RU2209772C2 - Method of detoxification of water involving synergetic effect - Google Patents

Abstract

FIELD: nature-preservative technologies. SUBSTANCE: invention can be used for detoxification of both drinking and waste waters in a variety of areas. When method is performed in flow volumes, water flow is subjected to hydrodynamic cavitation treatment and then to UV irradiation, the first operation is effected stepwise with the aid of additionally installed cavitation exciters. Before cavitation treatment , water flow is narrowed to obtain flow velocity 19.0-28.0 m/s, for which aim cross-section areas in the steps are selected basing on following relationships: S= (13.2-14.6)10^-6Q, S_i = nh(d_i+a_i), where S₁ is first-step cross-section area, sq.m; Q water intake, sq.m/h; S_i i-step cross-section area, sq.m; a_i distance between i-step exciters, m; d_i i-step exciter diameter, m; n number of exciters in each step; h height of cavitation exciter in each step, m; (13,2-14,6)10^-6 is factor determining reverse value of water flow velocity before the first step of exciters, h/m. Cavitation exciters are mounted in the step cross-section using relationships:

+0.975i-0.3 and

Description

 The invention relates to the field of environmental protection, and in particular to the disinfection of both drinking and wastewater, can be used in agriculture and utilities for settlements with a population of up to 100,000 people, as well as food, microbiological and other industries.

 A known method of disinfection of wastewater, in which the flow of water is treated with hydrodynamic effects (see RF patent 2057079 from 03/27/96). The hydrodynamic effect is carried out in such a way that the flow is separated and passed through a series of parallel volumes made in the form of venturi tubes.

 The disadvantages of this method include the low intensity of cavitation processes, the consequence of which is the need for a second cycle of water treatment.

 There is also known a method of disinfecting water, in which flowing volumes carry out a synergistic effect on the disinfected stream, performing hydrodynamic treatment and subsequent treatment with ultraviolet radiation (see application France 2637582 from 04/13/90).

 The disadvantages of this method include the low efficiency of the hydrodynamic treatment, which is carried out by cavitation, by exciting the flow of cavitation phenomena with turbulence without additional cavitation-inducing techniques.

 The task was set for the developers: to create a method of disinfecting water with a synergistic effect with increased efficiency at the first stage of exposure - hydrodynamic cavitation, which ensures the destruction of colonies of microbial cells to the level of single cells and further destruction of the outer shell of each cell, at the second stage of exposure - ultraviolet radiation, providing the final sterilization of the flow, by affecting the protein colloids of the cells, changing their structure and dispersion that causes the death of a microbial cell.

 The purpose of the invention is to increase the efficiency of water disinfection by increasing the synergistic effect by intensifying hydrodynamic cavitation.

а ультрафиолетовое облучение проводят интенсивностью 13,5-15,0 мДж/см².This goal is achieved by the fact that in the method of disinfecting water with a synergistic effect, in which hydrodynamic cavitation treatment of a water stream and subsequent treatment with ultraviolet irradiation are carried out in flowing volumes, it is proposed that hydrodynamic cavitation be carried out in steps using additionally installed cavitation pathogens, while before starting the cavitation treatment, the water stream narrow until reaching a flow velocity of 19.0-28.0 m / s, for which the cross-sectional areas of the steps are selected shout, based on the following ratios:
S ₁ = (13.2 ÷ 14.6) • 10 ^-6 Q; (1)
S _i = nh (d _i + a _i ), (2)
where S ₁ - the cross-sectional area of the first stage, m ² ,
Q - water consumption, m ² / h,
S _i - the cross-sectional area of the i-th stage, m ² ,
and _i is the distance between pathogens of the i-th stage, m,
d _i - the diameter of the pathogen of the i-th stage, m,
n is the number of pathogens in each step,
h - height of cavitation pathogens in each stage, m,
(13.2 ÷ 14.6) • 10 ^-6 - coefficient determining the reciprocal of the flow rate of water in front of the first stage of pathogens, h / m,
at the same time, cavitation pathogens are installed in the section of the stage based on the ratios:

and ultraviolet irradiation is carried out with an intensity of 13.5-15.0 mJ / cm ² .

