FR2757504A1 - Preparation of organo-mineral fertilisers - Google Patents

Abstract

Preparation of organo-mineral fertiliser comprises preparing the first mixture of mineral constituents (1,3), preparing the second mixture of organic constituents (7,9) and mixing the two compositions to a paste in a mixer (13) followed by: (a) granulating the paste; (b) baking (19) the granules (17) without destroying the organic elements, and recovering the vapour, cooling to liquefy and returning to the mixer (13); and (c) cooling the baked granules rapidly. Also claimed is the fertiliser prepared as above containing 5-50% organic elements.

Description

 ORGANO-MINERAL FERTILIZER AND ITS MANUFACTURING PROCESS.

 The invention relates to an organo-mineral fertilizer and its manufacturing process.

 Plants use nutrients for their growth, which they capture by the leaves during photosynthesis (this is the case with carbon) and essentially by the roots for other elements. The elements that plants must draw from the soil, notably nitrogen, potassium and phosphorus are often present in insufficient quantities to meet the needs of plants.

The use of fertilizers therefore greatly increases yields.

 There are already known mineral nitrogen (N), phosphate (P) or potassium (K) fertilizers called NPK fertilizers. These fertilizers, currently sold on the market, are dosed so that after leaching by the rains, there remains sufficient nitrogen, phosphate and potassium near the roots of the treated plants. This leads to an overdose and the dispersion of nitrogen, phosphate and potassium in groundwater and rivers.

 Also known are organic fertilizers based on waste from farms (slurry), sewage treatment plants (residual sludge) and the food industry (muddy waters from washing slaughterhouses and canneries). These organic fertilizers also contain nitrogen (N), phosphate (P) and potassium (K) as well as trace elements but are mainly used today to improve the physical qualities of the soil (organic amendment). However, after spreading, these organic fertilizers must be buried to limit odors and losses of ammoniacal nitrogen. Furthermore, when the liquid manure is spread by irrigation, it must be deodorized. In addition, it is common to spread 20 to 30 tonnes of slurry per hectare representing 100 to 150 units of nitrogen, 80 to 120 units of phosphorus and 60 to 90 units of potassium, while the needs of plants are 40 % less important. There are therefore environmental pollution problems resulting from such spreading.

 Finally, mixed fertilizers are known which consist of a mixture of organic and mineral materials which are not antagonistic but on the contrary complementary. These organo-mineral fertilizers allow the one-time application of nutrients from mineral and organic sources, elements that the plant can absorb for three to four months.

 Already known from the prior art is a process for manufacturing these organo-mineral fertilizers which consists in carrying out a first mixture of different mineral substances and then in adding organic materials of the slurry, straw or manure type, to grind and to mix the whole, then pressing the mixture obtained in an automatic press, to obtain fertilizer plugs of 7 to 8 mm in length. This process is carried out with organic and mineral mixtures in the dry state or possibly in the presence of steam.

 However, this manufacturing process has the serious drawback of causing the emission of polluting vapors, in particular ammonia vapors. In addition, fertilizer plugs are less easy to spread than existing mineral fertilizer granules and require the use of specific spreading equipment.

 The object of the invention is to solve the drawbacks of the prior art.

This object is achieved using a manufacturing process of the type consisting in carrying out a first mixture of mineral elements entering into the composition of a mineral fertilizer, in carrying out a second mixture of organic elements entering in the composition of '' an organic fertilizer, to mix the first and the second mixture and to knead the dough obtained in a kneader. Depending on the characteristics of the process, the following additional steps are carried out, consisting in:
a) granulating the dough obtained,
b) bake the granules obtained in the oven without destroying the organic elements, and recover the steam released from the baking oven, cool it to liquefy it and return it to the mixer, and
- c) rapidly cooling the cooked granules.

 Thanks to these characteristics of the invention, the ammonia vapors circulate in a closed circuit and there is no pollution of the atmosphere.

 Preferably, the granulation is carried out in a granulator, so as to obtain granules of 2 to 3 mm approximately. The granules of organo-mineral fertilizers are easier to spread than the plugs of these same fertilizers of the prior art and above all can be applied with the agricultural machines that users already have for spreading the granules of mineral fertilizers. of the prior art. The solution of the invention is therefore less expensive.

 Preferably, the cooking is carried out at a temperature between 200 "C and 380" C, for a duration less than or equal to 80 seconds. Thus, the fertilizers produced contain no germ. They can be put on grassland on which animals are grazed.

 Another object of the invention is also to manufacture a "organic" fertilizer.

This object is achieved using an organo-mineral fertilizer produced according to the process described above, said fertilizer containing between 5 and 50% by weight of organic elements. Thus, the proportion of NPK provided by elements of organic origin being important, the final cost of the fertilizer is reduced significantly (up to about 30%).

The invention will be better understood on reading the following description of an embodiment of the invention, given by way of illustrative and nonlimiting example, this description being given with reference to the attached drawing in which:
FIG. 1 is a diagram illustrating the different successive stages of the fertilizer manufacturing process.

As illustrated in FIG. 1, the method comprises a first step consisting in carrying out a first mixture of mineral elements 1, 3 entering into the composition of a mineral fertilizer, using a mixer 5. These mineral elements are generally in powder form. The first mixture contains, for example, at least one of the following elements: phosphate, magnesium hydroxide (magnesia), tricalcium phosphate (agricultural plaster), dolomite, potassium chloride (KCI), ammonium sulfate, or lithothamne. This type of mixture is already known for the manufacture of mineral fertilizers. The lithothamne is formed by the fossilization of a marine alga called lithothamnium calcareum, and composed of 70 to 80% of
CaCO3 and Mg CO3. In addition to calcium and magnesium, this element provides a lot of trace elements, in particular iodine.

