RU2700505C1 - Method of reagent-free water filtration and disinfection - Google Patents

Abstract

FIELD: water and air purification technology.

SUBSTANCE: invention relates to a method of reagent-free water filtration and disinfection. Method includes hydroacoustic waves of sound and ultrasonic frequency range with amplitude of acoustic pressure of not less than 10⁴ Pa at 1 m from radiator surface in main module, in form of water intake header, in the first additional module, which is a water intake well, in the second additional module, in the form of a mixer. Processing in the third additional module, which is at least two settling tanks, is carried out by hydroacoustic waves of the sound and ultrasonic frequency range with amplitude of acoustic pressure of not less than 10² Pa at 1 m from surface of corresponding hydroacoustic radiator, treatment in a special structure, which is at least two transparent for ultraviolet irradiation water conduits, containing at least four ultraviolet lamps with hydroacoustic emitters of ultrasonic frequency range, radiation of ultraviolet light, as well as with ultrasound acoustic wave acoustic signal with amplitude of acoustic pressure of not less than 10⁵ Pa at 1 m from hydroacoustic radiator surface with additional use of hydroacoustic waves of sound and ultrasonic frequency bands with amplitude of acoustic pressure of not less than 10⁴ Pa at distance of 1 m from the surface of the hydroacoustic radiator buried in granular filter material in the geometric center of the bulk filter.

EFFECT: obtaining clean disinfected water in a large volume taken from surface water supply sources.

1 cl, 11 dwg

Description

The invention relates to the field of physics and can be used for: reagent-free water purification from suspended (explosive) substances (mineral and biological) - by physical (acoustic) coagulation of differently dispersed explosives, as well as by forced (in addition to gravity) deposition of initial explosives and earlier acoustically coagulated explosives, as well as for physical (acoustic) disinfection of water - by destroying pathogenic bacteria (BB) in it - under the influence of hydrogen peroxide and OH ⁰ radicals formed during dissociation and water molecules in cavitation formations, in the interests of preparing high-quality drinking water selected from surface water sources to improve the quality and life expectancy of the population; non-reagent wastewater treatment from explosives, heavy metals (TM), salts and BB - in the interests of ensuring environmental safety of production (for example, in the extraction of diamonds, etc.); reagent-free treatment of recycled water - in the interests of increasing production efficiency (for example, to reduce the loss of diamonds during their enrichment, etc.). Spn. 11 Ill.

There is a method of non-reagent water purification, which consists in almost complete - more than 95%, cleaning from coarse explosives (KDVV) -size of more than 50 microns and insignificant - less than 50%, cleaning from medium-dispersed explosives (ADVS) - from 5 microns to 50 microns in size, in the main sump; in full - 100%, purification from KDVV, in almost complete purification from ADV and insignificant purification from fine explosives (TDVV) - less than 5 microns in size, in the first additional sump; in full cleaning from ADHD and in almost complete cleaning from TDVV in the second additional sump; in complete cleaning from TDVV in a special facility - in an acoustic filter / Acoustic technology in mineral processing // Ed. B.C. Yamshchikova.- M .: Nauka, 1987, p. 225-228 /.

The main disadvantages of this method are:

1. Low productivity, due to the limited area of a special structure - an acoustic filter.

2. Insufficient quality of water purification from explosives.

3. The inability to purify water from BB - the inability to disinfect water, etc.

There is a method of non-reagent cleaning and disinfection of water, which consists in almost complete purification from KDVV, minor purification from ADV and minimal - less than 5% purification from TDVV, by periodic - with alternating radiation and pause modes, as well as sequential in frequency, formation in the main sedimentation tank traveling hydroacoustic waves (BGAW) of the sound frequency range (UHF) - in the frequency range from 16 Hz to 16 kHz and the ultrasonic frequency range (UHF) - in the frequency range above 16 kHz; complete cleaning from KDVV, almost complete cleaning from ADHD, minor cleaning from TDVV and BB in the first additional settling tank, by periodic - with alternating radiation and pause modes, as well as sequential frequency, the formation of BGAV ZDCh and UZDCH; complete cleaning from ADHD, almost complete cleaning from TDVV, minor cleaning from BB in the second additional sedimentation tank - by periodically and sequentially forming a BGAV ZDCh and UZDCH frequencies; in complete cleaning from TDVV, in almost complete cleaning from BB in the third additional settler - by periodically and sequentially generating standing hydroacoustic waves (GWA) of the airborne frequency and ultrasonic frequency division; in full cleaning from BB in a special structure - in an acoustic hydrocyclone (AGC) operating at an excess of static pressure of 3-5 atm .; Gravity deposition - in the main sedimentation tank, in the first, second and third additional sedimentation tanks, as well as in the special construction of previously acoustically coagulated KDVV, ADVV and TDVV; acoustic compaction of sediment in a special structure / Bakharev S.A. The method of purification and disinfection of circulating and waste water. - RF patent No. 2280490, 2005, publ. July 27, 2006, Bull. No. 21. FIPS Diploma in the nomination: “100 Best Inventions of Russia”. The main disadvantages of this method include:

1. Low productivity for water purification from explosives, due to the limited volume of the working chamber of the AGC.

2. Low productivity for water disinfection (for water purification from BB), due to the limited volume of the working chamber of the AGC.

