RU47248U1 - FILTER FOR CATALYTIC PURIFICATION OF NATURAL AND SEWAGE FROM POLLUTION - Google Patents

Abstract

The utility model relates to devices for natural water treatment and wastewater treatment by filtration.

The purpose of the utility model is to increase the efficiency of catalytic purification by 10-15% in terms of COD, turbidity and color, while simultaneously increasing the filter performance by 1.5 times.

A filter for catalytic purification of natural and wastewater from pollution containing a container, pipelines for supplying raw water and drainage of purified water, a support layer, a system of distribution trays, a filtering two-layer loading arranged with a filter layer of a heterogeneous metal complex catalyst and a filter layer of sand, in which the ratio of the height of the filter layer heterogeneous metal complex catalyst to the standard height of the sand filter layer is from 0.5 to 1.0, while the filter layer the catalyst is arranged first along the water, the filtering sand layer second, and the grain diameters of the filtering layers increase - heterogeneous metal complex catalyst 4-7 times, and sand 1.5-2.0 times relative to the normalized equivalent grain diameter in the sand layer .

Description

The utility model relates to devices for water treatment and can be used to purify natural waters from pollution at wastewater treatment plants for drinking water and to treat wastewater at wastewater treatment plants of any capacity.

A known filter including a system for supplying and discharging waste water, a support layer and a two-layer filtering load of sand and anthracite (see Abramov N.N. Water supply; M. Stroyizdat, 1982, p. 251-252). The disadvantage of this device is the lack of efficiency of water purification by dissolved organic contaminants and not high efficiency by turbidity and color.

The closest in technical essence are devices using the method according to the patent of the Russian Federation No. 2108298, where a heterogeneous metal complex catalyst with a layer height is used for liquid-phase oxidation of dissolved organic pollutants and removal of suspended solids.

However, it has several disadvantages:

- the catalyst bed height is not optimized;

- the small height of the catalyst layer does not allow the stable operation of industrial filters with high performance, because it is impossible to evenly distribute the catalyst layer over the filter area after washing it;

- low filtering speed leads to non-competitive filter performance;

- low efficiency of reducing organic pollution;

- lack of data to reduce turbidity and color during water treatment.

The objective of the utility model is to increase the efficiency of catalytic purification using heterogeneous metal-complex catalysts for chemical oxygen consumption (COD), turbidity, and water color by 10-15%, while at the same time increasing the productivity of the device in relation to normalized for normal operation by 1.5 times.

The essence of the utility model is that the filter for catalytic purification of natural and wastewater from pollution, which includes a tank, a system for supplying and discharging treated water, a supporting layer, a two-layer filtering load, while the filtering two-layer loading is arranged with a filtering layer of a heterogeneous metal complex catalyst and a filtering layer of silica sand, in which the ratio of the height of the filtering layer of the metal complex catalyst to the standard height of the filtering sand layer with leaves from 0.5 to 1.0, while the filter layer of the catalyst settles first in the direction of movement of water, and the filter layer of sand - the second, and the diameters of the grains of the filter layers increase - heterogeneous metal complex catalyst by 4-7 times, and sand by 1, 5-2.0 times in relation to the normalized equivalent grain diameter in the sand layer.

The task is achieved in that the fast filter is performed in two layers with filtering from top to bottom, with a layer of heterogeneous metal complex catalyst and a layer of quartz sand, in which the ratio of the height of the layer of heterogeneous metal complex catalyst to the standard height of the sand layer in two-layer filters (see SNiP 2.04.02-84 Water Supply. Outdoor

networks and structures / Gosstroy of the USSR. - M.: Stroyizdat, 1985, tab. 5.1.) Ranges from 0.5 to 1.0, with the catalyst layer being arranged first along the course of the water, the sand layer second, and the grain diameters of the layers increase — the heterogeneous metal complex catalyst 4–7 times, and the sand 1.5 -2.0 times with respect to the normalized equivalent grain diameter in the sand layer.

The utility model is intended to increase the efficiency of treatment and increase the productivity of the main water treatment facilities for treating various water flows, as well as for wastewater treatment plants.

The essence of the utility model is illustrated in the drawing, which shows the filter in section.

The filter for catalytic treatment of natural waters and purification of wastewater from pollution consists of a tank 1 of a pipe 2 for supplying water for purification, a system of distribution trays 3, a filter layer of a heterogeneous metal complex catalyst 4, a filter layer of sand 5, a support layer 6 with a discharge pipe 7 located therein purified water, for the removal of washing water during countercurrent regeneration, a valve 8 is installed on the pipeline for the removal of washing water 9.

The filter for catalytic treatment of natural and wastewater works as follows. Water after preliminary processing through the pipeline 2 enters through the distribution trays 3 into the filter tank 1. Next, the water is sequentially filtered through the first filtering layer of a heterogeneous metal complex catalyst (MMC) 4, where adsorption and catalytic processes occur, associated with the formation of activated oxygen on the catalyst surface in the form of superoxide ions O ^{2 -} and O ^- or peroxide ions O ₂ ^2- . For activation, oxygen dissolved in water is used, and catalysis

occurs at the active sites of the catalyst along its entire surface in the monomolecular layer directly adjacent to the surface of the catalyst. Thus, liquid phase oxidation processes occur in the HMC layer, and HMC, in fact, plays the role of an activated oxygen pump, which determines all the catalytic processes that occur with dissolved organic impurities on its surface. In the second filtering layer of sand 5 along the course of the water, additional particles are suspended and agglomerated in the previous layer.

