HU191893B - Method and apparatus for processing the thin manure of animal keeping farms - Google Patents

Abstract

Processing begins with known mechanical phase decompsn. step performed in known equipment. Resulting liq. suspension is stirred after adjusting pH with lime to 12 in the presence of pref. potassium-phosphate and magnesium-sulphate and of the formaldehyde present, to destroy stability of colloid suspension and provoke pptn. reactions. Suspension is then neutralised to pH 6.5-7.5 in two steps, pref. using ferro-sulphate, and allowed to settle. Liq. so obtd. is stored in anaerobic conditions, sterilised with formaldehyde and then used either as industrial water for the washing of stables, or after addition of plant feed substances and/or microelements, for irrigation of crops. It is pref. to condition liq. before use in stables with further addition of formaldehyde, potassium-phosphate and magnesium-sulphate. - Equipment for process comprises mechanical preseparator, alkaline reactor, two-step neutraliser and settling tank, mud collecting container, and conveying pump, mud conditioning and dewatering unit consisting of mixers and filtering devices, anaerobic storage containers, sterilising unit, devices for adding substances to the resulting liq., and units for supplementing the dewatered mud with other solid substances and for sterilising solids.

Description

BACKGROUND OF THE INVENTION The present invention relates to a process and an apparatus for treating slurry in livestock farms in order to recover solid and liquid components of slurry in an environmentally sound form by recovering the solid and dissolved nutrient components. Concentrated liquid, free of suspended matter, phosphorus, nitrite, nitrate and pathogenic germs, usable for irrigation and as industrial water without any restrictions on animal hygiene, for use in agriculture without loss of the environment or for bioenergy utilization. In our process, a large part of the solid components of the slurry is separated by simple and inexpensive mechanical means at the beginning of the treatment to relieve subsequent treatment, and then the remaining floating impurities and a significant amount of dissolved solids are separated from the liquid phase by chemical flocculation and sedimentation. the mirror-clear liquid is chemically germinated after prior anaerobic dressing, and the pathogen-free liquid is used either as industrial water, preferably for rinsing stables or as irrigation water. The slurries obtained during the treatment are dewatered by the addition of chemical auxiliaries and the resulting dehydrated material either alone or in admixture with other suitable materials, preferably completely chemically sterilized or used as fertilizers in agriculture or for subsequent use.

It is known that technology for the economical and especially environmentally sound management of 42-45 million cubic meters of livestock manure in farm animals has not been developed to date. There are many different types of competition. One of the trends is treating slurry as wastewater: treating it with aerobic or anaerobic biotechnology, assimilating it with microbial populations, and eliminating organic and other materials that are otherwise valuable to the soil at very high cost without any use.

The other trend is to perform phase separation by essentially simple filtration (such as straw bales) and bypassing the liquid phase at times and times, bypassing environmental regulations. To illustrate the above and to describe some other treatment methods, the following patents are for information purposes:

No. T / 21117. According to U.S. Pat. No. 4,123, slurry is treated by adding to the fluidized bed slurry the humate and acid liberated by the interaction of carbon and alkaline hydroxide at the injection site, which results in the formation of a fluffy humic acid suitable for collecting colloidal impurities. The resulting solid tube liquid phase is separated.

Vermes et al., And many other authors, unanimously suggest that the slurry - as a treatment or disposal - is simply separated into a liquid and solid phase by some process, then the liquid is irrigated and the solid phase is used without further application. Such a process has a number of very disadvantages: the plant nutrient concentration in the liquid phase is usually too high and overfertilization can occur. It is also known that the bacterial state of the liquid phase is dangerous and that serious infections can occur.

No. 2,163,364. The German patent application proposes the use of slurry for the production of protein feed by fermentation of slurry in an acid medium. The process has the disadvantage that it requires the use of a large amount of acid, while the positioning of the liquid phase obtained after the separation of the protein materials poses another environmental problem.

Nos. 118,797, 99,768 and 98,818. The GDR patent applications also process slurry by fermentation without the use of pH-adjusting additives for protein production. A disadvantage of the process is that the animals fed with the feed materials thus obtained have anemia or bone weakness, but the placement of the liquid obtained during processing as waste water presents another problem. The disadvantage of the feed obtained in the process stems from the fact that the process results in the formation of calcium-binding carbonates, the mobility of which is permanently eliminated, since the alkaline feed is neutralized by stomach acid. thus, the process is not expected to spread. No. T / 22615. The disadvantage of the above process can be overcome by treating the proteinaceous biomass produced in the fermentation without additives with acid prior to direct feeding or drying, whereby the pI1 value goes into the slightly acidic range.