3. The high cost of cleaning and disinfecting a unit volume of water (for example, 1 m ³ ).

4. The insufficient quality of water disinfection, due to only one stage of water disinfection - in the AGC.

5. The limited scope of the method (for example, due to the impossibility of implementation under ice), etc.

Closest to the claimed one, there is a method selected as a prototype method, purification and disinfection of water, which consists in almost complete purification from KDVV, minor purification from ADVV and insignificant purification from TDVV, by emitting BGAV ZDCh in the main module for water purification; in full cleaning from KDVV, almost complete cleaning from ADHD, minor cleaning from TDVV, insignificant cleaning from colloidal particles (CFCs) and BB, by radiation of the BWA of the ZDV in the first additional module; in full cleaning from ADHD, almost complete cleaning from TDVV, minor cleaning from CS and BB, by emitting BGAV ZDCh and SPL in the second additional module; in full cleaning from TDVV, in almost complete cleaning from CS and BB, by radiation of BHAV ZDCh in the third additional module; in complete cleaning from the control and safety factors in a special facility - in a magneto-acoustic hydrocyclone (MAGC); Gravity deposition - in the main module, in the first additional module, in the second additional module and in the third additional module, as well as in the special building of the previously acoustically coagulated KDVV, SDVV, TDVV and KCh; acoustic compaction of sediment in a special facility. At the same time, water purified from explosives and BBs is additionally irradiated with a high-frequency electromagnetic field - ultraviolet light, in the MAGC; additionally carry out preliminary (acoustic) drying of the precipitate to transport humidity and final (thermal) drying of the precipitate followed by packing (sediment) / Bakharev S.A. The method of purification and disinfection of water. - RF patent No. 2487838, 2011, publ. 07/20/2013, Bull. No. 20 /.

The main disadvantages of the prototype method include:

1. Insufficient quality of water treatment.

2. Insufficient quality of water disinfection.

3. Limited scope.

For example, due to the impossibility of implementing the method: in the winter period (under ice), to improve the quality of the work of bulk filters, to improve the quality and efficiency of washing the filter material of bulk filters, etc.

The problem that is solved by the invention is to develop a method free from the above disadvantages.

The technical result of the proposed method consists in high-quality - to the requirements of SanPiN (2.1.4.1074-01 (Drinking water), physical - without the use of chemical reagents (for example, aluminum sulfate, etc.) cleaning, as well as in qualitative and physical - without using chemical preparations (for example, chlorine, etc.) disinfection of large (up to 50 thousand m ³ per day or more) volumes of water taken from surface water sources, in a relatively simple way with minimal financial and time costs, in any weather and climate environmental conditions (under ice, etc.) with ensuring medical safety - for humans and environmental safety - for the environment (OPS).

This goal is achieved by the fact that in the known method of non-reagent purification and disinfection of water, which consists in cleaning from coarse suspended solids (KDVV), from medium-dispersed suspended solids (ADVV) and from fine-dispersed suspended substances (TDVV) - by emitting traveling hydroacoustic waves ( BGAV) sound frequency range (UHF) and ultrasonic frequency range (UHF) in the main water treatment module; in purification from KDVV, from ADHD, from TDVV, from KCh and from pathogenic bacteria - by radiation of BGAV ZDCh and UZDCh in the first additional module; in purification from ADHD, from TDVV, from CK and from pathogenic bacteria - by radiation of BHAV of ZDCh and SPL in the second additional module; in the cleaning of TDVV, from CN and pathogenic bacteria, by emitting BGAV ZDCH and UZDCH in the third additional module; in cleaning from CN and from pathogenic bacteria in a special building, in gravity sedimentation - in the main module, in the first additional module, in the second additional module and in the third additional module, as well as in the special building, previously acoustically coagulated by KDVV, SDVV, TDVV and CS, in acoustic compaction of sediment, in irradiation of water purified from pathogenic bacteria by ultraviolet light, in the main water purification module, which is used as the tip of the water intake, carry out: significant - more than 50%, about source of KDVV, insignificant - less than 50%, purification from ADHD, insignificant - less than 25%, purification from TDVV, minimal - less than 5%, purification from CN and insignificant purification from pathogenic bacteria - by directed: towards-up and towards-down the flow of water in a natural surface water stream (in a river) of radiation from the BHAF ZDCH and UZDCH with an amplitude of acoustic pressure of at least 10 ⁴ Pa at a distance of 1 m from the surface of the corresponding sonar emitter; in the first additional module for water purification, which is used as a water intake well, they carry out: substantial - more than 75%, purification from KDVV, significant purification from ADHD, insignificant purification from TDVV, insignificant purification from CN and insignificant purification from pathogenic bacteria - by directed: into a gravity pipe, as well as non-directional - on the middle horizon of the water intake well, radiation of the high-pressure water and airborne detectors with a sound pressure amplitude of at least 10 ⁴ Pa at a distance of 1 m from the surface of the corresponding hydroacoustic pump oral emitter; in the second additional module, the water purification, which is used as a mixer, is carried out: complete purification from KDVV, almost complete purification from ADV, substantial purification from TDVV, significant purification of water from KP and significant purification from pathogenic bacteria - by non-directional: on the average horizon of the mixer radiation BGAV ZDCH and UZDCH with an amplitude of acoustic pressure of at least 10 ⁴ Pa at a distance of 1 m from the surface of the corresponding sonar emitter; in the third additional module, water purification, which is used as a few - at least two, identical to each other sedimentation tanks, is carried out: complete water purification from ADW, almost complete water purification from TDVV and significant water purification from CN, as well as sediment compaction by non-directional : on the mid-horizon of the corresponding sedimentation tank, radiation of the high-frequency acoustic waves of the airborne sound generator and ultrasonic sonicator with an acoustic pressure amplitude of at least 10 ² Pa at a distance of 1 m from the surface of the corresponding sonar emitter; in the fourth additional module, which is used as a few - at least two, identical to each other, bulk filters (filters with a layer of granular filter material), carry out: complete water purification from TDVV, as well as almost complete cleaning from the filter by indirect: upper horizon corresponding bulk filter and the emission BGAV ZDCH UZDCH with acoustic pressure amplitude of at least 10 ² Pa at a distance of 1 m from the surface of the respective hydroacoustic transducer, and by delaying (str infusion) acoustically TDVV and coagulated in ZFM CN; in a special building, which is used as several - at least two, identical to each other, transparent (for ultraviolet irradiation) conduits with several - at least four, identical to each other with ultraviolet lamps and with several - at least four, identical to each other with hydroacoustic emitters UZDCH, carry out a complete purification of water from pathogenic bacteria - by directing radiation of ultraviolet light (high-frequency electromagnetic waves), as well as by directing radiation ZDCH with acoustic pressure amplitude of at least 10 ⁵ Pa at a distance of 1 m from the surface of the corresponding sonar transmitter; additionally, for accelerated and better washing of the ZFM, they use BGAV ZDCH and UZDCH with an acoustic pressure amplitude of at least 10 ⁴ Pa at a distance of 1 m from the surface of the corresponding sonar emitter buried in the ZFM in the geometric center of the corresponding bulk filter.

