UA61287A - A process for preparing the purified potable water - Google Patents

Abstract

A process for preparing the purified potable water comprises preliminary purification thereof from mechanical admixtures, oxidative treatment with ozone with a subsequent filtration through the activated charcoal. Before the oxidative treatment the water is passed through the ion-exchange filter with the ionite layer of a mixed action.

Description

Description of the invention

The invention relates to the technology of multi-stage water treatment for obtaining drinking water with improved 2 biological and physico-chemical properties and can be used in food units of hospitals, children's institutions, as well as to provide the population with high-quality drinking water.

The practice of water supply proves that in extensive water supply systems with a large number of water pipes and networks with intermediate reservoirs and dead-end areas, there are cases of water loss of potable quality and its supply to the consumer with non-standard sanitary and bacteriological indicators. These negative 70 phenomena are caused by the penetration of both organic impurities and viable microflora into the water supply systems by various routes and the massive development of a certain group of microorganisms that form fouling and deposits on the inner surfaces of pipes, in tanks and water treatment facilities.

There is a known method of obtaining purified drinking water, which includes oxidation treatment with ozone and subsequent filtration of water through activated carbon (Ukraine, Mo26085, M. kl. СО2Е9/00, application dated 11.21.1996). According to this 72 method, after oxidation treatment with ozone, water is additionally subjected to chlorine treatment and reagent treatment by flotation.

The disadvantage of this method is the low quality of drinking water and high specific costs. Final treatment of water by flotation does not ensure complete removal of hardness ions, as well as organic impurities in the form of organochlorine compounds, which are formed in the process of treating water with chlorine.

The implementation of this method requires the use of bulky equipment, which leads to a significant increase in specific costs.

The method of obtaining purified drinking water, which includes its preliminary purification from mechanical impurities, oxidation treatment with ozone followed by filtration through activated carbon, is the closest in terms of technical essence and the result achieved to the claimed invention (item of Ukraine Mo39703A, M. cl. 29 СО2Е1/78, application dated 12.26.2000). According to this method, for more complete removal of organic impurities, water after filtration through activated carbon is subjected to secondary oxidation treatment with ozone. The disadvantage of the known method is low purification of water from hardness ions and high specific costs.

In the process of treating water with ozone, soluble and suspended organic impurities are destroyed and oxidized. The destruction of the most stable organic compounds, for example, phenol derivatives, humic acids and their salts, which are both in truly soluble form and in colloidal form, takes place. The process of removing organic compounds from water to minimum values is carried out in two stages and continues for a long period of water treatment with ozone, which significantly increases the cost of obtaining purified drinking water. In addition, when treating water with ozone, it is impossible to regulate the hardness of water due to the presence of calcium, magnesium and other ions. A high content of hardness ions in water leads to a decrease in the solubility of ozone in it. As a result, the processes of oxidation of organic impurities slow down by 30%, which increases the duration of water treatment with ozone and, as a result, increases ee, specific costs and worsens water quality.

The basis of the invention is the task of improving the method of obtaining purified drinking water, in which by introducing new operations - ion exchange treatment of water and its additional purification through a woven filter and "a new sequence of their execution - regulation of the ionic composition of water and reduction of the duration of water treatment with ozone, in as a result, a reduction in specific costs and obtaining water with a low number of hardness ions is ensured.

From" The problem is solved by the fact that in the known method of obtaining purified drinking water, which includes its preliminary purification from mechanical impurities, oxidation treatment with ozone followed by filtration through activated carbon, the new thing, according to the invention, is that before oxidation treatment, the water is passed through an ion exchange filter with an ionitic layer of mixed action. b It is also new that the water is passed through an ion exchange filter with an ionite layer of mixed action, in which the mass ratio of anionite and cationite in the layer is within 2.5-4.0.

What is new is that the water is passed through an ion-exchange filter with an ionic layer of mixed action, in which the specific weight of the cationite is chosen from the ratio (1.3-1.8)2 p, where p is the specific weight of the anionite. (ee) 50 It is also new that the water after filtration through activated carbon is subjected to filtration through a woven filter.

