DE923791C - Process for the manufacture of soil improvers - Google Patents

Description

Process for the production of soil improvers That already more than 60 years ago first by Berthelot, then by Winogradsky, Beij e r i n k, Hellriegel etc. have shown that the Gare of the arable land mainly due to the balance of the microorganisms it contains is and that fertilizers and manure less the growth of higher crops rather than the balance and flow of the effects of microbes in the soil influence. The higher cultivated plants only utilize the products and excretions of the lower living beings.

When the experiments were continued, it was found that at the moment. in which a living cell is destroyed, solid, liquid, gaseous or ionized Substances arise, and it appears as if certain of these substances stimulate the creation, maintenance or development of the life of other cells or should support, while energy, such as, for example, in the form of potential, thermal, electrical, electromagnetic, chemical, phototonic, cosmic Radiant energy and the like., Is provided.

It has now been found that the breakdown of a living cell by chewing or mechanical rubbing as a result of some type of mechanical cracking a change the chemical nature causes, whereby biotic factors such as Growth factors, become free. Therefore, for the production of the soil improvers according to the present invention green plants that have previously been triturated or mechanical chewing was used. By rubbing or chewing it in organic cell substances of green plants the biotic factors, such as growth factors.

It was also found that in the soil, mainly in the first 15 to 20 cm deep, certain substances must be present in an assimilable state and that these substances are in a certain proportion to the amount of the assimilable Carbon as it is present in the organic matter of the soil must be.

For example, one can say that for sugar plants of the type Sugar beet is the ratio between assimilable boron and assimilable carbon at roughly 85o to 90o per million, the ratio between manganese and assimilable Carbon at around 5o and 6o per million and the ratio between cobalt and assimilable carbon must be about 5 to 10 per million; For plants containing starch, glue or cellulose, the three aforementioned are available Ratios correspond to about 65o to Zoo, from 3o to 40 and from io to 12 per million.

It was also found that a product did not get through the plants is assimilable if it is oxidizable. The influence of the redox coefficient can be seen from this or the rH and the importance of its maintenance as well as the importance of a by maintaining a certain content of rubbery polyuronides in the soil and developing the bacteria and protozoa in the soil; because these bacteria and protozoa occur in the fluid of the rumen contents of ruminants (the also build proteins directly from urea, but always in the absence of light can), such liquids are used according to the invention.

It was also found that there is a need to assimilate a product To facilitate for the plants is useful, with this one static, negative Maintain charge that facilitates the binding of the metallic coenzymes.

Based on these findings and observations, the Invention aimed to stimulate, maintain and develop life to be realized in the soil and using the soil improver according to of the present invention to enable its regeneration.

So the invention has the manufacture of a product for improvement of soils to the subject, the balanced biotic factors and contains selected cultures of microorganisms, the whole in a nutrient medium and energy medium is present, which is a vigorous proliferation of said microorganisms and especially the zymogens. It has been found that the solid and liquid Fractions of the rumen contents of animals facing vegetable materials in green Condition and various mineral substances, such as potash salts, and possibly mineral colloids as well as bacterial cultures are added, a regeneration of the soil to which they are added by placing a physico-chemical in it and create biological equilibrium that has not yet been achieved by any known, simple or complex soil improver could be achieved.

It has been suggested for the manufacture of soil improvers and fertilizers to use organic and / or mineral substances to which certain Bacteria and also certain colloids were added. However, there is still no procedure known for the production of a soil improver in which organic materials, mineral materials, bacteria and mineral colloids used together and in which, among other things, in particular the rumen content of ruminants, the half-digested feed, which has a great regenerative capacity for the soil own, and in addition to other bacteria in particular bacteria of the Actynomycete type contains, is processed.

According to the invention, the rumen content of ruminants (slaughtered animals) squeezed to separate the liquid contained therein from the solid parts, and plants in the green state are crushed to remove the liquid contained in them separated from the solids. Then the separated substances (liquids and solids) preferably for several days in cold and dark chambers Aging, then the solid products mixed with crushed trace elements and Phosphates and adds the mentioned fluids from the rumen contents and the greens Plants added.

In addition, zymogenic cultures can be added to the separated products which are essentially composed of nitric acid and nitric acid ferments, Cellulose ferments and in particular actynomycetes, thermophilic bacteria, obligocarbophils Put together bacteria, sulfobacteria and ferrobacteria.

The preferred trace elements are silicon, carbon, boron, Cadmium, Magnesium, Titanium, Molybdenum, Zinc, Iron, Manganese, Sulfur, and Tungsten Cobalt, either some or all of them, in a colloidal state added.

