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Drinking water playing the major role in maintenance of people’s health is one of irreplaceable components in production of much foodstuff: reduced dairy production, meat and bakery goods, alcoholic and soft drinks. Water from system of economic-drinking water supply or prepared of underground water sources is basically used on food industry enterprises. Kemerovo region - is a large territorial and production complex of the Russian Federation, where the considerable quantity of the metallurgical, chemical enterprises is placed, the mines which are a source of intensive pollution of the main waterway of area, the river Tom'. Therefore in Kuzbas underground waters are also used for water treatment. In the structure of water supply of Kemerovo region underground waters make 37.2%. Practically in all underground waters of Kuzbas there are phenols which are washed away from coal layers and humic connections. So, in Kuzbas in 2015 33.1% of hallmarks of water from sources of the centralized water supply of population mismatched hygienic specifications on sanitarian-chemical indexes, including from open reservoirs of 13.6%, underground - 33.6% [1, 2]. Underground water is extracted from a source and is exposed to purification directly in a place of extraction with application of modern technologies, including the ozonization, excluding influence of external medium and contact to the person. Ozone is one of the strongest natural oxidants and a good disinfectant agent. Ozone is applied as disinfectant and oxidations of organic contaminants [3]. However as a result of water disinfecting by ozone, oxygen-containing organic compounds mainly aldehydes (formaldehyde, acetic aldehyde) can be formed. Being in water in the concentration exceeding maximum concentration limit, these contaminants damage central nervous system, liver, kidneys, possess toxic and carcinogenic properties [4-9]. So, there is a necessity of working out a technology of water afterpurification from organic contaminants, including phenol, formaldehyde and acetic aldehyde. For water purification from microadmixtures of organic compounds it is more expedient to use the adsorptive methods. The efficiency of water adsorption cleaning from organic compounds is defined by active charcoals on set of researches of balance, kinetics and dynamics of the adsorptive process. The purpose of the present work is producing the adsorptive technology of afterpurification of drinking water for foodstuff production from phenol, formaldehyde and acetic aldehyde, occasionally presenting in natural water or arising in the stage of ozonation in water processing. OBJECTS AND METHODS OF STUDY Research objects were: active charcoals of marks AG-OV-1, SKD-515, AG-3, BАU (manufacturer “Sorbent”, JSC, Perm'), coconut active charcoal КsАU (“Eurocarb”, England), АBG (lignite semi-coke, “Karbonika-F”, CJSC, Krasnoyarsk), differing in raw materials, in the way of reception, chemical state of a surface, technical characteristics; water solutions of acetic aldehyde, formaldehyde, phenol with variable organic content (0.0001-50 mmol/dm3) and their mixes. Balance of mixes adsorption of phenol and formaldehyde is studied in the ratio components 1 : 50 (mmol/dm3), formaldehyde and acetic aldehyde - 9 : 1. The chosen parities of organic matters correspond to the periodic maintenance of phenol, formaldehyde, acetic aldehyde in water prepared with utilization of ozone. Studying of kinetics and dynamics of adsorption of systems formaldehyde-phenol - water-AC and formaldehyde-acetic aldehyde - water-AC were made on modelling water solutions with the greatest possible real maintenance of components during spring period in water with concentration of formaldehyde of 0.2000 mg/dm3, phenol - 0.0120 mg/dm3, acetic aldehyde - 0.0500 mg/dm3. Production tests were made in the shop of bottled water of “Talinka”, LLC using ozonization as disinfecting. The maintenance of phenol, formaldehyde, acetic aldehyde in samples was defined by method of molecular absorption spectroscopy. Porous characteristics of active charcoals (total area of surface, area of micropores, volumes) were studied by method of low-temperature adsorption of