No. T / 20902. According to U.S. Pat. No. 4,663, animal fertilizers are utilized by mixing with about 10 times the amount of agricultural waste material, first by aerobic and then anaerobic digestion, adding to the separated fermentation broth partially leaching the pH to the alkaline direction, , the fermentation broth is recycled to obtain biogas, and organic mass can be used as a fertilizer. Another disadvantage of this process is that the disposal of the resulting fermentation juice poses another problem and also requires highly skilled personnel.

No. 160,055. A process and apparatus for treating slurry is disclosed in Hungarian Patent No. 5,198,198, which comprises the step of gravitationally settling the slurry into phases of a tapered basin divided into vertical walls and alternating the sludge with the resulting sludge. , then used as fertilizer, and the diluted juice is irrigated on arable land.

The disadvantage of this process is that it requires very large and expensive artefacts and, in this case too, does not provide for the elimination of the pathogenicity of the dilute phase.

No. 178,725. According to the Hungarian patent, slurry is treated by phase decomposition, for example by flotation, then the resulting slurry is ponded for algae propagation, the solid phase is dried by dewatering and used as fertilizer. A very disadvantageous feature of the process is that economically efficient algae synthesis can only be achieved under climatic conditions assuming a lot of sunlight and high ambient temperatures, and on the other hand large algae lakes need to be provided for large specialized livestock farms.

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No. T / 20886. According to U.S. Patent No. 4,123,121, slurry is to be utilized in biogas production to obtain fertilized material and irrigable liquid. In the process, slurry is concentrated by mixing 3 to 10% by weight of slurry material, the coarse particles are pre-separated, solid impurities are also separated from the liquid phase by flocculation with aluminum sulphate, and the sludge and dense phase are used for biogas production. The resulting stabilized solid phase is fertilized, the liquid phases either irrigated or used to rinse barns. A major disadvantage of the process is that its investment costs are very high, the resulting fluids are not germinated, so their use is dangerous and further treatment is required before placement.

No. 172,727. Hungarian patent proposes chemical and biological treatment of slurry. After homogenization, 0.4 to 1.0 kg / m ^{3 of} aluminum phosphate and 25 to 30 mg / m ^{3 of} polyelectrolyte are added to the slurry followed by filtration through a press-belt filter. The filtrate is treated with activated sludge sewage treatment plant.

No. 3,773,659. U.S. Pat. No. 5,123,198 proposes biological treatment of high organic matter wastewater by adding enzymes synthesized by bacteria under controlled conditions to the biological step of the purification system and then separating them from the fermentation broth by coagulation. It has the disadvantage that the quality of the purified liquid is not sufficient for delivery to surface recipients.

No. 3,763,038. U.S. Pat. In the first step, a trivalent iron salt is added as a coagulating agent, followed by phase separation after coagulation by settling. In this case, the quality of the purified water is not satisfactory either. No. 122,564. Hungarian patent proposes a process for the digestion of various types of organic waste. It treats the material to be digested in a paste-like state with a water content of at least 90% by weight and traps the evolving gas.

No. T / 16771. U.S. Pat. The point is that the slurry is watered with an open-cell plastic foam that has been used to loosen soil. According to the present invention, in the case of urea-formaldehyde foam, the formaldehyde gas released from the foam decomposition kills the pathogenic germs so that the resulting fertilizer can be released into the soil within a few hours. The disadvantage of the process is that, in practice, sufficient amounts of plastic foam are not available to absorb the aforementioned amount of slurry.

No. Τ / 17824 U.S. Patent Publication No. 4,123,125 discloses a process and apparatus for the thickening and composting of slurry. It is important that he slurry the slurry onto absorbent agricultural wastes, then, after the layer is saturated with moisture, place another absorbent layer on top of the previous one, and finally leave the full tank for forty days and then fertilize the product. One of the major drawbacks of the process is that no large agricultural farm has enough absorbent waste material that is regularly sufficient to absorb slurry.

