DE2815181A1 - BIOLOGICAL THINNERS AND METHOD FOR ITS PRODUCTION - Google Patents

Description

PATENT LAWYERS

PROF. DR. DR. J. REITSTÖTTER

DR.-ING. WOLFRAM COLORFUL 2815131

DR. WERNER KINZEBACH

BAUERSTRASSE 22. D-BOOO MUNICH 4O ■ FERNRUF (O89I 37 65 S3 ■ TELEX S2I52O8 ISAR D POSTAL ADDRESS: PO Box 78O. D-BOOO MUNICH Λ3

5-

Munich, April 7, 1978! M / 19 071

MIZRAIM AKTIENGESELLSCHAFT
Moors / Liechtenstein

Biological fertilizer and method to |

its manufacture ί

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The invention relates to a biological fertilizer and a method for its manufacture.

Preservation and care of the soil as the basis of agriculture used to be almost exclusively on European ones However, countries where the soil has been the subject of generally intensive development is nowadays restricted also the subject of increasing attention in countries with typical extensive agriculture. Numerous, generally similar problems give rise to endeavors in many places be undertaken to cultivate wasteland and desert soil or to recultivate wasteland. Indispensable requirement for survival in different geographical situations, nen is the sufficient quantity and quality of an organic and microbial component in the soil, which is generally known as humus. Humus represents the component that the physical, chemical and biological properties of the earth harmonized. These factors are essential for planting and plant growth necessary. In this regard, the humus leads to the following effects: (a) It increases the cohesion of the soil particles and. j their ability to absorb and retain precipitates. The physical-mechanical structure of the ! Affects the soil and the washout effect of the water, as well

reduces erosion caused by atmospheric agents; (b) it enables the soil to grow together and is responsible for ion exchange phenomena, whereby the accessibility of the nutrient elements is regulated which are necessary for the growth and yield of plants, whereby an improved utilization of the nutrient elements is supported at the same time; (c) it maintains, modulates and conditions j the development and activity of the soil microflora, which is one of the fundamental parameters of soil fertility

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represents; (d) it neutralizes or weakens the inhibiting ones ; antimetabolic or toxic effects of inorganic or Ί organic substances that occasionally or systematically! lead to poisoning of the soil; (e) it stimulates the resistance of higher plants to unfavorable atmospheric conditions, to parasitic, endomological and fungal infestations. At the same time, the presence of humus leads to a coordination of the various biochemical effects of the tellural microflora, which is known to be responsible for the natural cycle of materials and consequently, in the edaphic medium, the conversion of nitrogen, carbon, phosphorus, sulfur and other compounds with biogenic elements, which are the nutritional basis of the higher plant life. This can lead to an enrichment of biologically active substances (for example phytohormones), which can be processed by many soil microbes and released in the medium, thereby directly influencing the plant physiology.

Although manure matured over thousands of years,. which has been suitably applied to the ground, the Source of humus and useful microorganisms for the-traditional Agriculture is represented nowadays by the changing demands on agriculture, especially as Result of the division into cultivation and livestock farms with the subsequent mechanization of agriculture, - "stable fertilization" no longer available for the fields. On the other hand, the accumulation of large amounts of liquid and solid excrement results in contributes to considerable problems for intensive livestock farms their elimination.

In addition to all of this, there is the fact that the uninhibited The use of inorganic fertilizers for a time

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has led to increased production, but to an impoverishment of larger ones Agricultural land has led to a disproportionate amount Use of pesticides and a reduction in the organic quality and nutritional value of the Crops and their usability. At the same time, however, it is impossible to meet the urgent needs of the farmers' by providing organic fossil substances (e.g. peat or young lignites or their derivatives) to be satisfied because these are only accessible in limited deposits and only in certain geographical areas and in addition, even without precisely those microbes are whose biopedological Effectiveness made these substances particularly interesting. Just as little can all those substitute products of manure, those by converting agricultural by-products are obtained (which, moreover, are only accessible in small quantities and generally require very long periods of time, until a satisfactory conversion to fertilizer has taken place) or substitutes from solid urban waste, such as' for example common composts to solve the fertilization problem.

