RU2528999C1 - Method of purifying natural or waste water from fluorine and/or phosphates - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: method includes treating water with a calcium-containing composite sorbent while stirring to obtain solid treatment products and purified water. The sorbent consists of calcium sulphate particles immobilised on fibrillated cellulose fibres containing not less than 95 wt % of fibres with length of not more than 1.2 mm and not less than 55 wt % of fibres with length of not more than 0.56 mm, in amount of 100-1200 pts.wt of calcium sulphate per 100 pts.wt fibres. The solid treatment products obtained are a composite material consisting of fibres and calcium fluoride and/or phosphate particles immobilised thereon.

EFFECT: invention simplifies the method of treating water with extraction of fluorine or phosphates in a wide range of concentration thereof.

2 cl, 4 ex

Description

The invention relates to water treatment technologies and can be used to extract fluorine and phosphates from waste and natural waters containing various pollutants.

A known method of treating wastewater from fluoride ions, including its treatment with calcium hydroxide to a pH of 11-12, a coagulant (aluminum sulfate) and a flocculant, which uses silica gel slurry. The flocculant is fed into the water before treatment with calcium hydroxide (and.with. 1393802, C02F 1/58, publ. 07.05.88). The treatment is subjected to an acidic (pH 1.6-1.9) solution with a fluorine content of 500 mg / L. After adding all the reagents, the mixture is stirred, settled and the water drained. The precipitate is a mixture of calcium fluoride, a slurry consisting of many components, aluminum sulfate. The residual fluorine content in purified water is 0.3 mg / l.

The disadvantage of this method is that it is not possible to obtain calcium fluoride, not contaminated with other chemicals that complicate the processing and / or disposal of sludge.

A known method of wastewater treatment from phosphates and fluorides, including the introduction into the water of a mixture of milk of lime and magnetite with a mass ratio of components 4-2: 1, mixing the mixture, settling sediment for 30 minutes (SU 1673531, C02F 1/58, publ. 30.08 .91). Wastewater contains phosphates in an amount of 300 mg / l (P ₂ O ₅ ) and fluorides in an amount of 1000 mg / l (F), the reagent consumption is 1.5-2.5 g / l. When the height of the mixture column with its lag equal to 100 cm, the height of the sediment layer is 21 cm. The concentration of solids in the sediment is not more than 1.8%. The residual fluorine content in water, in mg / l, 0.82-1.56, phosphates 0.25-0.35, calcium ions 16.8 mg / l.

The disadvantages of the method include the long duration of deposition of the processed products, difficulties in processing the sludge due to its high water retention, a noticeable residual content of pollutants in the water.

There is also a method of purifying natural water from fluorine with its content of 2.6-5.0 mg / l using as a sorbent macroporous cation exchange resin in the form of particles with a size of 0.3-0.8 mm, treated with a solution of aluminum oxychloride and, accordingly, containing the active component in the form of immobilized aluminum ions (RU 2220911, C02F 1/28, 1/44, publ. 10.01.2004).

The method is carried out by contacting a stream of water with a sorbent in a column filled with it. The aluminum content in the sorbent 28.8 mg / cm ³ .

Upon contact of water with the sorbent, fluorine ions are immobilized in it until it is saturated with the formation of a composite material in the form of cation exchange particles with aluminum fluoride complexes immobilized as a product of processing.

The water treatment product is separated from the aqueous phase by discharge from the column.

To regenerate the sorbent, it is treated with a solution of aluminum oxychloride, followed by washing with water. The product of this treatment with complete regeneration of the sorbent is a solution of a mixture of aluminum fluoride and a certain amount of aluminum oxychloride. Information about the fate of this product is not contained in the description. The disadvantages of the method are the high complexity of the processes of preparing the sorbent, water purification, sorbent regeneration, as well as a low fluorine capacity.

New technical results of using the proposed method are to simplify the process of water treatment with the extraction of pollutants - fluorine and / or phosphates in a wide range of their concentrations in water, as well as providing the possibility of separate extraction of fluorine and phosphates from water.