There is such a cause-and-effect relationship between the set of essential features of the claimed invention and the technical result achieved.

Treatment of water before its ozonation by passing it through an ion-exchange filter with an ionic layer 22 of mixed action allows cationization and anionization to be carried out in one layer of the filter, alternating, that is, in one ionic layer is subjected to a two-stage ion exchange. The mutual influence of each of the components on exchange reactions makes it possible to ensure a high degree of water purification.

At the same time, organic compounds present in water in the form of highly soluble high- and low-molecular organic acids are adsorbed on anionite according to the mechanism of anion exchange. Next, the water 60 passes through a layer of cationite, in which the hardness ions of calcium and magnesium and others are retained, as well as residual metal impurities, for example, manganese, copper, iron. In addition, the passage of water through the anionite and cationite allows you to adjust the ionic composition of the water, which allows you to adjust the value of the active reaction of the treated water (pH) to values of 6-7 units. At such pH values, the greatest solubility of ozone in water is observed. Thus, the next stage of oxidative treatment of water with ozone takes place under optimal conditions, which ensure a more complete course of chemical reactions between ozone and organic compounds in a shorter period of time. All this contributes to the deep purification of water and the reduction of specific costs.

It has been experimentally established that the optimal way to ensure high quality of drinking water is to use an ionic layer with a mass ratio of anionite to cationite in the range of 2.5-4.0. If the mass ratio of anionite to cationite in the ionite layer is less than 2.5, there is a low capture of organic impurities on the anionite. At the same time, the subsequent process of ozonation of the filtrate must be long, which leads to an increase in specific costs. When the mass ratio of anionite to cationite in the ionic layer is greater than 4.0, an unregulated process of capturing harshness ions is observed, in which it becomes difficult to adjust the pH of the water, as a result of which the reproducibility of the main purification indicators is not ensured. 70 It has been experimentally established that the optimum for ensuring the high quality of drinking water is that the specific weight of the cationite must be selected in the ratio (1.3-1.8) of the specific weight of the anionite. If the specific weight of the cationite is less than 1.3 of the specific weight of the anionite, there is an unregulated mixing of ionites in the ionite layer after their regeneration. At the same time, the sequence and duration of the capture processes of organic impurities and hardness ions is disturbed. In addition, there is clogging of the cationite with organic impurities, as a result of which the exchange capacity of the cationite is sharply reduced, which leads to an increase in specific consumption and a decrease in water quality. When the value of the specific weight of the cationite is more than 1.8 of the value of the specific weight of the anionite, the time of precipitation of the anionite during the regeneration of the ionite layer in the ascending flow of the regenerate increases. As a result, the productivity of the water treatment process decreases, which also leads to an increase in specific costs.

The method of obtaining purified drinking water is carried out using the installation shown in Fig. 1 and Fig. 2. Figure 1 shows a diagram of an installation for obtaining purified drinking water. Figure 2 shows a diagram of an ion exchange filter with an ionic layer of mixed action.

Processors subject drinking water with the following indicators: smell - 2.5 ОР, aftertaste - 2.5 ОР, turbidity - 0.54

NOM, chroma - 22.45", general hardness - bmg.zkv/dm? (PR - dilution index, NOM - nephelometric units of turbidity).