nitrogen at 77°С on the device “Sorbtometr M” (production of IR Siberian Branch of the Russian Academy of Science, Novosibirsk). IR-spectroscopic researches were made on samples АC preliminarily slashed to a powdery state and mixed with KBr in the ratio 1 : 10. IR DOFP-spectra were registered on the infra-red Fourier-spectrometer “Infralyum FT-801’, production of IFP Siberian Branch of the Russian Academy of Science (Novosibirsk) in the range of 4000-500 cm-1, number scans 50. RESULTS AND DISCUSSION One of the basic criteria of estimation of sorbents' adsorption properties are adsorption isotherms. Adsorption isotherms were constructed under the received experimental data of adsorption of formaldehyde, phenol, acetic aldehyde from solutions of individual components in a wide interval of concentration by carbon sorbents (Fig. 1). Various adsorptive capacity of active charcoals at adsorption of organic matters from solutions is caused by physical and chemical properties of an adsorbent and adsorbate nature. In the field of low concentration (Fig. 1) for all adsorption isotherms is typical the linear site, testifying that the maximum adsorbability has not been reached yet. The isotherms presented in Fig. 1a, 1b have a classical appearance and according to Giles's classification adsorption isotherm of phenol and formaldehyde from water solutions of individual components are isotherms of class L, isotherms of acetic aldehyde adsorption are isotherms of class S. The character of sorption isotherms according to Giles's classification allows to make the conclusion that interaction between the adsorbed molecules is not enough, and critical increment of energy does not depend on degree of fullness of sorbent surface. In case of adsorption of acetic aldehyde the force of interaction between the adsorbed molecules is more than force of interaction between a solute and an adsorbent, and energy activation increases [10, 11]. (a) (b) (c) Fig. 1. Adsorption isotherms (a) formaldehyde, (b) phenol, (c) acetic aldehyde from individual water solutions on active charcoals: 1 - КsАU; 2 - AG-3; 3 - ABG; 4 - SKD-515; 5 - BAU; 6 - AG-OV-1. The analysis of adsorption isotherms of organic contaminants also shows, that the maximum adsorbability of carbon sorbents depends on nature, contents, specific surface and porosity. The influence of adsorbate properties is presented on Fig. 2. (c) (b) (a) Fig. 2. Adsorption isotherms of organic matters by active charcoal (a) АG-3, (b) КsАU, and (c) АBG: 1 - phenol; 2 - formaldehyde; 3 - acetic aldehyde. The dependence known from literary data [11] between solubility sorbate and its sorption activity proves to be true for all probed substances. The influence of solubility on the acetic aldehyde adsorption, which limit of solubility is infinite, is especially appreciable. Because of high water solubility it is more favourable for acetic aldehyde thermodynamicly to be in solution, than to be adsorbed on АC. Higher solubility of formaldehyde in water (12400 mmol/dm3) in comparison with phenol in water (925 mmol/dm3) and ability of formaldehyde to form clusters in the solution also reduces sorptive capacity because of dispersive interaction for the yielded component on all probed coals. In the yielded conditions it is more favourable for formaldehyde to be adsorbed on superficial active groups forming the secondary adsorptive centres. In spite of the fact that formaldehyde and acetic aldehyde have identical functional groups, in this case the influence of solubility prevails and acetic aldehyde practically is not adsorbed. In the field of high concentration formaldehyde adsorption exceeds phenol adsorption, i.e. the yielded dependence is not conserved, because solubility is not the unique factor defining adsorption from water solutions of individual substances. At concentration increasing formaldehyde is adsorbed on the secondary adsorptive centres, forming new active centres for formaldehyde adsorption. Formaldehyde adsorption exceeds phenol adsorption on АC АG-3 in the field of concentration more than 20 mmol/dm3, on АS КsАU more than 5 mmol/dm3, on АC АBG more than 3 mmol/dm3, reflecting features of sorbents behaviour, caused in their various sizes of porosity and