In a preferred embodiment of the invention, this takes place Production of the soil improver in several stages, the in one The products obtained in the first stage are used for the partial preparation of the following stage.

The individual components of the soil improver according to the invention can be used, for example, in the following amounts approx. 30% raw rumen content of ruminants, 10 to 15% green herbs or grasses, 2o to 2.5% straw, 5 to io% calcium carbonate, 9 to i% phosphates, q. up to 5% dry Earth, 2 to 3% starch, 2 to 3% potash salts, 3 to, 4% natural manure, 0.7 to i% animal excrement, 0.4 to 0.6% colloidal trace elements and 0.2 to 0.4% Cultures of microorganisms.

Finally, soil worms can also be added to the soil improvers or eggs from ground worms are added.

The microorganisms selected according to the particular requirements come especially from microbial cultures that have previously been produced in the laboratory became. They are then united in such a way that they work together and support themselves to the crop yields of higher plants, which one is under regeneration of the cultivated soil to be increased to the maximum.

Since the aerobic microorganisms have a characteristic color, it seems that their more or less important activity is similar to a phenomenon depends on photosynthesis.

It was found that among the microbial cultures produced in the laboratory those that are particularly suitable for soil improvement, from zymogens are formed. For example, without any intention of limitation, Mentioned the following: A. Bacteria that fix molecular nitrogen. like Azotobacter, which release ammonia by fixing molecular nitrogen, especially there the products which they can oxidize dilute and those due to a diastatic Phenomenon work in the way. that they increase the content of husk-nut substances. Also to be mentioned is Clostridium, the molecular nitrogen without exposure of Fixed ammonia.

The Azotobacter and Clostridium species require carbonaceous ones Substances in the presence of calcium, potassium, sulfur (especially for Azotobacter, Iron, Magnesium, Molybdenum, and Tungsten to develop. While the Azotobacter species Clostridium species cannot reduce nitrates.

B. Ammonia-oxidizing ferments, formed by the nitrite and nitrate ferments, like nitrodomas and nitrosocysts on the one hand and nitrobacter on the other hand, all of them in the presence of calcium, silicon, manganese. Sulfur and the like require a lot of oxygen.

C. The cellulose degrading ferments, e.g. B. certain cellulolytic Species, certain fungi and actynomycetes (Penicillium, Phytomyces, Proactinomycetes), which attack the cellulose and cause it to undergo a fermentation that causes the Is the result of a synergistic effect in all microbial cultures. One can find that the fungi and the Actynomycetes are especially in the presence of Straw multiply and that they use carbonaceous products and products for their development need a lot of assimilable nitrogen and assimilable phosphorus.

The main characteristics of the microbial cultures were briefly presented enumerated, primarily in the production of the soil improver according to the invention play a role in making choices about the main components of the nutritional and energy medium that corresponds to the different cultures, to make it easier to understand.

It should be noted that the ability to fixate and the ability to restore vary according to the coloring, which in turn depends on the lesser or greater exposure to light varies, according to the Property of light and also corresponding to the effect of invisible radiation.

The soil improver according to the invention essentially comprises especially with the cultures of molecular nitrogen-fixing bacteria and products half-digested by cellulose ferments obtained from the rumen contents of ruminants originate (especially from cattle and sheep), chaff, shredded grass, waste of all types from household waste, mineral components (such as phosphoric acid, Potassium, silicon, calcium, sulfur, magnesium, iron, cobalt, boron, zinc, molybdenum, Titanium and, in addition to saltpetre formers, insoluble carbonates of calcium and manganese). Once the microbial cultures are well developed, they are mixed together and then with the biotic factors that come from the living beings mentioned.

The following is an example of making the inventive Soil improvers listed, without thereby limiting the invention is intended.

This example consists of three stages of work, namely: i. Step: The contents of the rumen of cattle or sheep are collected in slaughterhouses its liquid, which mainly contains ptyaline, and presses the contents of this Rumen firmly and slowly to separate the liquid from the solid components. The solid substances then form a kind of press cake or flatbread. You bring the liquid and the press cake in a cool room, preferably at a temperature between 2 and 6 °.

Green parts of plants are pressed (grass, nettles, green leaves, fleshy Plants, etc.), which are separated from their liquid if possible. To this one To facilitate the process, it is advisable to shred these green parts of the plant and crush.

The whole thing is brought to cold, damp and dark for a few days Chambers.

