RU2167133C1 - Method of clear, liquid combined fertilizer producing - Google Patents

Abstract

FIELD: production of fertilizers. SUBSTANCE: invention relates to method of production of liquid combined fertilizers. Method of production of clear, liquid combined fertilizers involves neutralization of wet-process phosphoric acid with mass part of P₂O₅ 50-52% with potassium-containing reagent and addition of sequestering agent in the amount 0.5-5.0% of clear, liquid combined fertilized to wet-process phosphoric acid before neutralization followed by addition macroelements and trace elements. Organic compounds of the group including hydroxyethylidenediphosphonic acid, nitriletrimethylenephosphonic acid, diethylenetriamihepentaacetic acid, ethylenediaminedisuccinic acid, EDTA and dihydroxybutylenediaminetetraacetic acid are used as sequestering agent. Trace elements are added to clear, liquid combined fertilizer composition as chelates with compounds taken among the same group. Method ensures to use low-priced phosphorus-containing raw and obtain stable liquid combined fertilizers. EFFECT: improved method of production, simplified technology. 5 cl, 3 ex

Description

 The invention relates to the field of complex fertilizers used in agriculture in intensive technologies for growing agricultural products both in open and in closed ground.

 There is a known (according to USSR author's certificate N 1060603 of 05.24.82, MKI C 05 G 1 / 0.6; C 05 D 9/02) a method for producing fertilizers for hydroponics, including the dissolution of salts of nitrates, phosphates, sulfates, potassium chlorides, calcium, magnesium, ammonium, iron and trace elements in water, evaporation of the initial solutions and their mixing. In order to simplify the process and increase stability, the initial solutions are pre-mixed, then added to the complexon-trilon-B mixture in an amount of 0.07-0.25 g / mol per 1 g-ion of the sum of multivalent cations, and then evaporated to a moisture content 5-20 wt.%.

As the disadvantages of the above method of obtaining housing and communal services should be noted:
1. The use of salts as starting ingredients is not economical.

 2. The presence of the stage of evaporation of the obtained solutions leads to increased energy consumption for the production of HCS.

The closest in technical essence and the achieved effect is the method of obtaining complex liquid fertilizers described in the patent CPP N 93426 from 12.30.85, MKI C 05 G 1/00. According to this method, at the first stage, a solution of macronutrients is prepared as follows: phosphoric acid H ₃ PO _{4 is} neutralized with potash, while the ratio of reagents varies in the range: (0.5-0.67) -1.0.

Then, the nitrogen component is introduced into the neutralized mixture as a mixture of NH ₄ NO ₃ : CO (NH ₂ ) ₂ in the following ratio: (1-0) - (3.9-4.9: 1).

At the 2nd stage, a ME solution in chelate form is prepared, for this, 0.12 mol of a chelate (complexing agent) is dissolved in water, 2 to 3 moles of NH ₃ are added and 10-15% of ME in the form of salts are added.

At the 3rd stage, both solutions are mixed to obtain a finished product containing:
N - 12%; P ₂ O ₅ - 6.0%; K ₂ O - 8%; ME - 0.4%.

The disadvantages of this method should be noted:
1. In order to obtain stable systems, it is necessary to use either thermal phosphoric acid or H ₃ PO ₄ purified from impurities (ballast) to the level of food condition. Otherwise, when neutralizing H ₃ PO _{4 with} potash, a large number of colloidal gels are formed, which are difficult to get rid of.

 2. The inability to use cheaper phosphorus-containing raw materials - extraction phosphoric acid (EPA).

The above disadvantages of both the analogue and the prototype are eliminated in the method for producing transparent liquid complex fertilizers, including the neutralization of EPA with a potassium-containing reagent and the subsequent introduction of additional macro- and micronutrients, in order to stabilize the composition of PUFAs and transfer the ballast impurities of EPA into a form easily digestible by plants, into Before neutralization, the sequestering agent is introduced in the amount of 0.5-5.0% by weight of the PUFA, and the organic compound selected from PPs containing: hydroxyethylenediphosphonic acid (HEDPA), nitrile trimethylene phosphonic acid (NTP), diethylene triamine pentaacetic acid (DTPA), ethylenediamino succinic acid (EDDYA), ethylenediaminetetraacetic acid dibutyl acid (DETA). As a phosphorus-containing reagent, extraction phosphoric acid with a mass fraction of P ₂ O _{5 of} 50 to 52% is used, and trace elements are added to the composition of the PUFA in the form of a complexonate with an organic compound selected from the above group. The magnesium-containing component of PZhKU is entered in the form of a complexonate with OEDFK.

Thus, the introduction of a sequestering agent to the stage of neutralizing EPA with a potassium-containing reagent (potash or KOH) leads to the formation of transparent and stable liquid complex fertilizers, while the ballast impurities of EPA (Fe, Mg, Ca, etc.) are converted into a complex form - easily digestible by plants. The introduction of sequestering agents after the stage of neutralization leads to their significant (2-3 times) cost overrun, which is not economical and also worsens the processability, since the dissolution of precipitated gel-like precipitates is very slow. The most common sequestering agents used in the manufacture of liquid and solid fuels are ammonium polyphosphates and polyphosphoric acids (PFC). However, their norm can reach from 20 to 60% P ₂ O ₅ of its total content in the product according to the data given in "Technology of phosphate and complex fertilizers." Moscow, Chemistry, 1987, p. 280.