chemical surface state, and also adsorbate properties. For substantiation of adsorption mechanism data of poremethry, potentiometric titration according to Byom and adsorptive curves in the field of low concentration were used. The results of research of a pore structure and titration are presented in Tables 1 and 2. Data of poremethry showed, that the greatest bulk volume of micro-and mesopores at АC КsАU in comparison with other coals (Table 1), assumes higher adsorptive capacity of the yielded sorbent in relation to the substances which adsorption has the physical nature and goes mainly in micropores (Fig. 1а, 1b). The sorbent of mark АBG possesses the least bulk volume of micro-and mesopores, in comparison with others АC, that causes the least adsorptive capacity of the yielded sorbent in relation to contaminants (Fig. 1). Experimental data also show, that the important factor defining the adsorptive extraction of phenol, formaldehyde and acetic aldehyde is the chemical surface state meaning quantitative and qualitative contents of functional groups. Potentiometric titration data according to Byom have allowed to explain higher attenuation range of phenol and formaldehyde, at АU КsАU in comparison with АBG and АG-3. A surface of sorbent КsАU (Table 2) contains acid (carboxylic and lacquer) КFG on surface area 3 times more, than АBG, and 2 times more than АG-3. It provides the additional adsorption of organic matters caused by specific interaction because of a hydrogen bridge with KFG of coals. For the characteristic of carbon materials and calculation of the adsorptive parametres monolayer adsorption theories (Freindlikh and Lengmyur's equations), theory of volume filling of micropores (Dubinin-Radushkevich’s equitation modified for a case of adsorption from water solution) and the generalized theory of polymolecular adsorption Brunauer, Emmet and Teller (BEТ) are used. Applicability of these equations for calculation of adsorption parametres was defined by pre-award experimental researches. The calculated values of adsorption parametres of phenol and formaldehyde from water solutions for all coals are resulted in Table 3. According to the received parametres theoretical adsorption isotherms of components are calculated. Таble 1. The main characteristics of pore structure of probed samples Sample Smicro, m2g *VS, cm3/g Vmicro, сm3/g **Vmeso,сm3/g SKD-515 404.0 0.561 0.359 0.202 AG-ОV-1 369.0 0.459 0.218 0.241 BAC 586.0 0.455 0.352 0.103 АG-3 490.0 0.340 0.270 0.060 АBG - 0.260 0.020 0.240 КsАU 1418.7 0.730 0.620 0.110 Note. * - general volume of pores with dimeter less than 150 nm; ** - volume of mesopores, got from the balance VS - Vmicro, Table 2. Surface condition of active charcoals АC The maintenance of oxygen active in mmol/g of coal (nkfg, mkmol/м2) -OH phenol -COOHstrong carboxylic -COOlacquer SKD-515 0.181 - 0.157 АG-ОV-1 0.213 0.032 0.078 АG-3 0.321 0.035 0.039 ABG 0.130 0.020 0.040 КsАU 0.194 0.090 0.060 Table 3. Parameters of adsorption of organic matters from water solutions, probed active charcoals in static conditions Coal mark Type of equitation Freindlikh Lengmyur BET Dubinin-Radushkevich 1/n b, mmol/g аm, mmol/g аm, mmol/g -Q, kJ/ mmol аmax, mmol/g E0, kJ/mmol W, dm3/kg formaldehyde AG-OV-I 1.34 0.04 13.5 25.0 13.4 21.0 15.9 0.56 SKD-515 0.80 3.80 11.7 20.0 12.5 19.1 13.6 0.51 AG-3 0.99 1.67 11.1 23.8 15.9 20.1 14.7 0.54 BAU 1.00 1.60 8.5 12.8 10.8 15.6 11.3 0.42 KsAU 1.23 2.93 20.8 33.3 17.3 33.1 10.1 0.334 ABG 1.07 0.89 3.92 17.54 16.7 9.2 10.4 0.09 phenol AG-3 0.43 10.53 0.75 0.894 13.45 2.14 15.9 0.25 KsAU 0.64 14.30 2.001 2.007 17.42 6.75 14.9 1.115 ABG 0.46 5.83 0.459 0.046 17.7 0.009 15.7 0.086 AG-OV-I - - 0.85 1.30 14.9 2.22 15.0 0.310 SKD-515 - - 0.99 1.58 15.55 2.36 15.2 0.356 In connection with low initial concentration acetic aldehyde is practically completely adsorbed from water solutions on АC, therefore usage of monolayer adsorption theories, theory of volume filling of micropores and generalised theory of polymolecular adsorption BEТ for calculation of the basic adsorptive parametres of acetic aldehyde is not obviously possible. Analyzing adsorptive characteristics, it is possible to draw a conclusion, that sizes of limiting adsorptive volume W