 The essence of the processes is explained as follows. The negative effect of cavitation - hydroabrasive wear of metals - in the proposed method was used as a positive effect aimed at breaking down the protective barriers of microorganism cells, which ensures disinfection of both drinking and wastewater.

Upon receipt of hydrodynamic cavitation treatment, the water flow is narrowed to a flow velocity of 19.0-28.0 m / s, then cavitation processes are excited at each processing stage, providing the formation of powerful shock waves, cumulative water micro-jets and high-temperature thermal pulses. The maximum intensity of cavitation falls on the value of the cavitation zone, the length of which depends on the diameter of the causative agent of cavitation (see Kozyrev S. P. Hydroabrasive wear of metals during cavitation M .: Mashinostroenie, 1964. - p. 34):
l = 3d _i ,
where d _i is the diameter of the cavitation pathogen, d _i = 3-12 mm.

 The multi-stage excitation of hydrodynamic cavitation requires that the areas of the compressed sections of the channel increase sequentially, otherwise the counterpressure of the next stage can destroy the cavitation torch of the previous one. The cross sections of the steps of the flow volume are calculated according to the above formulas (1) and (2).

 At a flow velocity of less than 19.0 m / s, the energy released during the passage of cavitation processes is not enough to break the protective barriers of microbial cells. At a speed of more than 28.0 m / s, studies have shown that the hydraulic resistance to the transmitted flow increases significantly due to the strong turbulization of the compressed section zones, which leads to a decrease in the flow energy aimed at the destruction of cells.

 The method is as follows.

The flow of disinfected water with a flow rate of Q and a speed of at least 19.0 m / s is directed into the flow volume to the first stage of exposure to hydrodynamic cavitation, which has a cross-sectional area S ₁ and the intensity of cavitation processes provided by the first stage cavitation pathogens. Here begins the process of destruction of solid microinclusions having an inorganic and organic composition, including living microorganisms in water, the death of part of living and weakened microorganisms, and the breakdown of specific protective barriers of microbial cells as a whole.

Subsequent stages of cavitation treatment with a cross-sectional area S _i with n pathogens of hydrodynamic cavitation in each stage allow the most complete use of the accumulated energy of the disinfected stream itself and contribute to further cell destruction, significantly increasing their sensitivity to ultraviolet radiation.

 Figure 1 presents the technological diagram of the implementation of the proposed method, figure 2 is a diagram of a flowing cavitation generator for implementing the proposed method of disinfecting water with a synergistic effect.

The treated water through the pipeline 7 through the valve 2, providing the required flow rate of 19.0-28.0 m / s, enters the first stage of the flow volume 3 in the form of a cavitation generator, in the housing 7 of which a rectangular channel is made. Symmetrically to the channel axis, steps of cylindrical cavitation pathogens with diameters are located: d ₁ - steps 8, d ₂ - steps 9, d ₃ - steps 10. The necessary back pressure in the system to change the length of the cavitation zone is created by an ultraviolet irradiation unit with a flow volume of 4 and a valve 5, which provides regulation of hydraulic resistance in the system of flow volumes 3 and 4.

 After treatment with hydrodynamic cavitation, the water stream is supplied for ultraviolet treatment in the flow volume 4, made in the form of a chamber with submersible sources of ultraviolet radiation, in which its final sterilization of the stream occurs. Then the treated stream of water is discharged through the pipeline 6 for the implementation of the further process.

To carry out the practical implementation of the method, the parameters of the flow volume of the hydrodynamic cavitation treatment were selected, the ultraviolet treatment parameters for the disinfection of drinking and wastewater for settlements with a population of 5,000, 20,000, 100,000 people with an hourly average flow rate and a coli index of _0, respectively:
a) for waste water 40, 160, 900 m ³ , C ₀ = 100000;
b) for drinking water 25, 100, 500 m ³ , C ₀ = 100.