In FIG. 1 - FIG. 7 is a structural diagram of a device that implements the developed method of a non-reagent treatment and disinfection of water (hereinafter - the developed method). In this case: in FIG. 1 illustrates a structural diagram of a device as applied to the general principle of implementation of the developed method; in FIG. 2 illustrates the structural diagram of the device with respect to the implementation of the developed method in the main module of water purification (GMO) - in the head of the water intake; in FIG. 3 illustrates a block diagram of a device in relation to the implementation of the developed method in the first additional module of water purification (PDMOV) - in the water intake well; in FIG. 4 illustrates a block diagram of a device in relation to the implementation of the developed method in the second additional module of water purification (VDMOV) - in the mixer; in FIG. 5 illustrates the structural diagram of the device with respect to the implementation of the developed method in the third additional module of water purification (TDMOV) - in several, at least two, identical to each other, sumps; in FIG. 6 illustrates the structural diagram of the device in relation to the implementation of the developed method in the fourth additional module of water purification (CHDMOV) - in several, at least two (by the number of sedimentation tanks), identical to each other, bulk filters; in FIG. 7 illustrates the structural diagram of the device in relation to the implementation of the developed method in a special structure (ATP) - in several, at least two, transparent (for ultraviolet light) conduits with several - at least four, ultraviolet lamps and with several - at least four, directed by hydroacoustic UZDCH emitters.

A device for reagent-free water purification and disinfection, in the simplest case, contains (Fig. 1 - Fig. 7) sequentially functionally connected: a natural surface (PPV) watercourse (1) - a river (with an upper boundary (water surface) - a wavy line and direction water flow - double line with a tip) - source of source water (containing: TDVV, SDVV, TDVV, KCh and BB); the head (2) of the water intake (S), intended for receiving the source water ~ from the middle horizon of the natural surface watercourse (1) - from the horizon ~ 2 m with a depth of implementation of the developed method; figure 2 illustrates the structural diagram of the device in relation to the implementation of the developed method in the main module of water purification (GMO) - in the tip of the water intake; in FIG. 3 illustrates a block diagram of a device in relation to the implementation of the developed method in the first additional module of water purification (PDMOV) - in the water intake well; figure 4 illustrates the structural diagram of the device in relation to the implementation of the developed method in the second additional module of water purification (VDMOV) in the mixer; figure 5 illustrates the structural diagram of the device in relation to the implementation of the developed method in the third additional module of water purification (TDMOV) - in several, at least two, identical to each other, sumps; figure 6 illustrates the structural diagram of the device in relation to the implementation of the developed method in the fourth additional module of water purification (CHDMOV) - in several, at least two (by the number of sedimentation tanks), identical to each other, bulk filters; in FIG. 7 illustrates the structural diagram of the device in relation to the implementation of the developed method in a special structure (ATP) - in several, at least two, transparent (for ultraviolet light) conduits with several - at least four, ultraviolet lamps and with several - at least four, directed by hydroacoustic UZDCH emitters.

A device for non-reagent cleaning and disinfection of water, in the simplest case, contains (Fig. 1 - Fig. 7) sequentially functionally connected: a natural surface (PPV) watercourse (1) - a river (with an upper boundary - a wavy line and the direction of water flow - double line with a tip) - source of source water (containing: TDVV, SDVV, TDVV, KCh and BB, as well as: underwater terrorists, fish and biofouling); the head (2) of the intake (ОВ), intended for receiving the source water ~ from the middle horizon of the PPV (1) - from the horizon ~ 2 m at a river depth of ~ 4 m, with a trash holding grid (3) with a mesh of ~ 40 × 40 mm, intended for protect OM (2) from large debris (branches, etc.), as well as with a flat mesh (4) mesh ~ 4 × 4 mm, designed to protect OM (2) from small debris (leaves, etc.) functionally forming GMOs (5); gravity (6) line (SL) - a gravity pipe, which, on the one hand, is the output of the GMO (5), and on the other hand, is the entrance to the PDMOV (8), which, in turn, is the input of the SVPD (7), : water intake (MIC) well (9), which is the first supply tank of the source water, the first suction line (10), which is the output of PDMOV (8); a pumping station (11) of the first (HC-1) lift with a second suction line (12), which, like the first suction line (10), is a transport line for the source water, and also is the entrance to the VDMOV (13), which is consistently functionally connected: a mixer (14), which is, on the one hand, the second supply tank for the source water, and on the other hand (in the case of using chemical reagents) - a tank for mixing the source water and a solution of chemical reagents, as well as a discharge pipe (15), being on one side , the exit of VDMOV (13), and on the other hand, the entrance to the TDMOV (16), which contains, in turn, several - at least two, identical to each other, sumps (17), intended for rough cleaning (clarification) of water with the corresponding prefabricated gutters (18) - for continuous and uniform collection of roughly treated water, and with the first outlet channel (19) - TDMOV outlet (16), for its removal from sedimentation tanks (17), as well as with corresponding waste outlets (20) - for regular (as necessary) discharge (discharge) of sludge from sedimentation tanks (17) into the first discharge pipe (21) and further, using a sand pump (22), to the sludge site (23); ChDMOV (24) as a part of several - at least two, identical to each other, bulk filters (25), intended for fine purification (clarification) of water, with corresponding sockets (26) - for distributed discharges of treated water to the upper parts of bulk filters (25) ), with the corresponding layers of granular (ZFM) filtering (27) material (sand, crushed anthracite, expanded clay, etc.) located (material) in the lower parts of the bulk filters (25) and designed to detain (capture) TDVV and KCh in ZFM (27), with relevant collections (28) t purified water, with appropriate dispensers (29) of water flows designed to distribute the flows of finely purified water (regular operation of bulk filters) and wash water (after flushing with ZFM), with a second outlet channel (30), which, on the one hand, is an outlet ChDMOV (24), and on the other hand, by entering the ATP (31), which contains in parallel and sequentially functionally connected: a divider (32) of finely purified water flows, several - at least two, identical to each other, transparent - for ultraviolet irradiation, water conduits (33) s n with several - at least four, identical to each other, ultraviolet lamps (34) and with several - at least four, identical to each other, directed by sonar emitters (35) of the ultrasonic ultrasonic treatment device, a combiner of purified (clarified) and disinfected water flows (36) and a water conduit ( 37) for completely purified and disinfected water, which is the output of the SVPD (7).

