EA025226B1 - Method for production of granular compound fertilizers - Google Patents

Abstract

The present invention discloses a method for production of granular compound fertilizers comprising mixing the solid components within 1 to 10 min with moist components, obtained from the tubular reactor, arranged in the bottom part of a mixer, wherein the alkaline components were neutralized with mineral acids. The temperature of a mixture is raised up to 140°C. Ammonia aqueous solutions, containing ammonium nitrate, urea, ammonium sulphate, calcium nitrate, magnesium nitrate or mixtures thereof, potassium hydroxide or potassium salts or mixtures thereof are used as the alkaline component, whereas nitric, phosphoric or sulphuric acids - as the acidic component. The amount of nitrogen in the granulated product is from 5 to 25%, by weight and sulphur - up to 15% by weight.

Description

The present invention relates to the field of fertilizers and is suitable for producing complex granular nitrogen-phosphorus-potassium (ROS) fertilizers with the addition of minor plant nutrients and trace elements.

State of the art

A known method of producing complex fertilizers, which consists in the fact that the fertilizer is obtained by mixing three different solid free-flowing fertilizers, followed by wetting the mixture with water and / or water vapor and adding crushed clay (US patent No. 5749936, priority date 07.06.1996, published in 1998 .). When using this method of obtaining the yield of the commodity fraction of fertilizers increases, and the quality of the product improves. However, it is necessary to prepare a special clay slurry, and the concentration of ballast clay in the finished fertilizer can reach 5 wt.%, Which leads to a decrease in the concentration of nutrients.

The closest known technical solution is the method of producing complex fertilizers, where the components of solid fertilizer are mixed in a granulator with the products of the interaction of mineral fertilizers and ammonia, after which the mixture is granulated, dried and separated (Lithuanian patent No. 4720, priority date 11/29/1999, published in 2000 g.). The disadvantages of this method are the insufficiently high concentration of nitrogen, as well as the fact that the amount of the fine fraction sent for processing reaches 30-35 wt.%, Which, in turn, reduces the efficiency of the granulating device.

SUMMARY OF THE INVENTION

According to the present invention, a method for producing complex granular fertilizers comprises mixing free-flowing solid fertilizer components for 1-10 minutes together with moistened components obtained from a tubular reactor located at the bottom of the mixer, where the alkaline components of the fertilizer are neutralized with mineral acids; increasing the temperature of the mixture to 140 ° C; granulation by spraying with acidified water and / or steam heating; drying, separating and returning the finely divided fraction of the granular product to the mixer. As a result of mixing the alkaline component with the acid component, an exothermic reaction occurs in the tubular reactor. The alkaline component consists of aqueous ammonia solutions containing ammonium nitrate, urea, ammonium sulfate, calcium nitrate, magnesium nitrate or mixtures thereof, potassium hydroxide or potassium salts or mixtures thereof. The acid component consists of nitric, phosphoric or sulfuric acids. The molar ratio of alkaline and acid components is: ΝΗ ₃ : Η ₃ ΡΟ = 1-3: 1, or ΝΗ ₃ : Η ₂ 8Ο ₄ = 0.9-2: 1, or ΝΗ ₃ : ΗΝΟ ₃ = 0.9-1: 1. The amount and ratio of all components are selected so that the amount of nitrogen in the granular product is from 5 to 25 wt.%, And sulfur - up to 15 wt.%. Minerals of calcium, magnesium and boron, or mixtures thereof, can be mixed with solid components of the fertilizer.

Obtaining complex granular mineral fertilizers is carried out according to the following flow chart (drawing).

DETAILED DESCRIPTION OF THE INVENTION

The free-flowing solid components intended for fertilizer are weighed from the container (1) on the balance (2) and fed through mechanical feeders (3, 5) and an elevator (4) to the mixer (6), where they are mixed with moistened components obtained in a tubular reactor located at the bottom of the mixer, where the alkaline components of the fertilizer from the tank (7) are neutralized with mineral acids from the tank (8) and subjected to granulation. Granulation is continued and completed in the granulator (9). The resulting fertilizer is dried in an oven (10) using flue gases from the furnace (11). Granular fertilizer is raised using an elevator (12) to the first sifter (13), from where the finely dispersed fraction is returned to the mixer (6), and the rest is cooled in a refrigerator (14); then they are separated on the second sifter (15), after which the commodity part is sent for storage or subjected to conditioning with additives that improve the quality before being stored. The finely dispersed fraction is returned to the mixer (6), and too large particles are crushed in a crushing plant (16) and separated on the second sifter (15). If it is necessary to add calcium, magnesium and boron minerals, their mixtures or other nutrients suitable for plants to the fertilizer, they are loaded into the hopper (1).

The concentration of nutrients in the complex granular fertilizer, its physicochemical properties and commercial qualities were determined using standard testing methods.

The essence of the present invention is illustrated by the following examples.