for all carbon sorbents are in limits of 0.086-1.115 dm3/kg (for phenol), 0.09-0.56 dm3/kg (for formaldehyde) and allow to assume, that adsorption of phenol, formaldehyde from solutions of individual substances submits to the volume mechanism of micropores filling. The values of characteristic energy which are in limits 14.9-15.9 kJ/mole (for phenol), 10.1-15.9 kJ/mole (for formaldehyde), testify that adsorption occurs basically in micro-and mesopores of adsorbents, and for active charcoal АBG in mesopores. Formaldehyde and phenol АC adsorption isotherms assume physical nature of adsorption. The calculated sizes for heats of adsorbtion 13.42-17.70 кJ (for phenol), 10.8-17.6 кJ (for formaldehyde) confirm the conclusion about the physical nature of interaction of organic matters with a surface of the studied carbon sorbents. The received experimental data and settlement parametres allow to draw a conclusion, that adsorption of phenol, formaldehyde, acetic aldehyde has physical nature, and phenol mainly has dispersive (nonspecific) and partially specific interaction because of hydrogen connection, for formaldehyde is more typical specific interaction. The formaldehyde having the highest size of adsorption, besides nonspecific interaction in pores is capable to interact with functional acid groups of surface АC and even to serve for formaldehyde molecules as the secondary centres of adsorption. The complex estimation of adsorptive characteristics of the probed carbon sorbents in static conditions allowed to arrange them by efficiency of extraction: phenol - KsAU> SKD-515> AG-OV-1> AG-3> ABG; formaldehyde - KsAU> AG-3> AG-OV-1> SKD> 515> BAU> ABG; acetic aldehyde - KsAU> AG-3> ABG. As in natural water mixes of organic matters usually contain, the balance of adsorption in systems most often meeting in practice of water treatment with application of stage of ozonization is probed: formaldehyde - phenol - water - АC and formaldehyde-acetic aldehyde - water - АC [12]. According to the received experimental data of adsorption of formaldehyde and acetic aldehyde from water solution their mix various carbon sorbents are constructed by adsorption isotherms. Comparison of adsorption isotherms of acetic aldehyde and formaldehyde from water solution their mix with adsorption isotherms from water solutions of individual substances showed absence of components influence on adsorption of each other. At adsorption of formaldehyde and acetic aldehyde from a mix the form of isotherms does not vary, thus acetic aldehyde (Fig. 3) owing to its low initial concentration is adsorbed completely. On the basis of experimental data adsorption key parametres are received. (a) (b) Fig. 3. Adsorption isotherms of formaldehyde (a) and acetic aldehyde (b) on АC AG-3: 1 - individual component; 2 - mix of components. The obtained data allow to draw a conclusion, that adsorption of formaldehyde and weak adsorption of acetic aldehyde from a mix having physical nature, goes independently from each other, and for acetic aldehyde dispersive interaction in micropores prevails, for formaldehyde - both dispersive in micropores and specific on surface АC with hydrogen connection with oxygen-containing superficial groups of acid type; thus at formaldehyde adsorption some processes proceed: adsorption in accessible size of micropores and specific interaction with active centres (thus sizes of characteristic energies are averaged). The changing of adsorptive activity of carbon sorbents during formaldehyde and acetic aldehyde extraction at joint presence decreases in KsAU> AG-3> ABG. The adsorptive behaviour of mix phenol-formaldehyde-water is probed. Under the received experimental data of adsorption of formaldehyde and phenol from water solution their mixes adsorption isotherms are constructed by various carbon sorbents. Comparison of adsorption isotherms of phenol and formaldehyde from water solution of their mix with adsorption isotherms from water solutions of individual components showed, that in the field of low concentration (to 10 mmol/dm3) there is no influence of components on adsorption of each other. In the field of high concentration at joint presence of organic matters phenol adsorption does not change, and