The device also contains (Fig. 1 and Fig. 2): the first acoustic (PAM) module (38), consisting of parallel and sequentially functionally connected: the first (39) signal generator ZDCH and UZDCH F ₁ , the first power amplifier (40) signals ZDCh and UZDCH F ₁ , the first matching device (41), the first signal cable of the cable (42) and the first directed in vertical and horizontal planes towards the water flow and up to the surface of the water, sonar emitter (43) ZDCh and UZDCH F ₁ attached using the first mounting device (44) to OB (2); the second (45) generator of signals ZDCH and UZDCH F ₂ , the second power amplifier (46) signals ZDCH and UZDCH F ₂ , the second matching device (47), the second signal cable (48) and the second directional in vertical and horizontal planes - towards the water flow and down - in the direction of the bottom, sonar emitter (49) ZDCH and UZDCH F ₂ , attached by means of the second mounting device (50) to the OB (2).

The device also contains (Fig. 1 and Fig. 3): a second acoustic (VAM) module (51), consisting of parallel and sequentially functionally connected: a third (52) signal generator ZDCH and UZDCH F ₃ , a third power amplifier (53) signals ZDCh and UZDCH F ₃ , the third matching device (54), the third signal cable (55) and the third directed in vertical and horizontal planes - towards the flow of the source water, sonar emitter (56) ZDCh and UZDCH F ₃ attached with third mounting device (57) to bottom B R (9) - on the horizon trunk (6); the fourth (58) generator of signals ZDCH and UZDCH F ₄ , the fourth power amplifier (59) signals ZDCH and UZDCH F ₄ , the fourth matching device (60), the fourth signal cable-cable (61) and the first omnidirectional sonar emitter (62) ZDCh and UZDCH F4, posted using the first cable (63) at the first buoyancy (64) - on the horizon of the first suction line (10).

The device also contains (Fig. 1 and Fig. 4): a third acoustic (TAM) module (65), as part of a series of functionally connected: a fifth (66) signal generator ZDCH and UZDCH F ₅ , a fifth power amplifier (67) signal ZDCh and UZDCH F ₅ , the fifth matching device (68), the fifth signal cable (69) and the second omnidirectional hydroacoustic emitter (70) ZDCh and UZDCH F ₅ , posted by the second rope (71) on the second buoyancy (72) - on the horizon discharge pipe (15).

The device also contains (Fig. 1 and Fig. 5): the fourth acoustic (CHAM) module (73), consisting of parallel and sequentially functionally connected: several - at least two identical sixth generators (74) of the ZDCh and UZDCH signals F ₆ , several - at least two, sixth power amplifiers (75) identical to each other (ZDCH) and UFDF signals F ₆ , several - at least two, sixth identical matching devices (76), several - at least two, sixth identical cable ropes (77) and several - at least two identical to each other to each other of the third omnidirectional hydroacoustic emitters (78) ZDCh and UZDCH F ₆ , posted with the help of several - at least two, identical third ropes (79) on several - at least two, identical to each other third buoyancy (80) - on the middle horizon several - at least two, identical to each other sedimentation tanks (17).

The device also contains (Fig. 1 and Fig. 6): a reservoir (81) for circulating (washing for bulk filters) water, with a pump (82) for circulating water, with a pressure pipe (83) for circulating water, with several not less than three - on the left, in the center and on the right, for each of several - at least two, identical bulk filters (25), distributors of circulating water (84) that ensure uniform flushing of the ZFM (27), as well as with several - at least two (according to the number of bulk filters) second collecting chutes (85) identical to each other for circulating water and with a second waste pipe (86) for recycled water, through which the recycled water is sent to the structure (87) for cleaning the recycled water.