These results are achieved in that the method of purification of natural or waste water from fluorine and / or phosphates involves treating water with stirring with a calcium-containing composite sorbent to obtain solid treatment products and purified water, removing them from water, while the sorbent consists of particles of calcium sulfate immobilized on fibrillated cellulose fibers (FCV) containing, in wt.%, at least 95% of fibers with a length of not more than 1.2 mm and not less than 55% of fibers with a length of not more than 0.6 mm, in an amount of 100-1200 wt. hours calcium sulfate per 100 parts by weight fibers, and as solid processing products receive a composite material consisting of these fibers and particles of calcium fluoride and / or calcium phosphate immobilized on them. A variant is possible in which water is treated in two stages with the extraction of phosphates in the first stage and fluorine in the second.

The sorbent is contacted with water by mixing them to obtain a dispersion with a sorbent concentration of 50-300 mg / L. The conversion of the sorbent to the processing product occurs as a result of ion exchange reactions. Separation of the processed products from the aqueous phase is carried out by pressure flotation with the production of sludge without the use of auxiliary substances, such as coagulants, flocculants, flotation agents.

To enable separate extraction of fluorine and phosphates from water, water is treated in two stages with the extraction of phosphates in the first stage and fluorine in the second. In this case, two identical plants are used, successively interconnected in the liquid phase.

The proposed method is as follows. In the most preferred embodiment of the application of the proposed method for water purification at an industrial site with an installation for purification, sorbent production is envisaged.

Water purification in a single-stage process is carried out using a plant consisting of a reactor-mixer, saturator, flotator and filter press (or centrifuge).

Sorbent with characteristics that are optimal for the purification of a particular water is prepared in the form of a dispersion with its concentration of 3%.

Naturally or waste water containing fluorine and / or phosphate containing a known concentration of these components and 50-2000 mg of sorbent per 1 liter of water is fed into the reactor-mixer at a given volumetric rate with stirring. As a result of ion exchange reactions, CaSO _{4 is} converted into CaF ₂ particles and, for example, Ca ₃ (PO ₄ ) ₂ , which, in comparison with CaSO ₄ , has a lower solubility, which are immobilized on PCV. In this case, the composite sorbent is converted into a processing product in the form of a composite material consisting of PCV and CaF ₂ and / or Ca ₃ (PO ₄ ) ₂ particles immobilized on them and, possibly, some residual amount of CaSO ₄ particles.

Next, the dispersion containing this material is sent to a saturator, in which it is saturated with air at a pressure of 2-3 atmospheres. From the saturator, the dispersion is sent to the flotator chamber, in which the suspended particles float to the surface of the water and form a flotation sludge. As the sludge is formed, it is taken out of the chamber by overflow or taken out with a scoop and sent for dehydration. Dehydrated sludge is disposed of.

In purified water, the fluorine and phosphate content corresponds to the solubility limit of CaF ₂ and Ca ₃ (PO ₄ ) ₂ salts. Suspended substances are not detected.

The following examples illustrate the possibilities of the proposed method.

Example 1. Purification is subject to water containing fluorine in an amount of 6.8 mg / L. A composite sorbent with desired characteristics is prepared. This is a sorbent consisting of fibrillated cellulose fibers (PCV) containing, in wt.%, At least 95% of fibers with a length of not more than 1.2 mm and not less than 55% of fibers with a length of not more than 0.6 mm, with an immobilized active component (AK) in the form of fine particles of CaSO ₄ . The ratio between AK and PCV in the sorbent, in parts by weight, is 100: 100, which is equivalent to the content of 500 mg CaSO ₄ in 1 g of sorbent.

Water is supplied to the mixer reactor, to which the dispersion of the sorbent is also based on the calculation of 50 mg of sorbent per 1 liter of water, or 25 mg of AK per 1 liter, the fluorine capacity of which is 6.9775 mg. In the reactor, as a result of the ion exchange reaction, the composite sorbent is converted into a product in the form of particles of a composite material in an amount of 38.972 mg / l, consisting of 25 mg / l of PCV with the above characteristics and 13.972 mg / l of CaF ₂ particles immobilized by them. The degree of use of AK is 97.45%.

Next, the dispersion from the reactor-mixer is sent to a saturator, in which it is saturated with air at its elevated pressure. From the saturator, the dispersion is sent to a flotator, in the chamber of which particles of the composite material are floated to form a slurry. It is taken out, dehydrated in a filter press or in a centrifuge and disposed of, for example, by using thorium from its chloride solution as an sorbent to obtain a composite material containing ThF ₄ .