formaldehyde is adsorbed a little bit poorer, than from its water solution of individual substance (Fig. 4). The form change of an isotherm (reduction of isotherm steepness) is thus observed that can testify about changes of interaction character of components in the solution and with АC surface. The form change of adsorption isotherm of formaldehyde from a mix on АC AG-3 with L on S4, means growth of critical increment of energy and bigger force of interaction between adsorbed molecules than between a solute and an adsorbent, and also molecules aspiration of solute to settle down on a surface in the form of chains or clusters. The decrease in adsorption of formaldehyde from water solution of components mix in the field of high concentration (more than 10 mmol/dm3) is caused by competitive adsorption on the adsorptive centres. (a) (b) Fig. 4. Adsorption isotherms of formaldehyde (a) and phenol (b) on АC AG-3: 1 - individual component; 2 - components mix. It is experimentally positioned, that Lengmyur’s equation is not applicable for the adsorption equilibrium description in system water - phenol -formaldehyde - АC. The adsorption isotherms calculated on the equations of Dubinin-Radushkevich, Freindlikh and BEТ, testify a application possibility of the yielded equations for calculation of equilibrium parametres of adsorption in the system Au - water - phenol - formaldehyde. The sizes of limiting adsorptive volume W for all carbon sorbents are in limits of 0.0862-1.0641 cm3/g (for phenol), 0.33-1.231 cm3/g (for formaldehyde) and allow to assume, that phenol and formaldehyde adsorption at joint presence submits to the volume mechanism of micropores filling. The values of characteristic energy which are in limits 14.932-15.902 kJ/mole (for phenol) and 13.576-14.668 kJ/mole (for formaldehyde), testify, that phenol and formaldehyde sorption at joint presence occurs basically in micro-and mesopores of adsorbents. The value of adsorbtion heats at a small filling the pores of active charcoals are close among themselves and are in limits 11.282-16.963 kJ/mole for phenol, assuming the adsorption caused as Van-der-Vaal’sovy forces (dispersive interaction), and because of formation of hydrogen bridges (specific interaction). The values of adsorbtion heats for formaldehyde 16.704-22.243 kJ/mole give the basis to consider, that at its adsorption specific interaction prevails because of formation of hydrogen bridges with superficial polar functional groups, that is absorption of phenol and formaldehyde by active charcoals is a total process of nonspecific adsorption (in the volume of accessible pores) and specific (on active centres). For specification of adsorption mechanism of phenol and formaldehyde IR-spectroscopic researches are carried out. The IR-spectroscopy is used for identification of organic matters and their functional groups. The occurrence in a spectrum of characteristic frequency of a functional group is influenced by structure, power constant connections and a molecule environment. The fluctuations change of base units of a molecule because of interaction at formation of intermolecular communication (for example, hydrogen) or dispersive interaction at physical adsorption will also be reflected in a spectrum by change of frequencies and fluctuations intensities of corresponding functional groups that will allow to specify the mechanism of interaction an adsorbent - adsorbate [13]. IR-spectra of active charcoals are studied before and after adsorption of organic matters from water solution. The analysis of the received results showed (Fig. 5), that for all spectra it is possible to evolve areas of valent and deformation fluctuations -ОН of alcohol group, phenols and carboxylic acids (3700-3300 and 1300-1250 cm-1, accordingly), free and connected hydrogen bridge; area of valent and deformation fluctuations-S-N of aliphatic group (2970-2850 and 1450-1300 cm-1, accordingly); area of fluctuations> C=O groups in aldehydes, ketones and carboxylic acids (1780-1600 cm-1); fluctuations from group of alcohol and aethers (1300-1000 cm-1); the band corresponding to 2350 cm-1, falls into to carbon dioxide absorption, this absorption band is visible on all infra-red spectra received on one-beam