No. 158,766. The process according to the present invention solves the treatment or utilization of slurry by separating the floating impurities from the slurry with a vacuum filter, either by spraying or using the resulting liquid phase for washing. Alternatively, it also recommends chemically precipitating the nitrogen compounds and then separating them by filtration, but does not specifically specify the chemicals to be used. A disadvantage of the process is that it targets only the nitrogen in the leaching of the nutrients and does not germinate the liquid phase. A high-power, low-specific vacuum filter to separate solids? application.

No. 180,225. The Hungarian patent aims to chemically treat slurry, but the sole purpose of the chemical treatment is not to obtain nitrogen compounds, but to destroy the stability of the colloidal suspension by the formation of insoluble Ca and / or Mg compounds using alkaline earth metal hydroxides. precipitation of phosphorus, binding of protein substances, urea and ammonia using formaldehyde. germination of the liquid obtained at the end of the treatment with the same substance as the disinfectant, 2-step flocculation using the iron (II) salt to obtain a mirror-pure liquid and complete phosphorus separation using polyelectrolyte to achieve rapid sedimentation using sulfuric acid. The disadvantage of the procedure is that its investment costs are very high and require highly qualified personnel.

No. 169,988. According to the Hungarian patent, the treatment of slurry is carried out by separating the slurry into three main parts with suitable equipment and treating these parts separately. The resulting low urine phase is treated with a known wastewater treatment method and utilized as industrial water or rinse water. after dewatering, the recovered solid phase is utilized as an object, the urine, treated as a chemical feedstock, is used to recover nitrogen compounds, and the liquid is also deposited as a rinse and / or irrigation water. Its disadvantages are significant: as the liquid is not germinated and its use as irrigation water is not permissible under current environmental regulations, nor can it be used for laundering stalls without restrictions.

The XXVII. Vol. No. 35 describes a slurry treatment process in which, after separation of the coarse floating impurities, the liquid phase is treated with incest milk, sedimented and then further treated in a biological leachate. A major disadvantage of the process is that, despite the high investment costs, it is not possible to obtain surface water that can be delivered to a recipient, nor does it provide disinfection.

The process of the present invention eliminates all of the disadvantages of the above-mentioned processes and furthermore has several advantages over previous processes based on the following discoveries:

i. The liquid obtained in the process is disinfected with formaldehyde. Reintroducing formaldehyde in disinfected industrial water into the stables has the very advantage that formaldehyde can remain in the manure storage area of the stables for an extended period of time, providing the following reactions:

- Reacts with the odorous amines to make the stables odorless.

- reacts with urea to form methylol and / or methyl

191 893 form urea, which precipitates and thus significantly reduces the amount of dissolved solids in the liquid phase already in the stables, - the precipitates from the urea-formaldehyde reaction are considered to be retarded fertilizers due to their low water solubility and formaldehyde also reacts with ammonia from the decomposition processes already in the manure, which prevents the release of ammonia into the air, which is of great importance for animal health, - ammonia before the treatment plant binding is also important from a hygiene point of view as the hall becomes odorless - formaldehyde is already in the barn manure with colloidal stabilizing carbohydrates reaction, thereby significantly reducing the stability of the slurry suspension, which has a favorable effect on phase separation during treatment.

2. The present invention is based on the further realization that if potassium phosphate and magnesium sulfate are added to the liquid used for washing the stables (which can be obtained in the industrial water of the process) during the return to the stables, then the ammonia resulting from decomposition ₄ PO ₄ , which also results in deodorization of the stables and thus is of considerable animal health importance, the microcrystalline precipitate thus formed reduces the stability of the slurry as a colloidal suspension by mechanically disrupting the hydrate envelope of the colloidal particles, thereby also treating the slurry more effective - the use of the same two chemicals in the lime-alkaline treatment step, which is the first step in the chemical treatment of slurry as it results in the removal of ammonia from alkaline treatment, which also leads to deodorization of the treatment hall and elimination of nitrogen losses, the microcrystals also exert their effect on the breakdown of the hydrate envelope. - the addition of potassium phosphate increases the ratio of K / Na to urine, which means that when irrigated liquid manure liquid is used, the potassium ion may be displaced by the colloidal ion because of the higher potassium ion. In this way, salinisation can be suppressed by irrigation of this liquid, - due to the significant potassium reservoir in the irrigation, spraying of the irrigation liquid eliminates the potassium leaching losses from the plants, which otherwise can achieve a leaching value of 80% is added to the system, which, however, is eventually added to the collected solid phase through said precipitation reactions, significantly increasing the fertilizer value of the resulting manure.