Example 1

In the tubular reactor of the pilot plant, 200 kg / h of a solution containing 12 wt.%, Ammonia, 42.5 wt.%, Urea, 45.5 wt.%, Water, neutralized 72 kg / h of 98% concentrated sulfuric acid in a molar ratio of ΝΗ ₃ : Η ₂ 8Ο ₄ = 1.95: 1. The resulting suspension was mixed in a mixer with 109 kg of diammonium phosphos containing 18% nitrogen and 46% phosphorus pentoxide, with 430 kg of ammonium sulfate containing 21% nitrogen, with 200 kg of ammonium nitrate containing 34% nitrogen, and with 83 kg potassium chloride containing 60% potassium oxide. The resulting fertilizer was granulated, dried at a temperature of 80 ° C and divided depending on the particle size. Received ROS fertilizer has a ratio of 24: 5: 5. The output of a commercial fraction (with a granule diameter of 1-5 mm) of the fraction was 91%. The tensile strength of the granules (3 mm) in compression was 3520 g / gran.

Example 2

In the tubular reactor of the pilot plant 100 kg / h of a mixture of an alkaline component of the same composition as in example 1, neutralized 35 kg of 98% concentrated sulfuric acid, in a molar ratio of ΝΗ ₃ : Η ₂ 8Ο ₄ = 2: 1. The resulting suspension was mixed with 265 kg of ammonium sulfate, 79 kg of urea containing 46% nitrogen, 292 kg of diammonium phosphate, 50 kg of ammophos containing 12% nitrogen and 52% phosphorus pentoxide, and 267 kg of potassium chloride. The fertilizers were further processed further in the same manner as in Example 1. The obtained ROS fertilizer had a ratio of 16:16:16. The yield of the product fraction (with a granule diameter of 1-5 mm) was 93%. The compressive strength of the granule was 3320 g / gran.

Upon receipt of the complex granular fertilizer according to the method according to the present invention, an exothermic reaction occurs in a tubular reactor when neutralizing alkaline components with acids, the thermal effect of which accelerates the formation of granules in the mixer, reduces the amount of the fine fraction of the product sent for processing by 20%, reduces energy consumption per unit of production and increases the yield of the commercial fraction to 93%. The compressive strength of the granule increases to 3200-3500 g / gran. The fertilizers obtained by this method have a high concentration of plant nutrients (about 50% ROS and up to 25% nitrogen). In addition, these fertilizers are enriched with a minor nutrient important to plants - sulfur (up to 15%). Fertilizers obtained by the method according to the present invention may contain plant nutrients in various ratios and amounts. This expands the range of fertilizers and the scope of their application. The fertilizer production process is becoming cheaper, more efficient and environmentally friendly.

Claims (6)

CLAIM 1. The method of obtaining complex granular nitrogen-phosphorus-potassium (ROS) fertilizers, including mixing the solid components of the fertilizer in the mixer, moistening with water and / or water vapor, granulation, drying, fractionation, returning the finely dispersed fraction to the mixer and conditioning, characterized in , what: (a) the solid components of the fertilizer are mixed in the mixer for 1-10 minutes with the wet components obtained in the tubular reactor located at the bottom of the mixer, where the alkaline components of the fertilizer containing urea are neutralized with mineral acids; (b) the temperature of the mixture is increased to 140 ° C to obtain a homogeneous mass; (c) the resulting homogeneous mass is granulated at a lower temperature by spraying with acidified water and / or steam. 2. The method of obtaining complex granular nitrogen-phosphorus-potassium (ROS) fertilizers according to claim 1, characterized in that the granule yield is 91-93%. 3. The method of producing complex granular nitrogen-phosphorus-potassium (ROS) fertilizers according to claim 1 or 2, characterized in that the compressive strength of the obtained granules is 32003500 g / gran. 4. The method of obtaining complex granular nitrogen-phosphorus-potassium (ROS) fertilizers according to any one of claims 1 to 3, characterized in that the alkaline component includes aqueous ammonia solutions containing ammonium nitrate, ammonium sulfate, calcium nitrate, magnesium nitrate or mixtures thereof , potassium hydroxide or potassium salts or mixtures thereof, and the acid component contains nitric, phosphoric or sulfuric acids in a molar ratio of ΝΗ ₃ : Η ₃ ΡΟ ₄ = 1-3: 1, or ΝΗ ₃ : Η ₂ 8Ο ₄ = 0.9-2: 1, or ΝΗ ₃ : ΗΝΟ ₃ = 0.9-1: 1. 5. The method of obtaining complex granular nitrogen-phosphorus-potassium (ROS) fertilizers according to any one of claims 1 to 4, characterized in that the amount and ratio of all components is selected so that the granular product contains from 5 to 25 wt.% Nitrogen and up to 15 wt.%. sulfur. 6. A method for producing complex granular nitrogen-phosphorus-potassium (ROS) fertilizers according to any one of claims 1 to 5, characterized in that calcium, magnesium and boron minerals or mixtures thereof are added to the components of the granular fertilizer.