, mixing the strips, sterilizing the materials, and standing for 10min to finish the processing.

In the step S2, the stirring speed is controlled to be 150r/min-280r/min during the stirring process.

In step S2, the culture medium is a mixture of distiller' S grains, vinegar residue, manioc waste, sugar residue, and furfural residue.

In step S2, the mixing ratio of oxygen to nitrogen was set to 1: 0.8.

In step S5, the sterilization method is ultraviolet sterilization.

Example 1

24g of volcanic ash, 28g of coal residues, 27g of rare earth, 3.5g of lime, 2.7g of urease, 6g of phosphatase, 3g of dehydrogenase, 6g of ammoniated bacteria, 6g of actinomycetes, 7g of azotobacter chroococcum, 4g of azotobacter chroococcum, 8g of streptomyces jingyangensis, 3g of bacillus licheniformis, 1.5g of bacillus subtilis, 1.2g of trichoderma harzianum, 1.4g of bacillus mucilaginosus, 2g of bacillus coagulans, 4g of bacillus megaterium, 5.5g of polyglutamic acid, 3g of polyacrylamide, 6g of urease inhibitor and 3g of ammonia stabilizer.

Firstly, crushing the ore soil, namely pouring volcanic ash, coal residues, rare earth and lime into a crusher for full crushing, wherein the crushed particles are controlled to be 0.12-0.15 mm;

then, preparing a culture medium, pouring ammoniated bacteria, actinomycetes, azotobacter chroococcum, streptomyces jingyangensis, bacillus licheniformis, bacillus subtilis, trichoderma harzianum, bacillus mucilaginosus, bacillus coagulans and bacillus megaterium into the culture medium according to the amount of g, fully stirring for 25min, continuously injecting a mixture of oxygen and nitrogen in the stirring process, feeding at the speed of 85ml/min, keeping at normal temperature, and fully mixing with the ore soil;

then mixing the microorganisms, mixing urease, phosphatase and dehydrogenase with the raw materials in the step S2, and feeding the mixture into a heat preservation box, wherein the temperature is controlled at 65-72 ℃ and lasts for 6 hours;

mixing and stirring the raw material obtained in the step S3 with polyglutamic acid, polyacrylamide, urease inhibitor and ammonia stabilizer, and keeping the temperature at 60-72 ℃ for 25min in the stirring process;

and finally, sterilizing, namely sterilizing the material after the belt is mixed, and standing for 10min after the treatment is finished to finish the processing.

Example 2

2g of volcanic ash, 3g of coal residues, 4g of rare earth, 1.8g of lime, 1.7g of urease, 2.5g of phosphatase, 1g of dehydrogenase, 2g of ammonifying bacteria, 3.5g of actinomycetes, 4g of azotobacter chroococcum, 1.5g of azotobacter vinelandii, 3g of streptomyces jingyangensis, 2g of bacillus licheniformis, 0.6g of bacillus subtilis, 0.5g of trichoderma harzianum, 0.6g of bacillus mucilaginosus, 1g of bacillus coagulans, 2g of bacillus megaterium, 4.5g of polyglutamic acid, 1.7g of polyacrylamide, 4g of urease inhibitor and 1.5g of ammonia stabilizer.

Firstly, crushing the ore soil, namely pouring volcanic ash, coal residues, rare earth and lime into a crusher for full crushing, wherein the crushed particles are controlled to be 0.12-0.15 mm;

then, preparing a culture medium, pouring ammoniated bacteria, actinomycetes, azotobacter chroococcum, streptomyces jingyangensis, bacillus licheniformis, bacillus subtilis, trichoderma harzianum, bacillus mucilaginosus, bacillus coagulans and bacillus megaterium into the culture medium according to the parts, fully stirring for 25min, continuously injecting a mixture of oxygen and nitrogen in the stirring process, feeding at the speed of 85ml/min, keeping at normal temperature, and fully mixing with the ore soil;

then mixing the microorganisms, mixing urease, phosphatase and dehydrogenase with the raw materials in the step S2, and feeding the mixture into a heat preservation box, wherein the temperature is controlled at 65-72 ℃ and lasts for 6 hours;

mixing and stirring the raw material obtained in the step S3 with polyglutamic acid, polyacrylamide, urease inhibitor and ammonia stabilizer, and keeping the temperature at 60-72 ℃ for 25min in the stirring process;

and finally, sterilizing, namely sterilizing the material after the belt is mixed, and standing for 10min after the treatment is finished to finish the processing.

In conclusion, the invention adopts various ores for combination, improves the mineral content, simultaneously can accelerate the decomposition of fertilizers in soil by various microbial enzymes of the celestial body, can enhance the activity of soil by adding various biological fungi, can integrally inhibit the activity of urease in soil and delay the hydrolysis of urea, and has simple processing method and environmental protection.