Then those from the rumen contents and those from the Press cake from green parts of the plant, which was taken from the cooled chambers are crushed in grist mills and with chopped straw in equal parts (for each of the three products) mixed. At this moment one adds under good Mixing dry earth that had been sterilized with 2'10 carbon disulfide, added. The mixing ratio between the first three products and between earth is: 2: 1.- Then add phosphates, preferably di- or tricalcium phosphates of natural origin or ammonium phosphates, added, in quantities of 20% per year and 5% potash salt, optionally in the form of chlorides or nitrates. You knead the whole thing well and add q.0 / 0 starch, e.g. B. Barley flour.

Then the mass is poured with 33 percent by weight of a liquid, formed from that which has been obtained from the rumen content to which one has the Liquid that has been obtained from the green grass, in the Ratio of 3 parts rumen fluid to 1 part greens fluid. To this Mixture is added i5% liquid manure,: 21% active ruminant faeces and i% whole fresh and activated feces are added in equal parts.

After a few hours, the well-ventilated mass begins to close heat. For heating and maintaining the temperature between 3o and qo ° can be used for the preheated concentration chambers standing under vacuum Serve liquids.

Once the products have cooled, they are served with appropriate Mixed bacterial cultures, to which colloidal trace elements of iron, zinc, Cobalt, titanium, tungsten, molybdenum, boron, sulfur, silicon. the Suspension of the colloids in water is strengthened or stabilized by the presence of glucose, gum or glycerin in the mentioned liquid.

The product obtained is kneaded and dried. Afterward the dried product can be given a strong exposure or a strong ventilation subject. It is then ready for use.

On the other hand, the microorganism strains are produced in the laboratory. They are grown on culture media of silica gel and sterilized soil. To a few days in the incubator they are further grown in soil, whatever the energetic products have been added. The colloidal substances will be manufactured separately.

The bacterial strains and cultures «ground to liquid before use Media transferred and then in adapted proportions with the colloids mixed. The proportions are variable depending on the given case (the The surface of the liquid media should be as large as possible because it is special aerobic organisms), and once development has started, d. H. when veils become visible, the bacterial strains with the nutrient and mixed energy media prepared as described above are. The biotic factors are already in these media, caused by the different above-mentioned measures have been achieved.

2nd stage: For the manufacture of the products of the 2nd stage one uses the products of i. Step. The 2nd stage of manufacture is very similar to the first. Level, with the difference, however, that more straw is imported and that which is sterilized Earth is replaced by that in the i. Stage previously produced product.

3rd stage: In this 3rd stage the proportions are as follows changed to take into account the products introduced during the first two stages.

In order to better explain these three stages in the production of the soil improver according to the invention, the three stages in the production of a typical soil improver are shown below, for example, without any intention to restrict the invention. i. Stage: For this i. Stage a) 150 kg of rumen content; 66 kg of dry products and 84 kg of liquid are obtained therefrom; b) igo kg of fresh grass or greens; 68 kg of dry products and 222 kg of liquid are obtained therefrom; c) 66 kg of straw; d) 100 kg of dry earth; e) 60 kg of very finely ground phosphate; f) 15 kg of very finely ground potassium salt (in the form of nitrate, silicate or chloride); g) 15 kg of starch (in the form of barley flour). The following dry materials are then available: Dry products of the rumen. . . . . . . . 66 kg Dry products of grass. . . . . . . . . 68 kg Straw ... .. .. ....................... 66 kg Dry earth ..................... ioo kg Phosphate .......... .............. 6o kg Potash salt. . . . . . ... . . . . . . . . . . . . . . . . . . 15 kg Starch (or barley flour). . . . . . . . . . 15 kg Total mass .... 39o kg To this mass one adds 130 kg of a liquid, namely 7905 kg obtained from the rumen 26.65 kg obtained from the grasses 19.5 kg of liquid manure 2.6 kg of beef faeces 1.3 kg of horse waste. . . . . . . . . . . . 130 kg Together. . . . 520 kg The added bacterial cultures and the added colloids. . . . . . . . . . 2 kg Together .... 522 kg Partial losses due to evaporation as Result of the increase in temperature and of drying. . . . . . . . . . . . . . . . . . . . . about 22 kg Together .... 500 kg These 50o kg are divided into five fractions of 100 kg each for the 2nd stage. Stage: You process Dry product of the rumen. . . . 66 kg i-- 84 kg new fluid Dry product of the grass ..... 20 lcg -I- 35.8 kg of new liquid Straw . . . . . . . . . . 114 kg From the 1st stage originating pro ducts (a frac- tion) .......... ioo kg Total amount - on dry pro ducks . . . . . . . . 30o kg -I- i 19.8 kg of liquid. One anticipates 106.6 kg of the liquid, mixes it with liquid manure and feces to arrive at 130 kg. Then proceed as with the i. Stage, ie one adds 60 kg of phosphate, 15 kg of potash salt and 15 kg of starch to the solid products and 2 kg of bacterial cultures and colloids to the end product, as indicated above in stage i.

