RU2241681C2 - Method to purify a liquid by filtration - Google Patents

Abstract

FIELD: purification of liquids from different pollutions.

SUBSTANCE: the invention is dealt with the field of purification of a liquid from different pollutions and may find application in practice of purification of water, sewage and different solutions and liquid mediums in some processes of chemical engineering, in benefication, in food and other industries. The method provides for mixing of a liquid with reagents and-or sorbents and the mixture subsequent passing through a layer of the granular loading till its pollution, termination of the filtration, delivery of a washing liquid or an air till washing the loading from pollutions, termination of their delivery into the washing with consequent resumption of the process of filtration. At that the reagents and-or sorbents are previously admixed with a part of the delivered washing liquid and injected into the first along the course of movement expanded layers of the granular loading before the end of its washing. The invention allows to improve productivity and stability of liquids purification by filtration and-or to reduce consumption of reagents and-or sorbents.

EFFECT: the invention allows to improve productivity and stability of liquids purification by filtration and-or to reduce consumption of reagents and-or sorbents.

2 cl

Description

The invention relates to the field of purification of liquids from suspended solids, colloidal particles and dissolved organic impurities by filtration through a layer of granular load. It can find application in the technology of purification of natural and wastewater, as well as various solutions and liquid media in the processes of enrichment, chemical technology, hydrometallurgy, food and light industry, etc.

It is a well-known method of purifying water from contaminants, which consists in mixing it with reagents (coagulant, flocculant, alkali), separating the resulting flakes from the water by settling and then filtering the purified water through a layer of granular charge. This cleaning method is used at most water treatment plants. The disadvantages of the existing cleaning method include the high consumption of reagents, especially when cleaning high-color and low-turbid waters, as well as waters with a low temperature, which is observed in the winter period and, in particular, in the spring-autumn flood. In addition, mountain and northern rivers have a low water temperature for most of the year. When purifying cold water, a decrease in the effect of its purification is usually observed and the reagent consumption increases significantly, since the coagulation process slows down very much or is very sluggish.

These disadvantages are partially eliminated in another well-known method of water purification, which consists in mixing the liquid to be cleaned with reagents and then filtering it through a layer of granular charge. Contact clarifiers, contact filters and prefilters for water purification work on this principle. The disadvantages of this method, which is implemented when treating water on contact clarifiers, include the inappropriateness of its use with a significant concentration of suspended matter in the treated water and with high color water. So, SNiP 2.04.02-84. "Water supply. External networks and structures. ”(Table 15) recommends the use of contact clarifiers with a turbidity of water supplied to them not exceeding 120 mg / l and color not exceeding 120 °. In addition, contact clarifiers have a low productivity, because the maximum speed of water filtration even in forced mode does not exceed 5.5-6 m / h (Clause 6.130 of SNiP 2.04.02-84). When cleaning water with this method, it is recommended that contact water prefilters purify water with a suspension content of up to 300 mg / l and color up to 250 °, however, this provides a low cleaning effect, because the residual concentration of suspended matter in purified water is 15–40 mg / l (see V.Z. Meltzer. Filtering facilities in municipal water supply. - M .: Stroyizdat, 1995, - c.l38-141). Therefore, prefilters can be used as the first stage of cleaning before quick granular filters, i.e. two-stage filtration is required, which complicates and increases the cost of water treatment. When implementing water purification in this way on contact filters (filtering from top to bottom), there are difficulties with the uniform distribution of reagents over the filter area, the effectiveness of mixing the reagents with the water to be purified, which it is desirable to supply immediately before the treated water enters the granular charge, the filter cycle time is reduced compared to filtering in the direction of decreasing grain size of the loading grains (contact clarifiers), etc. This cleaning method has some other disadvantages.

There is also a method of purifying water from suspended solids, taken as a prototype (Aut. St. USSR No. 946603, BI No. 28, 1982), which consists in introducing polyacrylamide and finely ground coal as an sorbent into the water to be purified and then filtering it from the bottom up through the layer granular load, which use crushed burned rocks. Moreover, when treating water with this method, a higher content of suspended matter in it is allowed, the volume of sediment formed is reduced and its disposal is simplified. However, as follows from the description of this method, although it has some advantages over the known method, it does not provide a sufficiently high cleaning effect, since the residual suspension in the water purified by this method is 10-12 mg / L. In many cases, a higher quality of cleaning is required. So, according to GOST 2874-82 “Drinking water”, the suspension concentration in drinking water should not exceed 1.5 mg / l.