3. The use of iron salt, in particular the very cheap iron (II) sulphate, in two steps for neutralization after alkaline treatment has the following significant advantages:

- by acidic hydrolysis, reduces the pH of the liquid phase to no more than 6.5-7.5 without the use of any other acidic chemical; In our experience, iron sulfate neutralization in stages is reproducible.

- performing neutralization in a purifier has the significant advantage that flocculation, in addition to neutralization, collects colloidal impurities, which can be separated from the liquid by means of a liquid of mirror purity; - iron ions also react with ammonia to form complex iron-ammonium cations which, when irrigated with liquid manure treatment, ensure complete elimination or inhibition of chlorosis of the vegetation.

4. There are significant benefits to anaerobic storage of fluid that has been neutralized and suspended. According to our experience further decomposition of the nitrogen compounds takes place, which in most cases is completed within seven days and the liquid stabilizes. The ammonium ions formed in this process provide the liquid with the following beneficial properties as irrigation water:

- since ammonium ions can bind very strongly to soil colloids, it is also possible to irrigate the liquid off-season without loss of nitrogen. Thus, during this period, nitrogen is not lost, but accumulates, and the nitrogen thus accumulated is readily available to vegetation at the beginning of the growing season and exerts a starter effect, which until now has been induced by nitrogen fertilization only, - the decisive influence of ammonium ion on germination.

- because the ionic adsorption strength of ammonium ion is significantly higher than that of sodium and potassium. therefore, irrigation with such a liquid may increase the mobility of potassium in the soil, which results in elimination of acalic deficiency, thus saving potassium salt, while also reducing salinisation in the case of alkaline soils, since sodium is liberated from the soil by leaching from the soil.

- It is also remarkable that the concentration of ammonium ion produced by anaerobic storage at the pH of the Jött converts the liquid into an optimal medium for the separation of trace element humates. Thus, the addition of the inorganic salts of these micronutrients and the human anion (most preferably in the form of potassium humate) to the anaerobically treated irrigation fluid results in a high quality liquid suitable for fertilization with the following significance:

- in contrast to the known micro-nutrient substitutes (V'uxal. Peretrix, etc.) known so far, which at the same time contain a number of trace elements, not all of which are required, the method according to our method can only add the agronomically actual trace elements

191,893 - the applied anatomy is the closest to nature and thus the least foreign to the anions used to date in micro fertilizer fertilizers, - the free humate produced after uptake and decomposition of micronutrient humate is highly effective in plant life processes, -acid oxygen redox forms a reversible system and thus effectively enhances cellular respiration.

5. Unprecedented advantages in our process are obtained by effective disinfection of the obtained liquid, thereby obtaining rinse water which can be used unrestrictedly from an animal hygiene point of view and irrigation water which can be irrigated without health restrictions, and the presence of formaldehyde in the irrigation water processes, thus also having a beneficial effect on increasing the weight of the cultivated plants.

6. A very significant advantage of the process according to the invention is that the slurry is strongly alkalized at the beginning of the treatment, preferably using magnesium-containing lime hydrate. This gives you the following benefits:

- intense deamination in the strongly alkaline medium, which results in the appearance of nitrogen in the form of ammonia, the trapping of which has already been described above.

- magnesium in lime is involved in reactions leading to deodorization of the plant, - calcium and magnesium in lime are involved in reducing the phosphorus content of slurry, - highly alkaline medium causes plasmolysis of pathogenic germs, the lime hydrate used for the alkalization is not completely soluble, so some of it will be present as a hydroxide in the resulting fertilizer. This allows some of the humic carriers (peat, lignite, lignite, etc.) to be mixed with the manure to produce a degree of degradation which results in the formation of Ca and Mg humates which significantly improve the porosity of the soils. the resulting fertilizer is very advantageous for fertilizing acidic soils and increasing the Ca and / or Mg content of the soils, - the solids separated during the treatment are sterile due to the highly alkaline treatment step, so that the resulting fertilizer can be stored for a long time without decomposition it can be used later, inter alia, for biogas production.

7. Because it is good in the process of the invention! and irrigation fluids with a tangible composition and disinfectant can be obtained, which clearly ensures that they are disposed of in the intended manner, while the resulting solid manure can be used in agriculture in an organized manner, thus ensuring first the complete elimination of the environmental impact of slurry. high-level marketability. Since both irrigation liquid and solid fertilizers have the advantageous agronomic properties described above, and since their fertilizer value can be clearly determined, the equipment for carrying out the process is a return on investment, which can be very stimulating for the spreading of the method and equipment according to the invention.