After the i. Stage and this 2nd stage, during which 250o kg of end products were produced, the total consumption is as follows: Dry products from rumen 396 kg Dry grass products. . 168 kg Chopped straw. . . . . . . . 636 kg Dry earth. . . . . . . . . . . . ioo kg Phosphates ................ 36o kg Potash salt. . . . . . . . . . . . . . . . 90 kg Flour (starch) ............ 9o kg Liquid (and suspen- dated products). . . . . . . . . . 780 kg (on 945.4 kg Available) Bacterial cultures and Colloids. . . . . . . . . . . . . . . . . 12 kg Total amount .... 2632 kg The losses through evaporation (increasing the temperature ratur) and through partially Dehydration (6 X 22 kg) amount to. . . . . . . . . . 132 k g Total remainder .... 250o kg After the 2nd stage, this gives the following approximate figures for the various components Humidity ..................... ..... 26, oo% Straw ................................ 25,440 / 0 Dry products from rumen. .. .. .. ... 15.840 / 0 Phosphates ............................ 1q., 400/0 Dry grass product ................... 6,720 / 0 Dried earth. . . . . . . . . . . . . . . . . . . . . 4,000 / 0 Starch (barley flour) ... .. ............ 3.60% Potash salts ............................. 3.60% Various products (in particular from originating from the fluids). .... ..... o.4o% 100,000 / 0 The attached ones and those coming from the rumen liquid products make 6X84 kg, i.e. 504 kg From the grass stem (i22kg + SX36kg) 3o2 kg Coming from the liquid manure (6Xi9.5kg) .. 117 kg From the bacterial cultures and from the Colloid derived (6X2 kg). . . . . . . . . . 12 kg 935 kg One has to claim for the procedure taken (taking into account that the proportions in suspension represent about 23 kg). . . . . . . . . . . . . . . . . 935 kg 78o kg -I- 12 kg - 23 kg. . . . . . . . . . . . . = 768 kg Remaining unused 167 kg The measures required approximately i. on rumen fluid 480 kg against 504 kg (remainder 24 kg), 2. on green liquid 16o kg against about 302 kg (remainder 1q.2 kg).

This leaves about 24 -I- 142, = 166 kg, which amounts to about 14.4 per cent. Rumen fluids and 85.4 per cent. Green matter fluids.

The figures shown above, for example, are only very approximate, because the respective liquid content is always very different, on the one hand it depends he from the feeding of the ruminants before slaughter, on the other hand from that State of drought or the age of green products. The order of magnitude is right to some extent, and the aforementioned surpluses provide a margin of safety.

Incidentally, you can greatly reduce these surpluses by reducing the concentrated liquids obtained from the green products in vacuo.

During the production of these 262o kg, i.e. H. before the introduction of the Bacterial cultures and the colloids, the temperature of the whole mass rises a lot quickly to 7o to 8o °. However, this temperature is brought to about 30 to 32 ° return. So you have 262o kg X 46 ° (on average), i.e. H. about 12o ooo large calories.

Assuming that one is for the later drying of these calories about 6o ooo ver.-wend-et in order to increase the drying speed you still have over 600,000 calories to remove about 100,000 water from the greens in a vacuum remove. In this way the remaining total excess is only in liquid about 6o 1, which is a sufficient margin of safety.

3rd stage; Production: The 2500 kg of the 2nd stage allow the production of: 16 fractions of 532 kg, ie about 850o kg of end product, of which 2q.94 kg come from the 2nd stage and 60i8 kg of new components are added. Each fraction of 532 kg requires in its manufacture: Products obtained after the 2nd stage ...... 156 kg Dry rumen products ......... - ...... 52 kg Chopped straw ... .................. Zoo kg Drained grass. . . . . . . . . . . . . . . . . . . . . . . 14 kg Calcium carbonate. . . . . . . . . . . . . . . . . . . . . . . . 62 kg Dry earth .......................... 2o kg Phosphates .............................. 38 kg Potash salt ................................ 10 kg Starch (barley flour). . . . . . . . . . . . . . . . . . . . 1o kg Liquids (with suspended products ) 90 kg 552 kg One adds (the characteristic operation of the 3rd stage) bacterial cultures and colloids ................................. 2 kg _ 554 kg loss through evaporation and drying. 22 kg end product obtained. ... 532 kg The components of the end product have approximately the following content figures Moisture ... .. ..................... 20,300 / 0 Straw ................................ 25,950 / 0 Dry products of the rumen. . . . . . . . . . 14.450 / 0 Calcium carbonate ...................... 11.76% Phosphates ... .. .. .. .. .. .. .. .. .. .. .. ... 11.45% Dry earth. . . .. .. .. .. .. .. .. .. .. ... 5.07% Drained grass .................... q., 660/0 Potash salts .......................... ö .. 2.94% Strength ... .. .. .. .. .. .. .. .............. 2.93% Bacterial cultures and residues. ... 0.490 / 0 1 oo, oo% Taking into account the dry earth as a mineral product without organic substance, this results in the following values as essential components of the product obtained: 20.300 / 0 moisture, 31,: 220/0 mineral products, 48.48% organic substances.