 The mineral elements are mixed dry and at room temperature.

It takes about 4 minutes to mix 2 tonnes of components.

 A second step consists in carrying out a second mixture of organic elements 7, 9, using a mixer 11. This second mixture is carried out at ambient temperature by fractionating the organic waste. The second mixture contains, for example, sludge from sewage treatment plants or slurry. When the organic mixture contains only sewage treatment plant slurry and slurry, it preferably contains 10 to 400 kg of sewage treatment plant sludge and 80 to 900 liters of slurry.

Slurry is a mixture of urine and faeces from pigs or cattle obtained from gratings. It is more or less diluted by washing and watering waters. The average mineral composition of pig manure is as follows in grams per kilo of wicker:
N = 5
P205 = 4
K20 = 3
CaO = 3
MgO = 1
Nitrogen occurs mainly in the form of ammonia and comes from the transformation of urea from urine.

 The third step consists in mixing the first and the second mixture and in introducing the paste obtained into a kneader 13. Advantageously, the kneading takes place at room temperature. For example, it is carried out for approximately 11 seconds in an online mixer.

 The fourth step consists in granulating the dough leaving the kneader in a granulator 15. The granulator 15 has a granulation plate 16 allowing the formation of the granules. The granules 17 obtained are introduced into an oven 19 where they are cooked according to a temperature and a duration depending on the oven used while not exceeding a temperature which risks destroying the organic fertilizing material. This cooking temperature is at least 200 "C and at most 380" C and preferably between 200 and 2500C.

The cooking time is generally a maximum of 80 seconds.

 The ammonia vapors 20 from the furnace 19 are recycled to the mixer 13.

 The sixth optional step is a screening step in a sieve 21 which makes it possible to remove the fine particles 23 whose size makes them unsuitable for use as fertilizer granules. These fine particles 23 are advantageously recycled to the mixer 13, which limits the formation of dust around the devices.

 Finally, the last step consists in passing the granules, the dimensions of which correspond to the envisaged application, through a silo 25 equipped with vertical ventilation ramps 27 allowing the granules to be cooled all at once. By way of example, a steel cooling silo 3 m in diameter and 8 m high is used, provided with 15 vertical ventilation ramps distributed uniformly over the periphery of the silo and one of which is arranged in the center. from the silo. Aeration is carried out by an air turbo-cooler.

 The cooling takes place very quickly in order to maintain the hardness of the granules. Indeed, if the cooling is too slow, these tend to disintegrate. The granules thus pass from 90 "C to 10" C in about 30 minutes.

 The invention also relates to the fertilizer obtained by such a process. This fertilizer preferably contains between 5 and 50% of organic elements.

Advantageously, it is in the form of granules of approximately 2 to 3 mm long.

 An exemplary embodiment of a fertilizer according to the invention will be given below.

EXAMPLE 1
A mineral mixture of 900 kg was produced containing the following elements:
ammonium sulfate: 238 kg
phosphorus: 233 kg
potash: 167 kg
lithothamne: 262 kg
This mixture corresponds to the following percentages of the various constituents:
S04 5% K20 10%
P205 7% CaO 11.53%
An organic mixture of 150 kg of sewage treatment plant sludge and 300 liters of slurry was carried out.

 After mixing, kneading and granulation, the granules were baked in an oven at 250 "C for 80 seconds. After screening the cooked granules, the granules were cooled in the silo by passing them from the temperature from 90" C to the temperature 10 C in 30 minutes.

 The product obtained is in the form of granules 2 to 3 mm long.

Claims (9)

 1. Method for manufacturing an organo-mineral fertilizer of the type consisting in carrying out a first mixture of mineral elements (1, 3) used in the composition of a mineral fertilizer, in carrying out a second mixture of organic elements (7 , 9) entering into the composition of an organic fertilizer, mixing the first and the second mixture and kneading the dough obtained in a kneader (13), characterized in that the following steps are carried out consisting in:  a) granulating the dough obtained,  b) bake the granules (17) obtained in the oven (19) without destroying the organic elements, and recover the steam released from the baking oven, cool it to liquefy it and return it to the mixer (13) and  - c) rapidly cooling the cooked granules.  2. Method of manufacturing an organo-mineral fertilizer according to claim 1, characterized in that the granulation is carried out in a granulator (15) so as to obtain granules (17) with a dimension of 2 to 3 mm .  3. Method of manufacturing an organo-mineral fertilizer according to claim 1, characterized in that the cooking is carried out at a temperature between 200 "C and 380" C, for a duration less than or equal to 80 seconds.  4. A method of manufacturing an organo-mineral fertilizer according to claim 1, characterized in that the cooling is carried out in a silo (25) equipped with aeration ramps (27) for brutally cooling the cooked granules of about 90 "C to about 10 C.  5. A method of manufacturing an organo-mineral fertilizer according to claim 1, characterized in that it comprises the additional step carried out between steps b) and c) consisting of sorting the granules by sieving.  6. Method of manufacturing an organo-mineral fertilizer according to the  claim 1, characterized in that the first mixture of mineral elements contains  at least one of the following: phosphate, magnesium hydroxide,  tricalcium phosphate, dolomite, potassium chloride, ammonium sulfate or  lithothamne.  7. A method of manufacturing an organo-mineral fertilizer according to claim 1, characterized in that the second mixture of organic elements contains at least one of the following elements: sludge from sewage treatment plants or slurry.  8. Organo-mineral fertilizer obtained by the process according to one of claims from 1 to 9 characterized in that it contains approximately 5% to 50% of organic elements.  9. organo-mineral fertilizer according to claim 8, characterized in that it is in the form of granules (17) of about 2 to 3 mm long.