While there have been shown and described what are at present considered the fundamental principles and essential features of the invention and its advantages, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (8)

1. A mineral substance base fertilizer synergist with a soil improvement effect is characterized in that: the weight ratio of the components is as follows: 12-24 parts of volcanic ash, 13-28 parts of coal residues, 14-27 parts of rare earth, 1.8-3.5 parts of lime, 1.7-2.7 parts of urease, 2.5-6 parts of phosphatase, 1-3 parts of dehydrogenase, 2-6 parts of ammonifying bacteria, 3.5-6 parts of actinomycetes, 4-7 parts of azotobacter chroococcum, 1.5-4 parts of azotobacter chroococcum, 3-8 parts of streptomyces jingyangensis, 2-3 parts of bacillus licheniformis, 0.6-1.5 parts of bacillus subtilis, 0.5-1.2 parts of trichoderma harzianum, 0.6-1.4 parts of bacillus mucilaginosus, 1-2 parts of bacillus coagulans, 2-4 parts of bacillus megaterium, 4.5-5.5 parts of polyglutamic acid, 1.7-3 parts of polyacrylamide, 4-6 parts of urease inhibitor and 1.5-3 parts of ammonia stabilizer.

2. The mineral-based fertilizer synergist with a soil improvement effect according to claim 1, further comprising the following components by weight: 24 parts of volcanic ash, 28 parts of coal residues, 27 parts of rare earth, 3.5 parts of lime, 2.7 parts of urease, 6 parts of phosphatase, 3 parts of dehydrogenase, 6 parts of ammonifying bacteria, 6 parts of actinomycetes, 7 parts of azotobacter chroococcum, 4 parts of azotobacter chroococcum, 8 parts of streptomyces jingyangensis, 3 parts of bacillus licheniformis, 1.5 parts of bacillus subtilis, 1.2 parts of trichoderma harzianum, 1.4 parts of bacillus mucilaginosus, 2 parts of bacillus coagulans, 4 parts of bacillus megaterium, 5.5 parts of polyglutamic acid, 3 parts of polyacrylamide, 6 parts of urease inhibitor and 3 parts of ammonia stabilizer.

3. The mineral-based fertilizer synergist with a soil improvement effect according to claim 1, further comprising the following components by weight: 2 parts of volcanic ash, 3 parts of coal residues, 4 parts of rare earth, 1.8 parts of lime, 1.7 parts of urease, 2.5 parts of phosphatase, 1 part of dehydrogenase, 2 parts of ammonifying bacteria, 3.5 parts of actinomycetes, 4 parts of azotobacter chroococcum, 1.5 parts of azotobacter vinelandii, 3 parts of streptomyces jingyangensis, 2 parts of bacillus licheniformis, 0.6 part of bacillus subtilis, 0.5 part of trichoderma harzianum, 0.6 part of bacillus mucilaginosus, 1 part of bacillus coagulans, 2 parts of bacillus megaterium, 4.5 parts of polyglutamic acid, 1.7 parts of polyacrylamide, 4 parts of urease inhibitor and 1.5 parts of ammonia stabilizer.

4. The preparation method of the mineral-based fertilizer synergist with the soil improvement effect as claimed in claim 1, wherein the preparation process comprises the following steps:

s1, crushing the mineral soil, namely pouring the volcanic ash, the coal residues, the rare earth and the lime into a crusher to be crushed fully, wherein the crushed particles are controlled to be 0.12-0.15 mm;

s2, preparing a culture medium, pouring ammoniated bacteria, actinomycetes, azotobacter chroococcum, streptomyces jingyangensis, bacillus licheniformis, bacillus subtilis, trichoderma harzianum, bacillus mucilaginosus, bacillus coagulans and bacillus megaterium into the culture medium according to parts, fully stirring for 25min, continuously injecting a mixture of oxygen and nitrogen in the stirring process, feeding at the speed of 85ml/min, keeping the operation at normal temperature, and fully mixing the mixture with the mineral soil;

s3, mixing the microorganisms, mixing urease, phosphatase and dehydrogenase with the raw materials in the step S2, and feeding the mixture into a heat preservation box, wherein the temperature is controlled to be 65-72 ℃ and lasts for 6 hours;

s4, mixing, stirring and processing, namely mixing and stirring the raw material obtained in the step S3, polyglutamic acid, polyacrylamide, urease inhibitor and ammonia stabilizer, and keeping the temperature at 60-72 ℃ for 25min in the stirring process;

and S5, sterilizing, mixing the strips, sterilizing the materials, and standing for 10min to finish the processing.

5. The method of claim 4, wherein in step S2, the stirring speed is controlled to 150-280 r/min during the stirring process.

6. The method of claim 4, wherein in step S2, the medium is a mixture of distiller' S grains, vinegar residue, cassava residue, sugar residue, and furfural residue.

7. The method of claim 4, wherein the mixing ratio of oxygen to nitrogen is set to 1:0.8 in step S2.

8. The method of claim 4, wherein the step S5 is carried out by UV sterilization.

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