 The most detailed features of our proposed method for producing transparent liquid complex fertilizers are shown in the examples below.

Example 1. 100 kg of EPA containing - 50% P ₂ O ₅ ; 0.1% CaO; and 0.5 Fe ₂ O ₃ , mixed with 591.7 kg of water, and then introduced into a dilute solution of phosphoric acid - 5.0 kg of complexon - HEDPA. After complete dissolution of the complexone, phosphoric acid is neutralized with potash (60% K ₂ O) in an amount of 83.3 kg. When neutralized, 23.4 kg of CO _{2 are released} . After neutralizing the EPA, a solution containing a mixture of potassium phosphates is obtained, namely: KHPO ₄ - 46.89 kg and K ₂ HPO ₄ - 62.51 kg. Urea in the amount of 217.4 kg is introduced into the resulting solution with stirring. After complete dissolution of the urea sequentially introduced: - 5.55 kg Cu • EDTA; Zn • DTPA and 11.3 kg H ₃ BO ₃ .

The result is - 1000 kg PZHKU of the following composition:
N - 10%; P ₂ O ₅ - 5%; K ₂ O - 5%
and trace elements in the form of complexonates -
Cu - 0.1%; Zn - 0.1%; Ca - 0.014%; Fe - 0.07%; B - 0.2%
To obtain irrigation solutions, PUFAs are diluted 100 times.

Example 2. 196 kg of EPA containing - 51% P ₂ O ₅ ; 0.1% CaO; and 0.5% Fe ₂ O ₃ , mixed with 512.86 kg of water, and then 7.5 kg of complexon - DTPA are introduced. After complete dissolution of the complexone, phosphoric acid is neutralized with potash (60% K ₂ O) in an amount of 110 kg. Upon neutralization, a solution is obtained containing - 191.5 kg of monopotassium phosphate. Ammonium nitrate (N 34%) in the amount of 147 kg is introduced into the resulting solution with stirring. After complete dissolution of amcelite, the solution is sequentially introduced:
- 9.09 kg of Cu • DTPA (Cu - 11%); Zn • OEDP (Zn - 16%) - 6.25 kg and H ₃ BO ₃ (17.7%) - 11.3 kg.

The result is - 1000 kg PZHKU of the following composition:
N - 5.0%; P ₂ O ₅ - 10%; K ₂ O - 6.6%
and trace elements in the form of complexonates -
Cu - 0.1%; Zn - 0.1%; B - 0.2%; Ca - 0.027%; Fe - 0.13%.

 To obtain irrigation solutions PZHKU diluted 150 times.

Example 3. 102.56 kg of magnesium sulfate (7-water) is dissolved in 426 kg of water, and then 50 kg of complexon - OEDPK are introduced. The resulting solution of magnesium complexonate is mixed with 192.3 kg of EPA containing - 52% P ₂ O ₅ , 0.1% CaO; and 0.5% Fe ₂ O ₃ . The diluted phosphoric acid solution is neutralized with a 52% KOH solution in an amount of 229.13 kg.

The result is 1000 kg of PUFA of the following composition:
N - 0%; P ₂ O ₅ - 10%; K ₂ O - 10%; Mg - 1%; Ca - 0.025%; Fe - 0.125%.

To obtain irrigation solutions, PUFAs are diluted 100 times. The use of this method of obtaining fatty acids will allow:
- use more affordable and cheaper phosphorus-containing raw materials;
- receive stable liquid complex fertilizers according to simplified technology in a wide range of variation by nutrients in accordance with the phases of vegetation of agricultural crops (in spring, summer and autumn).

Literature
1. Auth. St. USSR N 1060603 from 05.24.82, MKI C 05 G 1 / 0.6; C 05 D 9/02.

 2. Patent C.P.P. N 93426 from 12.30.85, MKI C 05 G 1/00.

 3. Technology of phosphate and complex fertilizers. Moscow, Chemistry, 1987, p. 280.

Claims (5)

 1. A method of obtaining a transparent liquid complex fertilizer (PZHKU) by neutralizing the extraction of phosphoric acid (EPA) with a potassium reagent and the subsequent introduction of additional macro- and microelements, characterized in that the ballast impurities of the EPA are converted into a form easily digestible by plants, for which they are introduced into the EPA before neutralization sequestering agent in an amount of 0.5 - 5.0% by weight of PUFA.  2. The method according to claim 1, characterized in that the organic compound selected from the group consisting of HEDPA, NTF, DTPA, EDDYAK, EDTA and DBTA is used as a sequesting agent. 3. The method according to claim 1 or 2, characterized in that they use extraction phosphoric acid containing 50 to 52 wt.% P ₂ O ₅ .  4. The method according to any one of claims 1, 2 and 3, characterized in that the trace elements in the composition of the PUFA are introduced in the form of a complexonate with an organic compound selected from the group according to claim 2.  5. The method according to any one of claims 1, 2, 3 and 4, characterized in that the magnesium-containing component is introduced into the composition of the PUFA in the form of a complexonate with OEDPA.