Purified water contains fluorine in an amount of 0.3 mg / L. Suspended substances are not detected.

Example 2. In contrast to example 1, water is purified from phosphates present in water, for example, in the form of salts of phosphoric acid, with their content, calculated on P ₂ About ₅ , 15 mg / L. The sorbent is consumed in an amount of 88 mg / l of water, or 44 mg of AA per 1 l of water, the capacity of which but phosphate is 15.29 mg. As a result of ion-exchange reactions, a composite material is obtained in an amount of 76.78 mg / l, consisting of 44 mg / l of PCV, and 32.778 mg / l of Ca ₃ (PO ₄ ) ₂ particles immobilized by them. The degree of use of AK is 98.1%. Phosphates and suspended solids are not detected in purified water.

Example 3. Unlike example 1, water containing 29 mg / l of fluorine and 24 mg / l of phosphates is purified, the sorbent is taken with the ratio AK: FCV = 650: 100 (this is 866.66 mg AK in 1 g of sorbent) and consumed it in an amount of 200 mg / l of water or, based on AK, 173 mg / l. As a result of ion-exchange reactions, 59.58 mg / L CaF ₂ and 52.44 mg / L Ca ₃ (PO ₄ ) _{2 are formed} , which are immobilized on the PCV with the formation of 138.5 mg / L composite material - the product of purification. The utilization rate of AK 99.8%.

Example 4. Unlike example 1, water containing 510 mg / l of fluorine and 320 mg / l of phosphates is purified, and purification is carried out in 2 steps. The sorbent is taken with a ratio of AK: FCV = 1200: 100 (923.07 mg of AK per 1 g of sorbent). At the first stage, the sorbent is consumed in an amount of 1.0 g per 1 liter of water. The solubility product (PR) of Ca ₃ (PO ₄ ) ₂ is many orders of magnitude lower than that of CaF ₂ ; therefore, only calcium phosphate is formed in the reactor as a result of ion-exchange reactions involving CaSO ₄ , while CaSO ₄ is completely consumed. The resulting Ca ₃ (PO ₄ ) ₂ particles in an amount of 699.26 mg / L are immobilized on the PCV with the formation of a composite material in the amount of 776.18 mg / L, in which the proportion of the PCV is 76.92 mg.

The dispersion of the composite material is sent to a saturator, then to a flotator, in which it is separated in the form of sludge from the liquid phase containing 510 mg / l of fluorine. It is sent to the reactor-mixer of the second processing stage.

At the second stage, the sorbent is consumed in an amount of 2.0 g per 1 liter of water. In the reactor, as a result of ion-exchange reactions, CaSO _{4 is} converted to CaF ₂ in an amount of 1047.9 mg / L. The utilization rate of AK is 98.97%.

Particles of CaF _{2 are} immobilized on PCV with the formation of a composite material in the amount of 1201.74 mg / l of dispersion. She is sent to a saturator, then to a flotator.

Water after both stages of purification contains 2867 mg / l Na ₂ SO ₄ . It can be used in the production of sorbent based on calcium sulfate.

When cleaning acidic water containing, for example, fluorine in the form of a solution of hydrofluoric acid or phosphate in the form of a solution of phosphoric acid, the water is first neutralized with sodium hydroxide to form solutions of NaF and Na ₃ PO ₄ , and then it is treated by the proposed method. If necessary, purify water with a very high content of fluorine and / or phosphate; it can be diluted to an acceptable level before treatment.

Claims (2)

1. A method of purifying natural or waste water from fluorine and / or phosphates includes treating water with stirring with a calcium-containing composite sorbent to obtain solid treatment products and purified water, removing them from water, the sorbent consisting of calcium sulfate particles immobilized on fibrillated cellulose fibers containing in wt.% not less than 95% of fibers with a length of not more than 1.2 mm and not less than 55% of fibers with a length of not more than 0.6 mm, in an amount of 100-1200 wt.h. calcium sulfate per 100 parts by weight fibers, and as solid processing products receive a composite material consisting of these fibers and particles of calcium fluoride and / or calcium phosphate immobilized on them. 2. The method according to claim 1, characterized in that when water is purified from fluorine and phosphates, it is treated in two stages with the extraction of phosphates in the first stage and fluorine in the second.