The filter layers 4 and 5 are located on the supporting layer 6. The removal of purified water is carried out through the pipeline 7 for further processing. The washing of the filter layers is carried out similarly to the classical methods of filtering (see Abramov NN Water supply; M. Stroyizdat, 1982, p. 251-252) with the parameters given in the normative literature (see SNiP 2.04.02-84 Water supply. External networks and buildings / Gosstroy of the USSR. - M.: Stroyizdat, 1985). Rinse water is discharged when the valve 8 is opened via pipeline 9.

At the same time, to increase the efficiency of cleaning by COD in comparison with the prototype by 10-15% and the cleaning efficiency by turbidity and color, the ratio of the height of the filter layer of a heterogeneous metal complex catalyst to the standard height of the sand filter layer (see SNiP 2.04.02-84 Water supply. Outdoor networks and constructions / Gosstroy of the USSR. - M.: Stroyizdat, 1985, tab. 21) is from 0.5 to 1.0. This ratio corresponds to a catalyst bed height of 0.4 m to 0.7 m.

The regeneration of the filter layers of the load is carried out by a reverse current of water. The filter is turned off from work and through the pipeline 7, the water after filtering is pumped into the support layer 6,

evenly distributed over the area of the filter tank. Next, the wash water sequentially enters the layers 5 and 4, fluidizes them and leaches the delayed pollution. Wash water with contaminants is collected in a system of prefabricated trays 3 and with an open valve 8 through a pipe 9 is discharged for further processing. Then the filter is included in the work.

The results of experiments conducted at the facilities of MUE PO Vodokanal in Rostov-on-Don are shown in the table below.

The above results show the inappropriateness of using the height of the MMC layer more than 0.7 m, capital expenditures are increasing with a general trend towards a decrease in COD treatment.

The results of studies of the efficiency of the filter for catalytic water treatment N catalyst, m Filtration rate, m / h Average performance data, a sample of 30 series of experiments COD, MG O ₂ / l Turbidity mg / L Color, degrees entrance exit E% entrance exit E% entrance exit E% 0.4 10.0 50,0 26.0 48-55 12.0 5.3 55.8 15.0 12.0 20,0 68.9 31,0 15.0 78,4 39.2 46-55 12.5 5,6 53.3 24.0 15.0 37.5 78.0 35.1 0.7 10.0 68.9 32,4 40-53 7.9 1,2 84.8 25.0 15.0 40,0 68.9 41.3 15.0 29.0 18.0 38-50 7.9 1.3 83.5 25.0 16 36.0 50,0 25.0 1,0 10.0 68.9 57.2 12-17 11.6 4,5 61.2 30,0 19.2 36.0 68.3 60.1 15.0 37.7 33.1 8-12 11.6 5.5 52.6 30,0 17.0 43.3 37.0 34.0

Numerator and denominator - data from different series of experiments are given. Catalytic treatment studies when blowing the catalyst bed with air have shown that air supply to the catalyst bed while supplying water does not affect the increase in cleaning efficiency.

Similar data on COD reduction were obtained during the post-treatment of wastewater after the complete biological wastewater treatment facilities.

Using a catalyst bed height of less than 0.4 m complicates the operation of the filters due to the inability to maintain uniformity of the height of the MMC layer over the filter area after countercurrent regeneration. Thus, the optimal height of the filtering layer of the MMC is from 0.4 m to 0.7 m.

The experimental results presented also show a stable high purification effect by turbidity and color of natural water, even without preliminary coagulation and flocculation.

Since the increase in the efficiency of catalytic treatment is achieved at speeds of 10-15 m / h, 50% higher than normalized under normal filter operation (see SNiP 2.04.02-84 Water supply. External networks and structures / Gosstroy USSR. -M.: Stroyizdat, 1985, table 21), then the values of speeds of 10-15 m / h are used as workers.

To ensure the duration of filtration between washes of 8-12 hours, typical of the normal mode, at a filtration rate increased by 1.5 times, the grain diameters of the filter layers increase - a heterogeneous metal complex catalyst by 4-7 times, and sand by 1.5-2.0 times with respect to the normalized equivalent grain diameter in the sand layer (see SNiP 2.04.02-84 Water Supply. External Networks and Structures / Gosstroy of the USSR. -M.: Stroyizdat, 1985, Table 21). The absolute sizes of the grains of GMCs are 3-5 mm, and sand grains 1.1-1.8 mm.

Claims (1)

A filter for catalytic treatment of natural and wastewater from pollution, including a tank, a system for supplying and discharging treated water, a support layer, a two-layer filter loading, characterized in that the filter two-layer loading is arranged from two elements: a layer of a heterogeneous metal complex catalyst located first along the movement of water and having a height related to the normalized height of the sand filter layer as 0.5 ÷ 1.0, while the filter layer of the catalyst is made of particles, diameter toryh relates to normability equivalent diameter of the sand grains as 4 ÷ 7, the sand layer located along the second movement of the water is made of particles whose diameter refers to the equivalent diameter normability sand grains as a 1.5 ÷ 2.0.