In particular, the latter fertilizers, which are produced by processes with the main purpose of eliminating waste too often have proven to be devoid of any fertilizer ability or have even resulted in damage to the harvest and, in many cases, contaminate the soil with inert or dangerous foreign objects.

The invention is based on the object of creating a biological fertilizer and a method for its production. It in particular, a fertilizer is to be created that is made from abundant materials and which is free from the disadvantages outlined above with regard to biological usefulness and accessibility.

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This problem is solved by the teaching of the claims.

According to the invention, a method for producing a biological fertilizer created in which the considerable Amounts of organic substances used in solid waste, in urban sewage and in residues from agricultural and animal production processes, food production processes and pharmaceutical processes, and the like are included. The method according to the invention leads to a simple and economical way biological, organic, mixed organic and humomineral Fertilizers that are extremely valuable in soil treatment and, surprisingly, of the most varied Meet the requirements of agricultural technology.

The method according to the invention is not limited to a significant progress in the field of manufacturing mixed To create fertilizer, it also solves the problem of waste disposal, which is becoming increasingly important and its previous attempts at solutions in one way or another Were unsatisfactory.

The systems currently used to remove waste are of dubious value. They can be summed up as follows: (a) Contacting in blocks, e.g. for building purposes; the contact has the consequence that the biogenic elements that make up the organic residues, and which by their nature belong to the biosphere are removed from the natural cycle; (b) Methods that the return the biogenic elements mentioned to the biosphere by incineration, but in less suitable forms and under Use of systems which are expensive to build and operate and which are often only good for the ones that arise Reduce the amount of waste, but not remove it;

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(c) the dumping of waste in natural or artificial areas, E.g. river beds that are literally lost as a result and always be a source of environmental damage;

(d) Composting methods, their application either to crushing, stabilizing and partial drying of the waste! or is limited to a certain degree of conversion, whereby this conversion essentially relates to those constituents: parts is limited to the easiest of the microorganisms are metabolized, yielding products that do not have any or only have a low agronomic value; (e) procedure, in which certain forms of energy or metabolic products (e.g. methane, hydrogen, alcohol and the like) are withdrawn, these processes are very expensive and give only low yields.

In comparison with all these known systems, the method proposed here is more rational and in every respect ! cheaper.

! The method of the present invention for making mixed fertilizers comprises the following essential stages:

1. Organic waste materials of any origin, size and Composition which, however, is prerequisite that they can be attacked by microbes, for example solid urban waste, canteen waste, sludge from water purification plants, vegetable residues, agricultural or animal by-products or by-products of agricultural, Food engineering or pharmaceutical industries, and the like, are used alone or preferably in admixture with inorganic substances or inert materials of acceptable composition independently of their particle size and nature into one suitable device fed to a first, controlled

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ι 'perform biological conversion. The composition of the raw material only has to be included - preferably with the help of suitable mixtures of different waste _; be adjusted to: (a) bring the mean humidity to 45 to 60%; (b) the pH of the medium (in aqueous '; suspension at a 1:25 weight / volume ratio sawn' \ true) to 4 to 8.5 to bring; (c) Bring the carbon / nitrogen ratio to 25: 1 to 35: 1. Only in the very special cases in which organic residues with a low or no microbe content are used is it necessary to mix with other residues with a high microbe content. At this initial stage, no comminution or sorting of the large lumpy inert materials is required, since their presence can surprisingly be used to ensure optimal oxybiotic and anoxybiotic conditions in the fermenting mass. The recovery of economically important materials (e.g. metals, glass and the like) that may be present in the waste is usually (with the exception of cases where special requirements exist) postponed to later stages, in which their separation from the mass is much easier . One of the critical aspects of the cycle in the process according to the invention is to be seen in the fact that the raw material is to be prevented from reaching a steady state because spontaneous fermentation then occurs. The raw material must therefore immediately go to the conversion stage. This must be done in a location that is protected from atmospheric precipitation and before any undesirable fermentation has set in to any appreciable extent.