On the basis of the above, it can be stated that none of the slurry treatment methods so far ensures that the slurry is disposed of in an environmentally friendly manner and at the same time it is fully utilized at a value higher than its original value.

An exemplary embodiment of our process is illustrated by the following example.

Example 1

The example illustrates a continuous embodiment of the process of the present invention and uses Figure 1 to explain it.

The slurry from the sheds 1 to the collecting shaft 2 was transferred to the battery 4 (sheet screen) by the dispensing pump 3 to remove the coarse solid impurities. Liquid flowing through the battery 4 (through a sieve) and containing a large amount of colloidal impurities was conveyed via the dispensing pump 5 to the alkaline reactor 6, while magnesium sulfate was diluted to 15% w / v in the mixing tube 30 with the four-way chemical feeder 33. 36% by weight, and the slurry was intensively circulated through the mixer-transfer pump 7 in the alkaline reactor 6, adding enough magnesium lime to the slurry in the 38-screw lime feeder so that the pH of the medium was 12 or higher. During the circulation, potassium phosphate 0.64% by weight, based on the amount of slurry, was added to the mixing tube 35 in the form of an aqueous solution of the four-way chemical feeder 33. The slurry thus prepared was fed to the centrifuge settler 9 by the mixer-dispensing pump 7, with an average residence time of three hours, while in the mixing tank 8 in the form of a 15% aqueous solution of the tank 22. iron (II) sulfate was added to the dispenser 23 to bring the pH to 8-9 of the material flowing to the neutralization settler 9, which was checked with indicator paper. To enhance the treatment performance, 1 ppm of Praestol 444K in 0.2 wt% aqueous solution was added to the liquid from the polyelectrolyte solvent storage tank 26 using the solvent dosing pump 27. Iron (II) sulfate was repeatedly added to the effluent from the neutralization sedimentation apparatus 9 in an amount such that the pH of the effluent from the neutralization settler was 7.3. The addition of polyelectrolyte to the mixing tube 10 can also be used at a rate of 1 ppm only if flocculations have been observed.

The liquid obtained above, which was completely free of suspended matter, was transferred to the 16 anaerobic reservoir, which was stored for six days. The liquid was then passed through the overflow into the disinfection compartment 18, which provided a residence time of about one hour, into which 1.1 m% of technical grade concentrated formaldehyde was added to the liquid dispenser for germination. From here, the liquid was led in two directions: irrigation and laundering of stables. In the previous case, 5.1 wt.% Potassium humate solution was added to the germinated liquid from the chemical container 36 via the chemical dispenser 29 in the amount of irrigation fluid.

-5,191,893, and because the vegetation to be irrigated was deficient in skin and manganese, 29 chemical feeders were also added manganese sulfate and boric acid in the form of 10% aqueous solutions to give a manganese content of 6 ppm, the amount of boron in the irrigation liquid was 4 ppm. The conditioned irrigation fluid was sprayed onto the alfalfa in area 31 by means of a pump 19.

The gutter was also pumped for washing the stables using pump 19 containing 0.4% w / v free formaldehyde, while 0.64% potassium phosphate / 0.36% potassium phosphate was added to the mixing tube 37 via the 33-gauge chemical feeder and m% magnesium sulfate was added in the form of 15% w / w aqueous solutions.

The sludge taken from the sludge dewatering plant 9 and 11 was combined in the sludge collecting vessel 12 from where it was transported to the sludge conditioning unit 14 via the sludge transfer pump 13, while the sludge was pumped to the sludge in a 0.2% aqueous solution. Praestol 444K polyelectrolyte was added in ppm. The conditioned slurry was introduced into the dewatering container 15, where it was spontaneously discharged to a dry solids content of 22% by weight over three days. The leachate was returned to the anaerobic reservoir 16.

To the dewatered sludge, the solids separated from the screen 4 were added to the dewatered sludge in a 24-screw homogenizer with enough air-dried peat to give a 56% w / w dry matter content after homogenization. During homogenization, formaldehyde (0.8% w / w) was added to the material with feeder 20 to completely germinate the product, and the resulting product was bagged in a solid handling unit 25 and stored for further use.