In these 250o kg there are 1222 kg of dehydrated rumen products and 392 kg of dehydrated green products.

These 1222 kg of dewatered products amount to approximately 2777 kg in total used material and resulted in about 1555 kg of liquid; the 392 kg drained grass comes from 1095 kg of fresh grass (straight from the fields or from the silage).

All in all, you have 2777 kg of rumen products, 1095 kg of fresh green grass, 2256 kg of straw, 1000 kg of calcium carbonate, 968 kg of phosphates, 42o kg of dry earth, 25o kg of starch 250 kg of potash salts 354 kg of manure, 47 kg of cattle faeces, 24 kg of horse faeces, 44 kg Bacterial cultures and colloids to produce 8500 kg of the soil improver as an end product.

When the zymases, the enzymes, the diastases of all kinds, the hormones, the vitamins, the growth factors (derived from cells or through the action of microorganisms) once introduced into the soil, they will become part of it multiply strongly in the soil, but to achieve this it is necessary that the temperature, the degree of humidity, the sources of energy, the relationship between acidity and The alkalinity, the ventilation, the rH, the possibility of oxidation etc. remain optimal and meet the needs. It is necessary to monitor them from time to time and, if necessary, one or the other component that is out of balance with the total mass is to add or stimulate.

The production described above is not intended to limit the invention and is only to be regarded as one of the means to achieve the invention. Man can e.g. B. Add soil worms or eggs from soil worms to the final product to ensure the ventilation of the soil and the good adaptation of the product in the soil.

Claims (1)

PATENT CLAIMS: 1. A process for the production of soil improvers, characterized in that the rumen content of ruminants (slaughtered animals) is pressed in order to separate the liquid contained therein from the solid parts, and plants in the green state are crushed in order to remove the liquid from the solids, from which they are composed, to be separated, whereupon the separated substances (liquids and solids) are preferably subjected to aging for several days in cold and dark chambers and the solid products are mixed with crushed trace elements and phosphates and the liquids mentioned from the rumen interior and the green Plants are added to the mixture: 2. The method according to claim 1, characterized in that zymogenic cultures are added to the deposited products, which are essentially composed of nitric acid and nitric acid ferments, cellulose ferments and in particular actynomycetes, thermophilic bacteria ien, obligocarbophilic bacteria, sulfobacteria and ferrobacteria. 3. The method according to claim 1 and 2, characterized in that some or all of the following trace elements are added in the colloidal state to the deposited products: silicon, carbon, boron, cadmium, magnesium, titanium, molybdenum, zinc, iron, manganese, sulfur, Tungsten and cobalt. 4. The method according to claim 1, 2 and 3, characterized in that the production takes place in several stages, the products obtained in one stage being used for the partial production of the following stage. 5. The method according to any one of claims i to 4, characterized in that the ingredients are mixed in the following proportions: about 30% raw rumen content of ruminants, io to 150/0 green herbs or grasses, 2o to -95010 straw, 5 to 10% calcium carbonate, 9 to 2% phosphates, 4 to 5% dry earth, 2 to 3% starch, 2 to 3% potash salts, 3 to 4% natural feces, 0.7 to 1% animal excrement, 0.4 to 0 , 6% colloidal trace elements and 0.2-0.4% cultures of microorganisms. 6. The method according to claim i to 5, characterized in that the soil improver or soil worms or eggs of soil worms are added. Cited publications: German Patent Nos. 701 903, 500 999, 435 534, 383 779, 355 038, 26o 747, 228 592, 1 23 054, 120 141, 111 247, 84 82 0 , 866 343; French Patent Nos. 762 752, 503 668, 415 161; U.S. Patent No. 2,200,532.