The first controlled biological conversion takes place in a device that circulates the material and what is inside it Breaks up clumps to ensure that the

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aerobic and exothermic fermentation predominates. This process j is usually carried out in suitable rotary fermentors; led, if necessary with internal elements and; Openings for loading and unloading and for the safest possible ·. ventilation. In the specific cases in \ which is compact the material excessively, the ventilation may: take place in that one arranges devices for controlled air blower.

According to the invention, however, it has been found that in most cases the oxygenation of the mass by natural diffusion. can be done. This is a simple consequence of the circulation process; ganges. In this respect, the transformation must be predominant! Be aerobic, but avoid excessive ventilation as this leads to rapid mineralization of the more easily metabolized organic substances. This would lead to a sudden increase in temperature with a corresponding "stabilization" of the mass. This would give products that are only slightly converted and not moistened at all. In this stage the ventilation is regulated by allowing the circulation processes to alternate with static phases in a suitable manner. This leads to temperature profiles which simplify the recovery of the fermenting mass and facilitate the selection of the humus-forming microflora. It is clear in the course of 3 to 4 days (for example, in the case of solid urban waste) is a constant rise in the temperature of the mass, .the 65 to 68 ⁰ C reach must to the disappearance of ineffective microbial agents, insect eggs and larvae. to secure from parasitic cryptogams, seeds and undesirable grass varieties. This first stage _9, in which the first effective attack on the organic substance is controlled in a suitable manner, is terminated from a technical point of view when the temperature rise does not exceed

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10 ⁰ C in the 24 hours after the maximum temperature has been reached.-At the same time, the pH of the medium stabilizes in the area of the neutrality point, and despite evaporation losses during the conversion, the moisture content is equal to the initial content, due to the amount of water that differs from the microbial effect on the organic components.

Under these conditions, the material is discharged from the fermenters and fed directly into the second conversion stage.

If indicated, crushing or metal reclamation can be used and the removal of inert material can be carried out after this first fermentation step. For these operations machines are available that work satisfactorily! and do not cause any particular problems. j

2. The second controlled biological conversion stage takes place, when the material is piled up. The piles must be made shielded from atmospheric precipitation will; their surface should be minimal.

In this stage the flikroflora leads their selection was favored, to an intensification of the conversion of the organic substance and that by new exotherr me reactions that lead to a further increase in the temperature of the mass. This is constantly monitored by instruments Rise is followed, after a few days, by a drop in temperature, when the occurrence of which causes the heap to tumble or turned upside down and with a mechanical shovel or other suitable device ensuring perfect uniformity results to be formed anew. As with education

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of the initial pile, turning the pile over leads to a further increase in the temperature of the mass. The more \ Treatment of the heap is as indicated above and carried out until the ■ occurring during inversion temperature rise reaches a limit ι which is substantially lower than that in the preceding cycle (for example, 5 to 1O ⁰ C). Then the second stage \ is finished. I.

The first biological conversion stage is carried out by adding a culture of microbes suspended in a liquid medium while further inverting the heaps. Instead of using cultures from collections or from commercial inoculations, cultures are used isolated from the actual fermentation mass or were selected. This is how one makes of the scientific Properties of the phytogeographical and ecological distribution of microorganisms use.

The culture to be used is among thermophilic species selected against the most important forms of organic substances (cellulose, starch, gelatin, proteins and the like) have an intensive degradation activity and thus have the ability to form humus. It should also be checked that the selected strains compared to the main microbes of bio-pedological interest have no antagonistic activity.

The third stage of conversion is the same as for the second stage specified, controlled by looking at the temperature profiles of the monitored masses accumulated and checked the C / N ratio from time to time. The conversion is complete when this relationship is stable.