Claims (3)

Claims 1. A process for treating slurry from livestock farms to obtain irrigation water and / or industrial water by mechanical and chemical separation of the solid components of the slurry, chemical precipitation of the solids and recovery of the slurry-free and slurry-free slurry sterilization and addition of vegetable mikrotápelemekkel optionally through, characterized in that the pH of the phase is broken down in a per se known mechanical means (e.g. ívszitás, vibrószitás, endowment) slurry liquid phase of 2-8 kg / m ^3, preferably 4-6 kg / m ³ of alkaline with magnesium-containing lime hydrate to a pH of at least 12 and to a 1: 1 molar ratio of potassium phosphate in a total amount of 0.02 to 1.5 m%, preferably 0.05 to 1.0 mTf, based on the weight of the liquid, and magnesium sulfate is added with vigorous stirring for 0.5 to 4 hours, preferably for an average residence time of 2 to 3 hours, so that the pre-treated material is a metal salt. preferably by adding iron (II) sulfate in an amount such that the pH of the mixture is adjusted to 8-9, and in some cases neutralizing with cationic polyclifttrolite, preferably in an amount of 1 ppm, in a wall sedimentation apparatus, with addition of the medium so that the pH of the medium is 6.5- Set to 7.5 and neutralize in a second neutralization-settler, then transfer the thus-neutralized and sedimented liquid to an anaerobic reservoir with a storage capacity of 0.5 to 20 days, preferably 2 to 6 days, and to the disinfectant compartment for at least one hour residence time. whereby 0.1 to 2.0% by weight of formaldehyde, preferably 0.5 to 1.5% by weight, is added to the liquid, and the liquid so treated is preferably returned to 0.2-0.6% by weight of free formaldehyde or to rinse stables while adding to the liquid 0.1 to 2.0% by weight of the potassium phosphate in a total amount of 0.1 to 2.0% by weight, preferably 0.5 to 1.0% by weight, and magnesium sulfate is added to the manure collecting compartment during washing or as irrigation water If used, it has a dry matter content of 1.0-7.0% by weight, preferably 3.5- An aqueous solution containing 5.5% potassium humate is added in an amount of 0.1 to 1.0% by weight, preferably 0.3 to 0.6% by weight, based on the amount of irrigated water, and sometimes plant micronutrients of suitable quality and quality are added. The pre-treated liquid is irrigated, while the sludge obtained during the neutralization and sedimentation is combined, the cured active flocculant being added to the combined sludge, preferably Praestol 444K, at a volume of 50-150 ppm, preferably 80-120 ppm, and the slurry is slowly mixed. by dewatering spontaneous discharge to spaces formed by water-impermeable walls (e.g., a dewatering container), and then dewatered sludge alone or with absorbent organic materials (e.g., After mixing it homogeneously with the solids separated during the process, it is disinfected with 0.1-1.0% by weight of farmaldehyde and preferably after further drying is stored for fertilization or other purposes (for example, for the preparation of fertilizer compositions, biogas development). Apparatus for digging a tooth according to claim 1, characterized in that it comprises a mechanical reactor unit or a battery (4) formed therefrom, an alkaline reactor (6), two in-line neutralization sedimentation reactors (9, 11), a sludge transfer pump (12). (13), sludge conditioning mixer (14), dewatering system (15) consisting of filter walls (15), anaerobic fluid reservoir (16), disinfection compartment (18) with formaldehyde dispenser (18), pump (s) (19) for recirculating to the stables and for irrigating, a? dehydrogenating agent for homogenizing the dehydrated sludge with other substances, comprising a mixing tube (28), a chemical dispenser (29) and a multi-compartment chemical storage tank (36) for supplementing the liquid to be irrigated with vegetable micro and / or macronutrients, 24), a metal salt solubilizer dispenser (21, 22, 23), a polyelectrolyte solubilizer dispenser (26, 27), a potassium phosphate magnesium sulfate dispenser (33, 34) and a lime hydrate dispenser (38). An embodiment of the device according to claim 2, characterized in that the pump (7) connected to the outlet of the lower conical part of the alkaline reactor (6) Connected to the pressure side of 191,893 is a bifurcated branching pipe incorporating a flow control tube, such as a slider, into one of the branches, one leading back to the alkaline reactor (6), the other leading to the next unit of the treatment line, (7) designed for both mixing and conveying purposes.