devices or two-beam device at not enough good indemnification of a working bunch and a bunch of comparison. λ, cm-1 Fig. 5. IR-DOFP spectra of active charcoals AG-3 and KsAU and their samples after adsorption of organic matters: AG-3 - industrial sample (I), AG-3 after adsorption of phenol (II), AG-3 after adsorption of formaldehyde (III), AG-3 after adsorption of a mix of phenol and formaldehyde in the ratio 1 : 50 (mmol/dm3) (IV), KsAU (V), KsAU after adsorption of a mix of phenol and formaldehyde (VI). In Fig. 6 different IR - spectra are presented on which the studying of interaction of organic matters with superficial oxygen-containing groups AC is possible. Different spectra are received by subtraction of spectra АC after adsorption by organic matters from spectra АC [14]. On different spectra of samples II-IV and VI a set of bands of average intensity is seen, corresponding to fluctuation of -ОН group with formation of an intermolecular hydrogen bridge (3600-3400 cm-1). Hydroxyl group presence proves to be true by display of deformation fluctuations of -ОН group and valent vibrations from -С-О- group in the field of 1300-1000 cm-1. At difference spectrum AG-3 after phenol adsorption there are sets of bands with fluctuations of group -С-О- (1300-1000 cm-1), and also a benzene ring (1620 and 1450 cm-1) of adsorbed phenol. The set of bands 1790-1640 cm-1, probably, falls into to fluctuations of a carbonyl group of the carboxylic acids free and connected by a hydrogen bridge on an active charcoal surface. In difference spectra AG-3 after formaldehyde adsorption there are bands of fluctuations of group -С-О- (1300-1000 cm-1), also absorption bands for aliphatic aldehydes of 1230-1100 cm-1 caused by the valent and deformation fluctuations C-C-C in the group . Different spectra АC AG-3 after adsorption of a mix of organic matters at joint presence differs presence of more intensive bands of groups -ОН (3600-3400 cm-1), -С-О- (1300-1000 cm-1) and adsorbed phenol (3650-3520 and 1280-1010 cm-1). (b) (a) λ, cm-1 λ, cm-1 Fig. 6. Different spectra of active charcoals samples AG-3 (a), KsAU (b) after adsorption of organic matters. Area expansion of fluctuations to 3600 cm-1, probably, illustrates hydrogen connection between phenol and formaldehyde. In the field of 1790-1630 cm-1 fluctuations of a carbonyl group of the carboxylic acids free and connected by a hydrogen bridge, and also quinones are displayed. In different spectra АC KsAU after adsorption of a mix of phenol and formaldehyde the set of bands 1870-1540 cm-1 is observed, connected with valence vibrations of group C=O. The field 1800-1630 cm-1 corresponds to fluctuations of a carbonyl group of carboxylic acids free and connected by a hydrogen bridge, and also quinones. The strengthening of absorption bands in area (3600-3400 cm-1) in comparison with other samples is specified in occurrence of a hydrogen bridge -OH of groups of organic matters with oxygen-containing functional groups on АC surface. The absorption set of bands in area (3600-3400 cm-1) can be correlated with fluctuations phenolic and carboxyl groups on the active charcoal surface, being hydrolysate in the course of interaction of solvent with a sorbent. On the basis of experimental researches of the balance, the calculated adsorptive parametres and IR-spectroscopy data, it is possible to consider, that phenol and formaldehyde adsorption both from water solution of individual components, and from a mix has physical character and does not result in to strong linkage with an adsorbent. At joint adsorption of formaldehyde and phenol instead of adsorption of dimer structures on an active charcoal surface the increase aliphatic (-CH) and from -C-O- groups is observed. Hence, between phenol and formaldehyde there is an interaction both in water solution, and on an active charcoal surface where formaldehyde molecules are capable to represent themselves as the secondary adsorptive centres for phenol molecules. At joint adsorption between these connections, obviously, the effect of hydrogen bonding is displayed which is enough fragile that allows to assume possibility of effective regeneration of active charcoal after adsorption cleaning of water from a phenol and formaldehyde