The device also contains (Fig. 1 and Fig. 6): the fifth acoustic (PTAM) module (88), consisting of parallel and sequentially functionally connected: several - at least two, identical to each other seventh generators (89) of signals ZDCH and UZDCH F ₇ , several - at least two, seventh power amplifiers (90) identical to each other, of the ZDCh and UZDM F ₇ signals, several - at least two, seventh matching devices identical to each other (91), several - at least two, seventh identical signal cable ropes (92) and several - at least two, ide of the fourth undirectional sonar emitters (93) of the ZDCh and UZDCH F ₇ , hung with each other by means of several - at least two, identical fourth ropes (94) on several - at least two, identical fourth buoyancy (95) - on the upper horizons of several - at least two identical bulk filters (15); several - at least two, identical to each other, eighth generators (96) of the ZDCh and UZDM F ₈ signals, several - at least two, identical to each other of the eighth power amplifiers (97) of the signals of ZDCh and UZDCH F ₈ , several - at least two, identical each other of eighth matching devices (98), several - at least two, identical to each other of the eighth signal cable cables (99) and several - at least two, identical to each other of the fifth omnidirectional hydroacoustic emitters (100) ZDCH and UZDCH, attached with several - at least two, identical of fourth fastening devices (101) to each other on the bottoms of several - at least two identical bulk filters (25).

The device also contains (Fig. 1 and Fig. 7): the sixth acoustic (SHAM) module (102), consisting of parallel and sequentially functionally connected: several - at least two, identical to each other, the first two-channel generators (103) of the UFD signals F ₉ , a few - at least two, identical to each other, first two-channel power amplifiers (104) of the UFDM signals F ₉ , several - at least two, identical to each other, of the first two-channel matching devices (105), several - at least four, identical ninth signal cable cable (106), and several - at least four identical to each other Fourth directed sonar emitters (35) UZDCH F ₉ mounted inside a suitable transparent (for ultraviolet irradiation) conduit (33), ATP (31).

The device also contains a first electromagnetic module (107) consisting of parallel and sequentially functionally connected: several - at least two, identical to each other first two-channel generators (108) of high-frequency electromagnetic signals of the ultraviolet spectrum f _UVS , several - by the number of generators (108), identical each other of the first two-channel power amplifier (109) high frequency electromagnetic signals f _UVC ultraviolet spectrum, several - at least four - in the number of channels power amplifiers (109), identical to each other HF signal cables 110 and several - at least four identical directions to each other - in the transparent (to ultraviolet irradiation) conduit (33), ATP (31), emitters (34), high frequency electromagnetic signals ultraviolet spectrum f _UVs attached using several - according to the number of emitters (34), identical to each other of the fifth fastening devices (111) to the water conduits (33) of the ATP (31).

A device for the reagent-free purification and disinfection of water (for example, during the preparation of drinking water for the district center of Kamyzyak in the Astrakhan region) in the simplest case works as follows (Fig. 1 - Fig. 7).

At the same time, we initially take into account the following facts: - in this region of the Russian Federation in the summer period (high - up to 50 ° C and above, ambient temperatures, which contributes to the active reproduction of BB in surface watercourses;

- in this region of the Russian Federation in the summer, a large number of BBs are recorded in the water intake well, in various pipelines (gravity, pressure, etc.);

- in this region of the Russian Federation during the summer period, water consumption (irrigation of gardens, etc.) varies many times a day (up to 3 times or more: the maximum water flow rate is from 19:00 to 23:00, the minimum water flow rate is from 01 : 00 to 05:00);

- in this region of the Russian Federation (due to periodic discharges of water from the reservoirs of the hydroelectric power station cascade in the Volgograd Region — upstream of the Volga River) in the spring and summer periods, the explosive content in the source water can change many times (up to 3 times or more) during days;

- in this region of the Russian Federation (with a sharply continental climate) in the spring, autumn and winter periods (due to low - below 8 ° C, water temperatures in rivers) the effectiveness of the use of chemicals (for example, based on sulfate A1) for water treatment from explosives and cf is greatly reduced;

- in this region of the Russian Federation, treatment facilities of water treatment plants are morally and physically outdated, therefore the quality of drinking water often does not meet the standards, etc.

Source water, containing large amounts of up to 20 mg / l or more, variously dispersed explosives (KDVV, SDVV and TDVV), KCh and BB, from the middle (from the horizon ~ 2 m at the river depth ~ 4 m) PPV horizon (1) sequentially direct: through the trash holding grid (3) with mesh ~ 40 × 40 mm - to protect the OM (2) from large debris (from branches, etc.), and also through a flat mesh (4) with mesh ~ 4 × 4 mm - to protect OM (2) from small debris (leaves, etc.). At the same time, the protection of OM (2) from the BB is absolutely not provided.

In order to minimize or completely eliminate these negative impacts, PAM (38) is used in OM (2) of GMOs (5).

To do this, using series-functionally connected: the first generator (39), the first power amplifier (40), the first matching device (41) and the first signal cable (42), the signal is generated, amplified and transmitted (practically without energy loss) and UZDCh at a frequency of F ₁ to the first directed in the vertical and horizontal planes, as well as towards the flow of the source water and up to the surface of the water, sonar emitter (43), attached by means of the first mounting device (44) to the OB (2 )

As a result, under the influence of an acoustic wave at a frequency of F ₁ and with an amplitude of acoustic pressure of at least 10 ⁴ Pa at a distance of 1 m from the surface of the corresponding hydroacoustic emitter, the trajectory of the explosive, cn, and BB is changed in the flow of the moving (river flow) source water.

In particular, part of the explosives, cores, and BBs gradually — as they approach the working surface of the directional sonar emitter (43) and contrary to the force of gravity — are raised — by the front of the acoustic wave, above the water intake horizon (~ 2 m), and transported — by the river, down down the river.

At the same time, using a series-functionally connected: second (45) generator, second power amplifier (46), second matching device (47) and second signal cable (48), the signal is formed, amplified and transmitted (practically without energy loss) of the signal ZDCh and UZDCh at a frequency of F ₂ to the second directed in the vertical and horizontal planes, as well as towards the flow of the source water and downward, the hydroacoustic emitter (49), attached with the help of the second mounting device (50) to the OB (2).

