RU1790997C - Method of preparing ferromagnetic sorption reagent - Google Patents

Abstract

The method includes introducing alkali into the ferrous iron solution and sparging the air. The resulting reagent is used in water purification systems from heavy metal ions. 1 s p, f-ly, 1 tab.

Description

The invention relates to water purification and can be used in systems for purification of metalworking, radio engineering, local industry, as well as in the purification of natural waters from ions of heavy and suspended solids.

A known method of producing a reagent by treating ferrous salt with a 5% solution of milk of lime at pH 9.0 and heating to 70 ° C.

The disadvantages of this method are the high heat consumption, insufficient quality of water treatment.

A method for producing a reagent for treating heavy metal-containing wastewaters is known. A solution of pH 8 containing Fe (II) ions is treated with air or another oxygen-containing gas to oxidize compound i Pz / I). After the completion of the oxidation reaction, the gas supply is stopped, alkali and Fe (II) ions are added to the solution to neutralize and stirring is carried out to obtain oxides with strong magnetic properties. Upon subsequent supply of the oxidizing gas, the remaining Fe (II) ions are converted into iron oxyhydroxide (FeOOH), which forms a sorbing layer on the surface of particles with strong magnetic properties.

This method eliminates the energy consumption for raising the temperature of the solution to 70 ° C. However, the implementation of the method takes place in two stages, which complicates the process of producing the reagent and reduces its sorption capacity.

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The purpose of the invention is to simplify the process and increase the capacity of the reagent for heavy metals.

This goal is achieved by the fact that alkali is added to a solution containing Fe (II) ions to a pH of 9.4 - 9.6 at an initial concentration of Fe (II) ions of 5 - 6 g / l, and air sparging is carried out at a flow rate of 0.7 - 0.9 cm3 / s to form ferromagnetic particles. Air is bubbled at 15 ... 20 ° C.

As a result, particles of uniform composition are obtained, consisting of chemically bonded D6 oxides of two t-ferrous iron. The pH of the preparation of the reagent is 9.4 ... 9.6 t. K. At higher values, well-structured, crystalline forms of the ResO3 pN20 type are formed. having a small sorption capacity.

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At lower pH values, the formation of the reagent is delayed.

At higher initial concentrations of Fe (II), the salt concentration of the solution increases, which reduces the absorption capacity, and the production time increases. An increase in air flow leads to reagent reagent, which impairs its magnetic properties. During sorption, the ions of heavy metallrv (YTM) add up to Fe {5RiteShukE str: uktur. 8 particulars Cr (Vl) ions change valency and enter the structure in the form of Cr ().

Example. Take a solution containing Fe (ll). The concentration of Fe (II) was adjusted to 5.5 g / l, NaOH was added to a pH of 9.5. After air treatment with a flow rate of 0.8 cm3 / s, a suspension of the reagent is obtained. Tests of the resulting reagent were performed. The reagent is introduced into a solution of Cr (VI) with a concentration of 20 mg / L. And then they remove it on a magnetic separator. The concentration of chromium ions in the solution is determined. The results of this and other examples are tabulated. Examples 4,5 are made on the reagent prototype.

Using the proposed method allows a simple and reliable preparation of a reagent providing efficient sorption of heavy metals.

Claims (2)

1. A method of producing a ferromagnetic sorbing reagent based on iron oxides, comprising introducing alkali into a solution containing divalent iron. And sparging air through the resulting suspension, characterized in that, in order to simplify the process and increase the capacity of the reagent for heavy metals, alkali is introduced into a solution containing ferrous iron in an amount of 5-6 g / l to a pH of 9.4-9.6, and air is bubbled with a flow rate of 0 / 7-0.9 cm3 / s. 2. The method according to claim 1, characterized in that the air is bubbled at 15-20 ° C,