The technical problems solved by the invention are to increase the effect and stability of liquid purification by filtration and reduce the consumption of reagents and / or sorbents. To solve these problems, a new method for cleaning liquid by filtration is proposed, which consists in mixing it with reagents and / or sorbents, then passing the mixture through a layer of granular charge to contaminate the load, stopping the filtering process, supplying washing liquid or air and liquid through the layer of granular load before washing the latter from pollution, the cessation of their supply and the subsequent resumption of the filtering process, characterized in that the reagents and / or sorbents are additionally introduced into the main part of the grain layer net loading before resuming the filtering process. As a result of the supply and distribution of part of the reagents and / or sorbents in the layer of granular loading, before feeding purified water to the filter structure, a layer consisting of coagulant flakes and / or sorbent particles is formed in the intergranular space. Moreover, freshly formed flakes of hydroxides of various metals have a high sorption ability. Therefore, the contaminated liquid entering the granular charge will be better cleaned of contaminants from the very beginning of the filter cycle compared to the known method, especially from dissolved organic impurities (humic and fulvic acids, which determine the color of natural waters, phenols, petroleum products, surfactants, etc.). This is due to the fact that the efficiency of removing impurities by sorption, in addition to a number of factors, depends on the height of the sorbent layer and the contact time of the liquid to be cleaned with the sorbent. In the proposed cleaning method, this layer is formed within the existing granular loading layer immediately before the start of the filter cycle. Whereas in the known method it will accumulate in the thickness of the charge gradually as the filtered fluid is mixed with reagents and / or sorbents. In addition, for the same reason, the time of the protective action of the filter structure operating according to the proposed method will be longer in comparison with the known method. This is because coagulant and / or sorbent flakes located in the most distant layers of the granular charge during filtration of the liquid to be cleaned will be less contaminated at the end of the filter cycle and therefore will have an additional protective effect, continuing to sorb impurities from the liquid being cleaned and preventing their premature leakage to the exit of the filter structure.

To facilitate and simplify the practical implementation of the proposed method of filtering liquid cleaning, namely, the uniform distribution of reagents and / or sorbents in the thickness of the filter load, it is further proposed to introduce reagents and / or sorbents in the first expanded layers of the washed granular load in the direction of the washing liquid before the washing is completed. Due to this, the reagents and / or sorbents will be freely distributed by the wash liquid flow over the entire height of the expanded layer of the wash load. In addition, due to increased turbulization of the flow of washing liquid between the washed grains, good mixing of the reagents and / or sorbents with the washing liquid will occur. After washing and sedimentation or floating up (using a floating load), the loading grains are reagent and / or sorbent will be distributed between the grains relatively evenly along the height of the loading layer.

Also, to improve the uniform distribution of the reagents and / or sorbents over the area of the filter structure and to simplify the design of the process of their introduction into the expanded layer of the granular charge, the reagents and / or sorbents are pre-mixed with a portion of the washing liquid before it enters the thickness of the expanded layer of the granular load before washing . After mixing the reagents and / or sorbents with the washing liquid, their mixture enters the expanded layer of the granular charge and fills evenly the intergranular space along almost the entire height of this washed layer, after which the flow of the washing liquid stops and the loading grains settle or float. As a result, flakes of reagents and / or particles of sorbents are almost evenly distributed over almost the entire height and area of the granular loading layer. Then, the liquid to be purified is again fed into the granular charge charged with flakes of reagents and / or particles of sorbents until it is contaminated, after which, when the maximum pressure loss or leakage of impurities is reached, the filtration structure is turned off for washing, as in the known method. When a washing liquid or air, and then a liquid is supplied and the granular loading layer expands, the coagulant flakes and / or sorbent particles located in the granular loading together with the remaining contaminants are removed from it. Before the washing of the granular load is completed, fresh reagents and / or sorbents are again mixed with the washing liquid and then supplied with it to the expanded loading layer in accordance with the proposed method. After the distribution of the mixture of reagents and / or sorbents with the washing liquid in the space between the grains of the expanded layer of the granular charge, the washing stops, the granular charge settles or floats and the filter cycle is repeated.

The most simply proposed method is implemented by feeding reagent solutions and / or a suspension of sorbents into the suction line of the washing pump at the end of washing. You can also feed them into the ejector located on the pressure line of the washing pump, into which they are sucked in and mixed with the washing liquid. When their mixture moves through a pump or ejector, then along the pressure line of the washing pump and through the drainage system of the filter structure, they are mixed well with each other and the washed liquid before the mixture enters the expanded granular loading layer. This ensures an almost uniform distribution of reagents and / or sorbents over the area, and then along the height of the granular loading layer. After which the washing ends, the granular load settles or floats up and the flakes of reagents and / or suspension of sorbents are almost evenly distributed between the grains of the main part of the layer of granular load.

It should be noted that the distribution of coagulant flakes and / or sorbent particles in the thickness of the granular load before the start of the filter cycle in accordance with the proposed method will reduce intergranular porosity, which will lead to some increase in the initial pressure loss in the load. This can slightly reduce the duration of the filter cycle if the filter structure is turned off after reaching the maximum pressure loss. However, this reduction will depend on the number of coagulant flakes and / or sorbent particles and, given the uniformity of their distribution over the height of the loading layer, it may be insignificant, since the bulk of the pressure loss at the end of the filter cycle falls on the first layers of the granular loading along the filter. In addition, in the event that the filter structure is turned off for flushing along the impurities in the filtrate, the presence of coagulant flakes and / or sorbent particles along the entire height of the loading layer will, on the contrary, increase the duration of the filter cycle, since coagulant flakes and / or sorbent particles located in the layers at the outlet of the load will be less contaminated and therefore, even at the end of the filter cycle, will have an additional protective effect, continuing to sorb contaminants from the liquid being cleaned.