As a result, under the influence of an acoustic wave at a frequency of F ₂ with an amplitude of acoustic pressure of at least 10 ⁴ Pa at a distance of 1 m from the surface of the corresponding hydroacoustic emitter, the trajectory of the explosive, cn, and BB is changed in the flow of the moving (river flow) source water.

In particular, part of the explosives, cores, and BBs, gradually, as they approach the working surface of the directed hydroacoustic emitter (49) and in addition to the force of gravity, are lowered by the front of the acoustic wave, below the water intake horizon (~ 2 m), and transported by the river down the river.

In addition (except for changing the motion paths in the flow of the source water of explosives, cores, and BB), under the influence of acoustic waves at frequencies F ₁ and F ₂ with amplitudes of acoustic pressure of at least 10 ⁴ Pa at a distance of 1 m from the surface of the corresponding sonar emitter, carry out: acoustic coagulation of dispersed explosives (between themselves, as well as with BB) sent together with the water flow to the OM (2): partial acoustic disinfection of the source water at a distance of up to 2 m from the working surface of the corresponding sonar emitter - direct effects from the implementation of the developed method in GMOs (5).

It should be noted that the bactericidal effect on the microflora is primarily caused by hydrogen peroxide and OH ^° radicals, which are formed during the dissociation of water molecules in cavitation formations.

However, in the water directed along the SL (6) to the military-industrial complex (9), explosives, CN and BB remain.

In order to minimize, or completely eliminate these negative impacts, in the military-industrial complex (9) PDMOV (8), VAM is used (51).

To do this, using series-functionally connected: a third generator (52), a third power amplifier (53), a third matching device (54) and a third signal cable (55), the ZDCH signal is generated, amplified and transmitted (practically without energy loss) and UZDCH at frequency F ₃ directed to the third in the vertical and horizontal planes, and directed upstream of the initial water supplied from the trunk (6) MIC (9), hydroacoustic emitter (56) attached by the third krepezhnog Device (57) to the bottom (the lower part) MIC (9) on the horizon trunk (6); the fourth generator (58), the fourth power amplifier (59), the fourth matching device (60) and the fourth signal cable cable (61) generate, amplify and transmit (practically without energy loss) the signal ZDCH and UZDCh at a frequency of F ₄ to the first an omnidirectional sonar emitter (62), hung with the first cable (63) on the first buoyancy (64) - on the horizon of the first suction line (10).

As a result, under the influence of acoustic waves at frequencies F ₃ and F ₃ with amplitudes of acoustic pressure of at least 10 ⁴ Pa at a distance of 1 m from the surface of the corresponding sonar emitter, acoustic coagulation (second conditional line) of differently dispersed explosives (among themselves, and also with CS and BB), in the water stream at the outlet of the SL (6) using a sonar emitter (56), in the entire volume of water in the military-industrial complex (9) and in the water stream, at the entrance to the first suction line (10) - at sonar transducer aid (62), partial acoustic water disinfection (the second conditional line) in the immediate vicinity of the working surfaces of sonar emitters (56) and (62) - direct effects from the implementation of the developed method in PDMOV (8).

However, in the water directed along the first suction line (10) to the mixer (14), explosives, cores, and BBs may remain.

In order to minimize or completely eliminate these negative effects, TAM (65) is used in the mixer (14) of the VDMOV (13).

To do this, using series-functionally connected: the fifth generator (66), the fifth power amplifier (67), the fifth matching device (68) and the fifth signal cable (69), the signal is generated, amplified and transmitted (practically without energy loss) and UZDCH at a frequency of F ₅ to the second undirectional sonar emitter (70) of ZDCh and UZDCH, posted with a second cable (71) on the second buoyancy (72) - on the horizon of the discharge pipeline (15).

As a result, under the influence of acoustic waves at a frequency of F ₅ with an amplitude of acoustic pressure of at least 10 ⁴ Pa at a distance of 1 m from the surface of the corresponding sonar emitter, acoustic coagulation (third conditional line) of differently dispersed explosives (between themselves, as well as with BB), in the entire volume of the mixer (14); partial acoustic disinfection of water (the third conditional line) at a distance of up to 2 m from the working surface of the corresponding sonar emitter - direct effects from the implementation of the developed method in VDMOV (13).

At the same time (concomitant effects) under the influence of acoustic waves at a frequency of F ₅ with an amplitude of acoustic pressure of at least 10 ⁴ Pa at a distance of 1 m from the surface of the corresponding sonar emitter, physical destruction is carried out - at a distance of 2 m from the surface of the corresponding sonar emitter, BO (mollusk Dreisen, etc.).

However, in the water directed along the first suction line (15) to several, at least two, identical to each other sedimentation tanks (17) of TDMOV (16), explosives, CFCs and BBs can remain. In order to minimize or completely eliminate these negative impacts, ChAM (73) is used in several, at least two, identical to each other sumps (17) TDMOV (16).

To do this, using parallel in series functionally connected: sixth generators (74), sixth power amplifiers (75), sixth matching devices (76) and sixth signal cable cables (77), the signals are generated, amplified and transmitted (practically without energy loss) ZDCh and UZDCh at frequencies F ₆ to the third non-directional hydroacoustic emitters (78) ZDCh and UZDCH posted by third ropes (79) on the third buoyancy (80) - at the middle horizons of several - at least two, identical settlers (17) .

As a result, under the influence of acoustic waves at frequencies F ₆ with an amplitude of acoustic pressure of at least 10 ² Pa at a distance of 1 m from the surface of the corresponding sonar emitter, acoustic coagulation (fourth conditional line) of different dispersed explosives (between themselves, as well as with BB and BO) in all working volumes identical to each other several - at least two, sedimentation tanks (17). At the same time carry out acoustic compaction of sediment.