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'4. The material, heavily converted into humus, rich in micro-. benz cells and products of their activated metabolism is, ■ is subjected to a first comminution process and a sieving operation (or a further comminution; operation and a further sieving operation if the first crushing operation and the first sieving operation "; already carried out after the fermentation stage), I thereby obtaining a sieved product having an arbitrary j has adjustable particle size distribution. This product represents an excellent "biological organic j Fertilizer "as soon as it has been suitably dried. ■: Should it be necessary to obtain the |. Add fertilizer with bio-pedologically effective microorganisms! enrich, according to the knowledge according to the invention, is the fertilizer an optimal substrate for the growth of the following microorganisms: Azotobacter chroococcum, Az. vine! andii, Az. Päspali, Rhizobium leguminosarum, Rhiz. japonicum, Beijerinckia indica (in this case after suitable acidification of the medium), Arthrobacter globiformis, Bacillus megaterium and Bac. circulans. The new invention Fertilizer is therefore an excellent vehicle for delivering the mentioned microbial species to the soil. around the soil with free nitrogen-fixing microorganisms, like Azotobacter chroococcum, vinelandii etc., with symbionts like Rhizobium leguminosarum, japonicum, lupini, melitoti, trifolii, phaseoli etc., with tribasic phos -.- phat-s-ol ubilizing microorganisms, such as Bacillus niegaterium, with SiI i kat-solubilizing microorganisms, like Bacillus circulans, or with strong producers of Phytohormones such as Azotobacter paspali, Arthrobacter globiformis, to provide. The biological, organic, rich in usable microorganisms produced in this way Fertilizer, or the initial biological, organic If necessary, fertilizers can be mixed with inorganic fertilizers

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can be enriched to form a complex, mixed organic fertilizer.

Alternatively, the humus mass obtained by the four-step process described here can also be used to produce humo-mineral fertilizers directly or after a further ripening period be used. For this purpose, the humic acids that have accumulated in the mass during the transformation are suspended extracted in an alkaline solution, the slurry then being centrifuged or filtered through non-absorbent materials are separated from the extract and then the exhausted sludge is re-cycled is entered.

The humic acids are obtained from the extracts by flocculation with acids and subsequent decanting, filtering or Centrifugation and subsequent salt formation with alkalis, using the bases of the cations contained in the final product until the medium is neutralized.

The so obtained humo-mineral preparations can be used as concentrated solutions or after drying by spray drying, freeze drying or any other System that does not lead to the denaturation of the molecular structure of humic acids can be brought onto the market.

The following examples are intended to explain the invention in more detail without restricting it.

Example 1

The method described is applied to a mixture of household and street waste from Naples (Italy) with the following percentage composition of: inorganic residues (Stones, debris, dust): 14.5; organic vegetable,

animal and food scraps: 46.5; Paper and cardboard: 19.8}

Metals: 3.8; Glass and Ceramic Material: 4.0; _Textiles:

2.0; Wood: 0.9; Plastics, rubber and skins: 4.5; different-! ner drop: 4.0.

Moisture content: approximately 52 %; pH = 6.6; C / N ratio j approximates 32.

The materials are put into one without any adjustment Rotary fermenter entered with a hexagonal cross-section, on two non-contiguous sides with openings is provided for loading, unloading and ventilation and has the strong metal 1 elements, which are arranged transversely inside are to reduce the crushing and mixing action during circulation to increase. Immediately after loading, the device is powered by an electric motor with the doors closed moved with 4 lipm for 30 minutes.

The following scheme of work is carried out for 4 days:

6 rotation periods of 30 minutes each, interrupted during each j day by 2-hour waiting times with the doors open, whereby the entire system is kept stationary with the doors open during the night. During this process, which is the first stage of the controlled biological conversion, there is frequent monitoring. The temperature during the first day increases from ambient temperature (13 to 14 ⁰ C) to 18 to 2O ⁰ C to. In the morning of the second day lies

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the temperature at 32 C and at the end of the second day at 30 C. On the morning of the third day it is 58 ⁰ C and at the end of the third day at 38 ⁰ C. On the morning of the fourth day the temperature is 68 ⁰ C, am At the end of the fourth day it is 43 ^° C. In the morning of the fifth day it is 53 ^° C. The pH of the mass drops to 5.6 after the first day, after the second day it is 5.8, after the on the third day it is 6.5 and after the fourth day it stabilizes in the area of neutrality, ie at. pH 6.8 to 7.2. The moisture content remains practically constant. Micrological, microbiological and microscopic analyzes show the disappearance of insect eggs and larvae, phytopathogenic fungi such as Fusarium, protozoa such as Entamoebe hystolytica and pathogenic microorganisms such as Salmonella typhi, S. paratyphi, Shigella disenteriae, after the 4-day fermentation. Pasteurella typhimurium, Brucella melitensis, Mycobacterium ■

; tuberculosis, Corynebacterium diphteriae and Staphylococcus, ! aureus, on. The fecal streptococci and fecal colonic bacteria I.