mix. According to kinetic researches it is positioned, that a limiting stage of process of extraction of small concentration organic contaminants from water (phenol, formaldehyde, acetic aldehyde) is external mass carry. Factors of external mass carry, necessary for engineering calculations [15, 16] are calculated. Experimental studying of adsorption dynamics assumes consecutive selection of parametres (sorbent type, length of fixed bed, rate of flow, etc.) and reception of experimental target curves depending on one varied variable (for example, rates of flow of a solution) at the fixed values of the others. Dynamics research of adsorption of mixes with phenol and formaldehyde, formaldehyde and acetic aldehyde from water on АC were made in columns in diameter of 1.7 cm with height of bed of loading 0.5 m, peripheral speed of a stream - 1m/h. Experimental researches of dynamics of adsorption showed, that at the continuous water purification containing mixes of organic contaminants, breakthrough of a dominating component is observed as the first from a column: for mixes phenol-formaldehyde and formaldehyde-acetic aldehyde - breakthrough of formaldehyde that allows to model adsorption process on a dominating component. Calculation is executed on the basis of the fundamental equation of external diffusion dynamics of adsorption in the field of low concentration with utilization of experimental data on balance and kinetics of sorption of organic matters on АC [17]. Coincidence of the experimental and theoretically calculated curves confirms legitimacy of the offered approach to modelling of adsorption and possibility of definition of dynamic characteristics of adsorption without additional carrying out of experimental researches (Fig. 7). According to the results of modelling of process of adsorption of the studied mixes dynamic characteristics are received: length of working bed, length of not used bed, protective effect factor, running time of a column and quantity of refined water depending on parametres of a column and a purification mode. Experimental results confirm possibility of modelling of adsorption process. Engineering calculations for practical adsorptive installation can be made on a dominating component. While working the efficiency of the adsorptive filters on extraction of pollutants drops, therefore their periodic regeneration is necessary for restoration of sorbents adsorbability. The possibility of utilization of the following methods of regeneration is experimentally studied: a steam, air stream, heated-up to 200°С and hot water. C/C0 1.0 0.8 0.6 0.4 0.2 Fig. 7. Target curves of dynamics of adsorption of formaldehyde in the presence of phenol for dense bed АC AG-3 (on theoretically calculated curves points experimental data are put) at different rates of flow (n) and height of bed of a sorbent (H): 1 - n = 1m/h, Н = 0.5 m; 2 - n = 1 m/h, Н = 1 m; 3 - n = 5 m/h, Н = 0,5 m; 4 - n = 5 m/h, Н = 1 m; 5 - n = 5 m/h, Н = 2 m; 6 - n = 8 m/h, Н = 0.5 m; 7 - n = 8 m/h, Н = 1 m; 8 - n = 8 m/h, Н = 2 m. For restoration of adsorbability of sorbents the technology of regeneration АC after adsorption of probed mixes - application of washing АC by water warmed up to 50°С, with the subsequent warm-up by a stream of air with temperature 200°С within 2 hours is offered, allowing to reduce sorptive capacity of sorbents on 95-98%. Thermogravimetric researches have preliminarily been made for a choice of temperature of thermal regeneration. The estimation of restoration of adsorption properties of АC after adsorption of aqueous mixes in laboratory conditions showed, that after the fifth cycle regeneration-sorption adsorbability has dropped on 16-22%. On the basis of theoretical and experimental researches of adsorption process the technology of afterpurification of drinking water from priority organic contaminants and their mixes on АC, providing drinking water upgrading is developed, the carbon sorbent and hardware decor of process is chosen, the way of regeneration of the fulfilled sorbents, allowing to carry out their repeated utilization without decrease in adsorption properties is offered. The production tests on “Talinka”, LLC have shown efficiency of the offered technology.