Subsequently, the upper layers of roughly treated water continuously and uniformly along the corresponding collection channels (18) and along the first outlet channel (19), which is the outlet of the TDMOV (16), are withdrawn from several - at least two identical settling tanks (17) and sent to several - at least two, identical to each other, bulk filters (25) ChDMOV (24) and flows of treated water in the upper layers of the water of bulk filters (25) are evenly distributed over the corresponding bells (26).

At the same time, according to the discharge discharges (20), which are identical to each other, regularly (as necessary) discharge (discharge) the compacted sediment from the sumps (17) into the first discharge pipe (21), and then, using a sand pump (22), transport it to silt site (23).

Subsequently, in the corresponding ZFM (27) of the corresponding bulk filters (25), TDVV and KCh in the ZFM (27) are detained (captured), and finely purified water, according to the corresponding collections (28) of finely purified water, through open (operating mode of bulk filters) distributors (29) and through the second tap channel (30), which is the output of the ChDMOV (24), are sent to the ATP (31).

However, in finely purified water directed through the second bypass channel (30) to the ATP (31), explosives, cores, and BBs can remain. In order to minimize or completely eliminate these negative influences, PTAM (88) is used in several, at least two, identical bulk filters (25) of the PMDS (24).

To do this, using parallel-functionally connected: seventh generators (89), seventh power amplifiers (90), seventh matching devices (91) and seventh signal cable cables (92), signals are generated, amplified and transmitted (practically without energy loss) ZDCh and UZDCh at frequencies F ₇ to the fourth non-directional hydroacoustic emitters (93) ZDCh and UZDCH posted by means of the fourth ropes (94) on the fourth buoyancy (95) - on the upper horizons of several - not less than two, identical to each other bulk filters (25).

As a result, under the influence of acoustic waves at frequencies of F ₇ with an amplitude of acoustic pressure of at least 10 ² Pa at a distance of 1 m from the surface of the corresponding sonar emitter, acoustic coagulation (fifth conditional line) of differently dispersed explosives (among themselves, as well as with the RF, BB and BO) in all water working volumes identical to each other several - at least two, bulk filters (25).

However, during operation, the corresponding ZFM (27) of the corresponding bulk filters (25) gradually accumulate the maximum amount of impurities (clogged with impurities), and cease to purify water qualitatively. Moreover, TZHVV and KCh always with insufficient high efficiency detain in bulk filters (27) bulk filters (25). Also, a large amount (tens of minutes) of time and washing water (up to 30% or more of the volume of drinking water prepared using bulk filters) is spent on washing the ZFM (27) of bulk filters (25).

In order to minimize or completely eliminate these negative effects, in several, at least two identical to each other ZFM (27) bulk filters (25) ChDMOV (24) the following are used: PTAM (88).

To do this, using parallel in series functionally connected: eighth generators (96), eighth power amplifiers (97), eighth matching devices (98) and eighth signal cable cables (99) generate, amplify and transmit (practically without energy loss) signals ZDCh and UZDCh at frequencies F ₈ to the fifth non-directional hydroacoustic emitters (100) ZDCh and UZDCH attached with several - at least two, identical to each other fourth fastening devices (101) to the bottoms of several - at least two, are identical x bulk filters (25).

At the same time, in the process of washing the ZFM (27) of bulk filters (25), recycled (washing for bulk filters) water from the tank (81), thanks to the pump (82) for recycled water, several at least two identical to each other pressure pipelines (83) for recycled water, and several - at least three (left, center and right of the corresponding ZFM of the corresponding bulk filter) for each of several - at least two identical bulk filters (25), are uniformly directed into corresponding ZFM (27) of the corresponding bulk filter (25).

Then, after the washing process of the corresponding ZFM (27) of the corresponding bulk filter (5) is completed, the contaminated circulating (flushing) water, through the second collecting chutes (85) and through the second discharge pipe (86) for circulating water, is sent to the structure (87) for cleaning recycled water.

As a result, under the influence of uniform flows of circulating (flushing) water and acoustic waves of the air discharging device and ultrasonic ultrasonic treatment at frequencies F ₈ , the corresponding ZFM (27) of the corresponding bulk filters (25) are completely freed from the explosives and air filters that were previously detained in the shortest possible time and at the minimum cost of circulating (flushing) water.

Subsequently, finely purified water is sequentially directed into parallel and sequentially functionally connected divider (32) of flows of finely purified water, several - at least two, identical to each other, transparent - for ultraviolet irradiation, water conduits (33) with several - at least four, identical each other, with ultraviolet lamps (34) and with several - at least four, identical to each other, sonar emitters (35) of the ultrasonic ultrasonic treatment device, a combiner of purified (clarified) and disinfected water flows (36) and a water conduit (37) for I purified and disinfected water, which is the output of the SVPD (7).

Moreover, with the help of series-functionally connected: first two-channel generators (103), first two-channel power amplifiers (104), several - at least two, identical to each other first two-channel matching devices (105) and several - at least four, identical to each other ninth signal cable cables (106) generate, amplify, and transmit (practically without energy loss) the ultrasonic ultrasonic distribution signals at frequencies of F ₉ to several - at least four, identical to each other fourth directional hydroacoustic signals to teachers (35) of the UFD F ₉ installed inside two identical to each other transparent (for ultraviolet light) water conduits (33) ATP (31).

Under the influence of ultrasonic ultrasonic signals at frequencies F ₉ , acoustic disinfection is carried out, including water that is not completely purified from TDVV and KCh, as a result of cavitation processes in the voiced liquid. In particular, due to the bactericidal action of hydrogen peroxide and OH ° radicals, which are formed during the dissociation of water molecules in cavitation formations.