, like Platelminti and Nematelminti, are also absent.

After discharging, ferromagnetic materials are separated by electromagnets. Then be under a suitable one Protective roof pile formed. A self-propelled device is used to make the pile, which is attached to the plant is widely used by edible mushroom cultures, with Few small modifications can be made and the ability the device for making heaps with an approximate parallel elepiped shape with a height of approximately 1.80 m, a width of about 2 m and virtually any desired length can be used. With this device can many piles close together to perform the process using a smaller area. The temperature profiles of the ripening masses indicate that the heaps should be turned every 5 days. After the third

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The masses are turned with a culture broth from one th'ermophi Ten Actinomyceten, which is capable of humus formation and which was previously isolated from the masses themselves, watered (to the extent of 1 liter per 100 kg of material).

The culture broth is in the form of a starch-casein broth (according to Waksman and Lechevalier, 1961 "The Actinomycetes", Wi11iam & WiI kins Co., Baltimore). Incubating approximately 36 hours at 5O ⁰ C under aerobic conditions, in the course of the subsequent 6 to 7 days, the C / N ratio of the masses stabilized around a value of 21.5. The material is then comminuted in a hammer mill and then sieved through a vibrating sieve machine with openings of 1 cm 1 cm.

A portion of the sieved product is subjected to natural drying (down to a moisture content of about 20 % ), whereby a fertilizer is obtained which is useful as such. This biological, organic basic fertilizer is obtained in a yield of approximately 70 % of the raw material. It has the following characteristics: pH 7.5; Moisture content 19.8%; Ash 31 t \ organic matter 46.3 %, C / N ratio approx. 21; total nitrogen 1.5%; Phosphorus 0.45%; Potassium 0.95 %; Total calcium 3.5 %; Chlorides 0.05%; Sulfates 3.05%; Total sodium 0.3 % \ total magnesium 0-75 %; Total iron 1.54 t \ aluminum 3.25 % \ silicon 5.2 % \ total zinc 0.1 1; Total copper 0.01 % \ manganese 0.01 % \ molybdenum 0.2 ppm; Cobalt 1.8 ppm; Nickel.1.8 ppm; entire microbial

9
loading 6 χ 10 microns / g; Total number of thermophilic microbes

α 8

1.2 10 microbes / g; Actinomycete loading 5 χ 10 micro-

ben / g; thermophilic actinomycetes 4.1 10 "microbes / g; eumycete loading 9 10 microbes / g; aerobic nitrogen-fixing Microbes 9.5 10 microbes / g; anaerobic nitrogen-fixing Microbes 5 × 10 microbes / g; proteolytic microbes 1 χ 10

Microbes / g; ammoniating microbes 4.5 10 microbes / g;

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nitrosating microbes 8 10 microbes / g; nitrifying Microbes 7 10 microbes / g; the "trifying microbes 1.5 χ

3 8

10 microbes / g; amyiotic microbes 5 × 10 microbes / g; pectinolytic microbes 6 × 10 microbes / g; aerobic cellulosolytic Microbes 4 × 20 microbes / g; anaerobic cellulosolytic

3
see microbes 8 10 microbes / g; Total number of colonic bacteria

1 10 microbes / g; fecal colon bacteria absent; fecal streptococci absent. The product is also found to be free from the aforementioned pathogenic products. It shows against phytohormones such as auxins, gibberellin and cytochinins in extracts obtained from only 100 g, a biological activity.

The biological, organic fertilizer with the above characteristics is partly used as a basis for the production of complex organic, heavy fertilizer is used by mixing with complex inorganic fertilizers of the types 10:10:10 and 11:22:16.

Another part of the biological, organic basic fertilizer is divided into portions and mixed with a culture broth of Microbes such as Azotobacter chroococcum, Rhizobium legaminosarum and Rhizobium japonicum, enriched.

