SU793968A1 - Method of producing boron-containing fertilizer - Google Patents

Description

The invention relates to the production of mineral fertilizers containing boron.

A known method of producing boron-containing fertilizers by sintering 5 previously milled into powder of boron-containing silicate rocks with lime com [1] ·

A disadvantage of the known method is the complexity of the technology for preparing this fertilizer, which requires high costs for grinding the original boron-containing rock and cake, as well as for firing, at high temperature. The resulting product contains boric anhydride in an easily digestible form.

The closest in technical essence and the achieved result to the proposed one is a method for producing boron-containing fertilizer by introducing boron-containing waste products of production £ 2] into the crushed dolomite limestone. As production waste, a brown coal zone 25 and blast furnace slag are used.

The disadvantages of this method are the complexity of waste processing, as well as the presence of boron in a water-soluble form, which leads to 30 easy leachability from the soil by rainwater.

The purpose of the invention is to simplify the process and increase the content of boron compounds, slowly soluble in 2% carbonic acid. This does not entail a strong leaching of boron with respectable moisture and at the same time is easily absorbed by plants.

This goal is achieved by the fact that in the known method for producing boron-containing fertilizer by introducing boron-containing production waste into the ground limestone, waste from the production of calcium borate or sodium perborate is used with a weight ratio of ground limestone and boron-containing waste of 10: 0.3-0.6. These wastes contain 1.0-2.0% boric anhydride in a form that is slowly soluble in 2% carbonic acid.

PRI me R. In the process of preparing limestone flour in a wet way, a calcium borate waste pulp with a ratio of T: W = 1: 3 is introduced into the thickening operation at T: G at the rate of 5 m ⁵ waste pulp per 100 m * limestone pulp. The content of BjOj in the waste is 1.6%. When thickening in the titer · the products are mixed and after filtration and drying receive boron fertilizer with a content of 0.08%.

Example 2. The finished limestone flour is mixed with a dry powder, a waste of calcium borate waste with a content of Bj> Oj of 2% based on 3 parts by weight. powder per 100 parts by weight flour. The result is a boron-containing fertilizer with a content of B ^ Oj of 0.6%.

Example 3. In the process of preparing limestone flour in a wet way, a sodium perborate waste pulp with a ratio of T: W = 1: 3 is introduced into the thickening operation at T: W = 1: 3 at the rate of 5 m ^{e of} waste pulp '5 per 100 limestone pulp . The waste content is 1.5%.

Upon thickening in the thickener, the products are mixed and after filtration and drying a boron-containing 20 fertilizer with a content of B- ^ Oj of 0.075% is obtained.

Example 4. Ready limestone flour is mixed with a dry powder of waste sodium perborate with a content of VLO ^ 1.8% based on 3 parts by weight. 25 powder per 100 parts by weight flour. The result is a boron-containing fertilizer with a BjOj content of 0.05%.

Example 5. The finished limestone flour is mixed with dry powder __ waste sodium perborate with a BjOj content of 1.0% based on 6 parts by weight. powder per 100 parts by weight flour. The result is a boron-containing fertilizer with a BjO ₃ content _of 0.06%.

Boron-containing fertilizer obtained by introducing wastes from the production of calcium borate and sodium perborate into limestone flour expands the raw material base for the production of boron-containing fertilizers and has a significant effect on crop yield through a complex effect on soil acidity and the long-term effect of boron microadditives.

Claims (2)

(54) METHOD FOR OBTAINING A BORODTED FERTILIZER TITLE- Products are mixed and after filtration and drying, a boron-containing fertilizer with a BjO content of 0.0–8% is obtained. Example 2. Ready limestone flour is mixed with dry powder of calcium borate waste with a content of 2% at the rate of 3 parts by weight. powder per 100 weight.h. flour. As a result, boron-containing fertilizer is obtained with a content of 0.6%. Example 3. In the process of preparing limestone flour by a wet method, a pulp of sodium perborate waste with a ratio T: W of 1: 3 at the rate of 5 m waste pulp per 100 K pulp of limestone powder is introduced into the thickening operation at T: W 1: 3. Waste content is 1.5%. When condensed into thickeners, they are mixed and after filtration and drying, a boron-containing fertilizer is obtained with a B-jOj content of 0.075%. Example 4. Prepared lime powder is mixed with dry sodium perborate powder with a VLOa content of 1.8% at the rate of 3 parts by weight. powder per 100 weight.h; flour. As a result, a boron-containing fertilizer is obtained with a BjOj content of 0.05%. Example 5. Prepared lime powder is mixed with dry powder of sodium perborate waste with a content of 1.0% from a calculation of 6 wt. Hours. powder per 100 weight parts of flour. As a result, a boron-containing fertilizer is obtained with a BjOj content of 0.06%. Boron-containing fertilizer obtained by introducing waste products of calcium borate, sodium perborate into limestone flour, expands the raw material base for the production of boron-containing fertilizers and has a significant impact on crop yield by combining the acidity of the soil and the long-term effect of micro boil-boron. Claim 1. Method for producing boron-containing fertilizer by introducing boron-containing waste into ground lime, characterized in that, in order to simplify the process and increase the content of boron compounds slowly soluble in 2% carbonic acid, waste of calcium borate or sodium perborate with a weight ratio of ground lime and boron-containing waste 10: 0.3-0.6, 2. Method POP.1, characterized in that the waste contains 1.0-2.0% boric anhydride in the form of honey soluble in 2% carbonic acid. Sources of information taken into account in the examination 1. USSR author's certificate number 61624, cl. C 05 D 9/02, 27.12.38. 2. Patent of the GDR No. 78253, CL.16 C 3/02 (C 05), 12.12.70 (prototype).