 The parameters and research results are summarized in table.

 An example of the calculation of the flowing volume for the flow of wastewater Q = 40 m

1) According to the formula 7, we calculate the cross-sectional area of the first stage, m ² :
S ₁ = 13.5 • 10 ^-6 • 40 = 5.4 • 10 ^-4 .

 2) Accept, according to the specified range, the diameter of the pathogen of the first stage equal to d = 0.005 m

3) From formula 3, we calculate the distance between the pathogens of the first stage, m:
and ₁ = (- 0.175 • 1 ² + 0.975 • 1-0.3) • (0.005 = 0.0025.

4) From formula 4 we determine the height of the pathogens:
h = (0.125 • 1 ² -0.625 • 1 + 1.45) • (0.005 = 0.0048.

5) Find the width of the channel of the first stage as B ₁ = S ₁ / h, m,
B ₁ = 5.4 • 10 ^-4 / 0.0048 = 0.113.

6) The number of pathogens in the step is determined from formula 2 (with rounding up):
n = 5.4 • 10 ^-4 / (0.0048 (0.005 + 0.0025) = 15.

7) The diameter of the pathogens of the second and third stages is found from formula 4, m:
d ₂ = 0.0048 / (0.125 • 2 ² -0.625 • 2 + 1.45) = 6.9 • 10 ^-3 ,
d ₃ = 0.0048 / (0.125 • 3 ² -0.625 • 3 + 1.45) = 6.9 • 10 ^-3 .

8) Similarly to item 3, we calculate the distances a ₂ = 0.0066 m, and ₃ = 0.0072 m.

9) Using formula 2, we determine the cross-sectional area of the second and third steps, m ² : S ₂ = 15 • 0.0048 (0.0069 + 0.0066) = 9.7 • 10 ^-4 ; S ₃ = 15 • 0.0048 (0.0069 + 0.0072) = 10.2 • 10 ^-4 .

10) Similarly to item 5 we find the width of the channel of the second and third steps, m:
B ₂ = 9.7 • 10 ^-4 / 0.0048 = 0.202; B ₃ = 10.2 • 10 ^-4 / 0.0048 = 0.212.

 Based on the results obtained, it is seen that the use of the proposed method allows to increase the water flow through the ultraviolet installation by 11 ± 1%, which leads to a reduction in the cost of water treatment and an increase in the economic effect of using this technology.

Claims (1)

A method of disinfecting water with a synergistic effect, in which preliminary the hydrodynamic treatment of the water flow in a flow-type cavitation reactor is carried out, followed by ultraviolet radiation treatment, characterized in that the hydrodynamic cavitation is carried out stepwise with the help of additionally installed cavitation pathogens, while before starting the cavitation treatment the water flow is narrowed to reaching a flow rate of 19.0-28.0 m / s, for which the cross-sectional area of the steps is chosen, based on the following ratios:
S ₁ = (13.2-14.6) • 10 ^-6 Q;
S _i = nh (d _i + a _i ),
where S ₁ - the cross-sectional area of the first stage, m ² ;
Q - water consumption, m ³ / h;
S _i - the cross-sectional area of the i-th stage, m ² ;
and _i is the distance between pathogens of the i-th stage, m;
d _i - the diameter of the pathogen of the i-th stage, m;
n is the number of pathogens in each step;
h - height of cavitation pathogens in each stage, m;
(1.32-14.6) 10 ^-6 is a coefficient that determines the reciprocal of the flow rate of water in front of the first stage of pathogens, h / m;
at the same time, cavitation pathogens are installed in the section of the stage based on the ratios:

and ultraviolet irradiation is carried out with an intensity of 13.5-15.0 mJ / cm ² .

Images