Finally, in order to produce humo mineral fertilizers, the converted masses not used for the above products are suspended in n / 10 NaOH and vigorously stirred for 30 minutes. The extract is separated off by centrifugation and. the solid phase is suspended again in alkali, the extraction being repeated four times. Then the humic acids are flocculated from the combined extracts by acidifying with HgPO ^ (this method gives phospho-humic acids with no less than 7 % phosphorus). The flocculate is separated off by filtration and redissolved by neutralization with various bases. In this way, for example, ammonium

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\ phosphohumate, potassium, calcium, iron III phosphohumate, and animal like. With these products one can produce suitable mixtures with thin properties. The dry weight yield of these humomineral products is in the order of 17 to 18 % of the minerals that are extracted! became. These products are also dried by spray drying, giving 99.9 % water-soluble powders, which are therefore very suitable for fertilization by irrigation and for fertilizing hydrophonic crops. !

At s ρ i e 1

The method described is applied to solid urban waste from Naples (see example 1) and drained sludge that comes from a biological sewage treatment plant and has the following physical-chemical characteristics: moisture 68%; organic carbon 31 %; Total nitrogen 3.8%; total phosphorus 1.46%; total potassium 0.19%; pH 7.9. Waste and sludge are used in a ratio of 4: 1 parts by weight. The process is not affected at any stage, in fact it increases Yield of biological, organic fertilizer to 79 % of the total raw material used.There is also a substantial increase in the yield in the production of humo-mineral fertilizers, which are in the form of a powder in an amount of 19.8 % of the mass converted into humus and extracted can be obtained.

Be is ρ i el

One applies the method described on solid urban Waste from Naples (see example 1) and the continuous Centrifugation of wastewater from a pig rearing

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j \ intensive care unit received solid phase with the following

Features: humidity 71%; organic carbon

j holds 23%; Total nitrogen 3.9 % \ total phosphorus 1.8 %; j total potassium 4.5%; pH 8.0.

The waste and the product from the waste water are used in a ratio of 5: 1 parts by weight. The process is not affected at any stage by the addition of the product from the wastewater. As in the previous example, the yields increase compared to Example 1 and are 76 % for the biological, organic fertilizer and 20% for the humo-mineral fertilizer.

example

The method described is applied to solid urban waste from Naples (see Example 1) for the sole production of biological, organic fertilizers. In this case, the procedure described in Example 1 is followed, but the masses obtained after the third biological conversion stage are crushed in a hammer mill and sieved through a vibrating sieve with mesh openings of 1 cm χ 1 cm and finally the sieved product is subjected to natural drying. For this purpose, the sifted product is stored under a cover in layers with a height of 50 cm and turned daily until a moisture content of not more than 20 % is reached.

example

The method described is applied to solid urban waste from Naples (see Example 1) in order to exclusively

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\ gic, organic fertilizers to which one can produce inorganic complex fertilizers with different nitrogen, phosphorus and adding potassium levels. In this case you obey the procedure of Example 4, but still more comminuted and a vibrating sieve with the sieving operation Mesh sizes of 0.7 cm χ 0.7 cm are used. You drain that sifted product and adds commercially available inorganic complex fertilizers in suitable powder mixture; so "mix · ^ organic complex fertilizers "with fixed nitrogen, phosphorus and potassium concentrations.

example

The method described is applied to solid urban waste from Naples (Example 1) in order to produce only organic, biological fertilizers enriched with microorganisms belonging to different physiological groups. Using the Rhizobium japonicum species, a nitrogen fixing species that is a specific symbiont of soybean plants (Glycine hispidia), the procedure of Example 4 is followed. However, after sieving, the material is watered (using 1 liter / 100 kg) with culture broth of strain No. 11927 of the American Type Culture Collection (Rockwille, Maryland, USA) of the specified species. This culture broth was in the course of 48 hours at 30 ⁰ C in Wright's substrate (sodium chloride 0.2 g; biammonium phosphate 0.5 g; magnesium sulfate 0.3 g; calcium sulfate 0.1 g; calcium carbonate 0.1 g; mannitol 10 g; yeast water 100 ml; water 900 ml). After the subsequent drying as described, the material has a Rhizobium content of not less than 1 × 10 cells / g. This can be used to effectively initiate nodulation in soybean plants.