Thus, by cleaning the liquid by filtration, the proposed method solves the problems of improving the quality and stability of cleaning and reducing the costs of reagents and / or sorbents, especially when cleaning liquids with low temperatures, as well as liquids with a significant concentration of colloidal and especially dissolved impurities.

In addition, to further reduce the cost of reagents, it is proposed that reagents and / or sorbents or their mixture with a portion of the wash liquid be subjected to any of these treatments: temperature, magnetic, electromagnetic, ultrasonic, electrochemical or combined temperature magnetic, magneto-electrochemical effects or ultrasonic treatment in a magnetic or electric field.

An example of temperature activation is the heating of a reagent solution before mixing with a portion of the wash water before the mixture enters the suspended layer of the washed granular charge in the cold season. Even after such mixing with part of the cold wash water, the temperature of the mixture will be higher than the temperature of the treated cold water, which means that the formation of coagulant flakes in the thickness of the granular charge will occur more intensively. Moreover, the flakes formed in the intergranular loading space before the start of the filter cycle will be denser and stronger than the flakes formed in the process of filtering purified cold water with a lower temperature. This can allow to slightly reduce the costs of the reagents needed to form the structure of a hydroxide precipitate uniformly distributed in the thickness of the charge before starting the supply of raw water for treatment. In addition, due to the developed surface of the coagulant flakes and their significant sorption ability, pollution and smaller and loose flakes of sediment coming from the cold water to be cleaned will more intensively adhere to them. The latter can also allow to further reduce the consumption of reagents, especially when treating cold natural and wastewater.

The intensity of the coagulation process and the formation of sludge flakes also increases with magnetic, electromagnetic or ultrasonic treatment of the coagulant solution or its mixture with washing liquid. In addition, during magnetic treatment of a coagulant solution, for example aluminum sulfate, the sorption capacity of the resulting flakes of aluminum hydroxide increases by more than 9-10%. Due to this, it is possible to reduce the consumption of reagents or increase the effect of liquid purification by filtration by the proposed method (see, for example, Dushkin S.S., Evstratov V.M. Magnetic water treatment at chemical enterprises, - M., 1986, - p. 33-34 96-113).

An example of the combined activation of reagent solutions or their mixture with a washing liquid can be the passage of this mixture or reagent solutions before being fed into the expanded granular loading layer through an electrolyzer or electrocoagulator, where, under the influence of a constant electromagnetic field and electrochemical processing, the so-called coagulation under current occurs, as a result of which the intensity of flocculation increases and the costs of reagents are reduced to 30% or more (see, for example, Bychin N.A. Study of electrolytic methods of purification of mine water (on the example of the Donetsk coal basin). Abstract of a dissertation for the postgraduate student of the senior candidate of technical sciences. - Kiev, 1973. - 23s.).

The preliminary combined treatment of the reagent solutions or their mixture with the washing liquid before being fed into the granular loading layer, for example, temperature-magnetic, magnetic-electrochemical or ultrasonic in a magnetic or electric field, also allows you to intensify the coagulation process. This can reduce the consumption of reagents (see, for example, Dushkin S.S., Evstratov V.N. Magnetic water treatment at chemical enterprises, - M .: Chemistry, 1986, - p.96-113). Additionally, when combined processing of a reagent solution or its mixture with a washing liquid, for example, magneto-electrochemical, the adsorption capacity of the resulting flakes of aluminum hydroxide under optimal conditions increases by 31.2% (see ibid. P. 36), due to which it can also be reduced reagent consumption or increased liquid purification effect. At the same time, the density of the formed sediment flakes increases, which can help reduce the cost of cleaning dirty wash water.

Thus, the preliminary activation of the reagent solutions and / or sorbents or their mixture with the washing liquid before being fed into the expanded granular loading layer before the washing is completed can further reduce the consumption of reagents and / or increase the efficiency of filtering liquid cleaning.

Thus, the proposed method of purification of liquid by filtration allows to a large extent and quite simply to solve the technical problems at the minimum cost of its implementation.

Claims (2)

1. A method of purifying a liquid by filtration, which consists in mixing it with reagents and / or sorbents and then passing the mixture through a layer of granular charge until it is contaminated, terminating the filtering process, supplying a washing liquid or air and liquid through a layer of granular loading until the latter is washed from contaminants, the termination of their supply for washing and the subsequent resumption of the filtering process, characterized in that the reagents and / or sorbents are pre-mixed with part of the supplied washing liquid and introduced into the first e while moving granular layers extended before the end of its loading washing. 2. The method according to claim 1, characterized in that the reagents and / or sorbents before being fed into the granular loading layer or after mixing with a portion of the washing liquid before being fed into the expanded layer of the washed granular loading are preliminarily subjected to temperature, magnetic, electromagnetic, ultrasonic or electrochemical treatment or combined temperature-magnetic, magneto-electrochemical treatment or sonication in a magnetic or electric field.