Drinking water from water supply system 1, or in case of lack of water in system 1, from tank 2 using pump C under pressure of atm. fed into filter 4 with a propylene cartridge. In filter 4, water is pre-cleaned from mechanical impurities, such as sand, clay components, rust and others. Then the water is passed through an ion exchange filter 5 with an ionic layer 6 of mixed action. The upper part 7 of layer 6 consists of anionite of the brand "Ekosoft CO" with a specific gravity of 1.04 g/cm?. The lower part 8 of the ionic layer b consists of Sozhmekh NSV8 sodium cationite with a specific gravity of 1.51 g/cm?. The mass ratio of anionite and cationite in the layer is equal to 3. Regeneration of ionites is carried out with a 1595 sodium chloride solution in the upward flow mode, EM carried out in the automatic mode of operation of the ion exchange filter. Purified from the main mass of high-molecular organic acids and hardness ions, water with a pH value equal to 6.5 is subjected to oxidation treatment with ozone in the ozonator device 9 of the ejection type. The concentration of ozone in treated water "O" is 1.O0 mg/l. Oxidation treatment is carried out for 1.5 minutes. After oxidation treatment, the water is passed through activated carbon. Water treatment through activated carbon is carried out in two stages. First, it is passed through the adsorption filter 10, in which the reaction products of oxidation processes not dissolved in the water are captured from the water, and then through the adsorption filter 11, in which the ozone remaining in the water is captured from the water. At the outlet of filter 11, the water contains up to 0.1 mg/l of ozone. The water purified on carbon filters ts 10, 11 is subjected to final fine cleaning of suspended particles of coal dust, passing the water through a woven filter 12 with a pore size of 1-20 μm. Then the water is supplied to the tank 13 of purified water, in the upper part of which there is an adsorption filter 14 for absorbing the released residual ozone.

Purified drinking water is characterized by the following indicators: smell - 0.9 ОР, aftertaste - 0.8 ОР,

Me turbidity - 0.15 NOM, color - 9.15", total hardness - 1.4 mg.equiv/dm3. - As described above, experiments were also carried out on obtaining purified drinking water, in which at the stage of ion exchange treatment of water through an ionic layer of mixed action, in the ionic layer the mass ratio of de anionite and cationite, as well as the ratio of their specific gravities, were varied, as in the ratio interval that

Go! 20 are declared, as well as beyond it. The method of obtaining purified drinking water, which is described in the prototype, was also implemented. "M The table shows the results of experiments. ionite to cationite in specific weights "PRO SPR nom grad. General, mg | relative ionite cation and anionite ECV/DM3 units) 517V50011111831008 flavor

"x - nephelometric units of turbidity. ih - costs according to the prototype are taken as a unit.

From the data given in Table 1 (examples Mo2-4), it can be seen that the proposed method provides (compared to the known) reduction of specific costs by 2-2.5 times, and the total hardness of water decreases to values lower for 1.5 mg eq./dm3. Organoleptic indicators decrease by 2-3 times. Thus, the smell and taste are reduced to the values of dilution indicators (PR) less than one. Turbidity has a nephelometric indicator less than 0.2, and chroma is less than 9". These indicators are significantly lower than their corresponding values according to 70 "State Sanitary Rules and Norms of Ukraine", Mo383 dated 12.23.96.

Such indicators testify to the high quality of drinking water, which has a high physiological completeness of the mineral composition and organoleptic properties with minimal costs for water purification.

Implementation of the proposed method of obtaining purified drinking water is carried out with the help of a number of well-known cleaning devices using well-known reagents. The method can be implemented /5 both in autonomous execution and in the city water supply system.

Claims (4)

The formula of the invention 1. The method of obtaining purified drinking water, which includes its preliminary purification from mechanical impurities, oxidation treatment with ozone followed by filtration through activated carbon, which is characterized by the fact that before oxidation treatment, the water is passed through an ion exchange filter with an ionic layer of mixed action. 2. The method according to claim 1, which differs in that the water is passed through an ion exchange filter with an ionic layer of mixed action, in which the mass ratio of anionite and cationite in the layer is within 2.5-4.0. C. The method according to claims 1, 2, which differs in that the water is passed through an ion exchange filter with an ionic layer of mixed action, in which the specific gravity of the cationite is selected from the ratio (1.3 - 1.8) P, where P is the specific gravity " anionite 4. The method according to claim 1, which differs in that the water after filtration through activated carbon is subjected to filtration through a woven filter. them (ee) with - (Se) - and? (o) - name) (ee) that 60 b5