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Claims (1)

Claims Biological fertilizer, obtainable by full use; generation of solid urban waste and organic waste products, each of which can be attacked by microbes; where one (a) the waste material, which has a pH of 4 to 8.5, a
Humidity of 45 to 60% and a C / N ratio i of 25: 1 to 35: 1, before the start of a spontaneous! tanen fermentation in a device for circulating; and natural aeration of the mass avoiding compaction by cessation of diffusion aeration with a gradual increase
biologically converts the temperature to 65 to 68 ⁰ C, ■ the treatment continues until the pH stabilizes around the neutrality point and within 24 hours after reaching the maximum temperature
not contain more than 1O ⁰ C on the measured at the same time in a preceding cycle Tempe-i rature increases; j (b) the partially fermented materials on the free
Air, protected from atmospheric precipitation in the form of heaps, which are rearranged and newly formed each time after a temperature drop following an initial temperature rise, fermented further, the fermentation then being terminated see if the is on repackaging a pile
following temperature rise 5 to 1O ⁰ C ι
Is the increase in the previous cycle; the following temperature rise 5 to 10 ⁰ C lower than that ^: 8098 4 2/0904 M / 19 071 (c) and finally the materials from step (b) are subjected to a further biological fermentation which ■ by adding one from the under fermentation; borrowed mass of selected and isolated microbial culture! is stimulated, the process up to stabilization; sization of the C / N ratio is continued. A method of making the biological fertilizer of claim 1 using all of the solid urban waste and organic waste products, respectively can be attacked by microbes, characterized in that: (a) the waste material, which has a pH of 4 to 8.5, a humidity of 45 to 60 % and a C / N ratio of 25: 1 to 35: 1, prior to the start of a spontaneous fermentation in an apparatus for Circulation and natural aeration of the mass avoiding contact by setting the diffusion aeration with a gradual increase in temperature to 65 to 68 ⁰ C, the treatment continues until the pH stabilizes around the neutrality point and within 24 hours ! after reaching the maximum temperature this does not! increases more than 1O ⁰ C on the measured at the same time in a previous cycle temperature; (b) the partially fermented materials in the open air, protected from atmospheric precipitation in Form of piles, each time after a temperature drop leading to an initial temperature rise follows, restructured and newly formed j further fermentation, the fermentation is then to be regarded as ended when the rearrangement of a heap 809842/0904 M / 19 071 -X- ! the following temperature rise is 5 to 10 ⁰ C lower than the rise in the previous cycle; . (c) and finally the materials from step (b) one; subject to further biological fermentation, which by adding one of the fermentation-under-fermentation Mass selected and isolated microbe culture.stimu-; is lated, the process until stabilization;. the C / N ratio is continued, j 3. The method according to claim 2, characterized in that ι a thermophilic species is used as a microbial culture in stage (c) uses, which see against the main constituents of the organic substances, especially against cellulose, starch,] Proteins, pectins, uplifting! I have degradation properties based on j shows. . - 4. The method according to any one of claims 2 or 3, characterized in that there is between the first and second fermentation stage insert a work step for the removal of metals and inert materials. 5. The method according to any one of claims 2 to 4, characterized in that that the fertilizer obtained is enriched with bio-pedologically effective microorganisms and, for this purpose, ; special nitrogen-fixing microorganisms, symbionte Nitrogen-fixing microorganisms, silica-solubilizing ones Microorganisms, three basic phosphates-solubilizing Microorganisms and phytophormones-producing Microorganismsj used. 6. The method according to any one of claims 2 to 5, characterized in, that the fertilizer obtained is mixed with an inorganic fertilizer. 809842 / 09Ö4 M / 19 071 - / - 7. The method according to any one of claims 2 to 6, characterized in that that the fertilizer obtained is extracted by suspension in an alkaline solution, the extracts flocculates with acids and converts the precipitated humic acids into salt form with one or more alkalis. 809 ^ 42/0904