At the same time, using series-functionally connected: the first two-channel generators (108) of high-frequency electromagnetic signals of the ultraviolet spectrum f _yfc , the first two-channel power amplifiers (109) of high-frequency electromagnetic signals of the ultraviolet spectrum f _yfc , several - at least four - according to the number of channels of power amplifiers (109), identical to each other, high-frequency signal cables (PO) form, amplify and transmit (practically without energy loss) ultra-high-frequency signals oletovogo spectrum f _yfs to several - at least four identical to each other a fourth direction - towards two transparent (for ultraviolet irradiation) conduits (33) emitters (34).

Under the influence of high-frequency electromagnetic signals of the ultraviolet spectrum f _yfs , disinfection is carried out, mainly completely purified from TDVV and KCh, water. Wherein:

1. Qualitative - up to the requirements of SanPiN (2.1.4.1074-01 (Drinking water), water is purified and disinfected due to the fact that:

- water purification (from explosives, CNs, etc.) by: changing (deviations down and up) the trajectories of the explosives and CNs in the water flow in the region of the water intake head, particle coagulation at several stages (at several conventional acoustic boundaries), accelerated (due to the increase in mass due to acoustic coagulation) sedimentation of particles and compaction (due to acoustic exposure) of the sediment, disinfection of water (due to acoustic destruction of BB) is carried out at several stages (in the HMW - in the head of the water intake, in the PDMOV - in the water intake well, in VDMOV - in a mixer, in TDMOV - in several settling tanks, in ChDMOV - in several bulk filters, in ATP - in several transparent water ducts with ultraviolet lamps and directional hydroacoustic emitters UZDCH);

- carry out acoustic coagulation (due to acoustic waves), acoustic sorption coagulation (due to the physicochemical properties of mechanical and biological impurities located in the source water) and electrical (electromagnetic) coagulation (a concomitant effect of the work is the conversion of electrical energy into acoustic energy, electro-acoustic transducers of hydroacoustic emitters) BB, RF and BB;

- carry out acoustic and acoustic-gravity deposition of the original and previously acoustically coagulated explosives, cores and BB;

- carry out the delay (capture) of coagulated explosives, CFC and BB in the FMS bulk filters;

- regularly carry out sediment compaction;

- regularly (as necessary) carry out the removal of sediment, etc.

2. Physical (without the use of chemical reagents - during purification, without the use of chlorine - during disinfection) purification and disinfection of water is carried out due to the fact that:

- do not use chemicals (coagulants and flocculants) for water treatment;

- do not use chemicals (chlorine) to disinfect water;

- water purification is carried out at several stages (conditional acoustic boundary) due to: changes in the trajectories of the explosive and cn in the water flow in the area of the head of the intake, coagulation of explosives, cn and BB, sedimentation of particles and compaction of sediment;

- water disinfection is carried out at several stages (conditional acoustic boundary) due to the physical destruction of BB under the influence of nonlinear acoustic effects (acoustic cavitation, etc.);

- carry out the delay (capture) of coagulated (with explosives and CN) BB in the FMS bulk filters;

- regularly carry out compaction of sediment with BB;

- regularly carry out the removal of sediment from the BB, etc.

3. The cleaning and disinfection of large (up to 50 thousand m per day or more) volumes of water taken from surface water sources is carried out due to the fact that:

- carry out the purification and disinfection of water by changing the trajectories of the explosives, CFC and BB in the water flow in the area of the head of the water intake;

- purification and disinfection of water is carried out at several stages;

- several different physical mechanisms of coagulation of explosives are simultaneously implemented for water purification;

- simultaneously implement several different physical mechanisms for the deposition of the original and previously acoustically coagulated explosives, CN and BB;

- carry out the delay of explosives, CFC and BB in the FMS bulk filters;

- carry out regular compaction of sediment;

- carry out regular removal of sediment, etc.

4. The simplicity of the method is provided due to the fact that:

- the formation and emission of sonar waves of the ZDCh and UZDCH is carried out using commercially available electronic devices, as well as sonar emitters (including those removed from service, which contributes to the conversion of enterprises of the military-industrial complex);

- the formation and radiation of high-frequency electromagnetic waves (ultraviolet range) is carried out using commercially available electronic devices;

- the operation of the device that implements the developed method is controlled automatically and semi-automatically (without the constant presence of maintenance personnel);

- maintenance of equipment that implements the developed method is carried out with great discretion (once every 7 days or more) and directly during the operation of the treatment plant, therefore, no special time is required to stop the process of water treatment and maintenance of the device, etc.

5. The minimum financial costs are provided due to the fact that:

- exclude the consumption of expensive chemicals;

- eliminate the cost of expensive and dangerous during transportation and storage of disinfectants (chlorine);

- reduce (at least by 30%) the area of land allocated for the construction of treatment facilities;

- water purification is carried out in several stages;

- water treatment and disinfection begin directly in the river;

- the formation and emission of hydroacoustic waves ZDCH and UZDCH carried out using commercially available electronic and acoustic devices;

- the formation and emission of high-frequency waves is carried out using commercially available electronic devices;

- the power consumption of the acoustic devices of the device that implements the developed method is relatively small (less than 0.5 W / m ³ );

- the time for installation of all acoustic and electromagnetic equipment does not exceed 5 days;

- maintenance of equipment is carried out with great discretion and directly in the process of treatment plant, etc.

6. The minimum time costs provide due to the fact that:

- exclude the time spent on the preparation of solutions of chemical reagents;

- exclude the time spent on the preparation of solutions of disinfectants;

- water treatment and disinfection begin directly in the river;

- the time for installation of all acoustic and electromagnetic equipment does not exceed 5 days;

- maintenance of equipment is carried out with great discretion and directly in the process of treatment plant, etc.

7. The implementation of the method in any weather and climate conditions is ensured by the fact that:

- the formation and emission of sonar waves of the ZDCh and UZDCH is carried out using commercially available hydroacoustic emitters capable of working in any weather and climate conditions (including under ice);

- a device that implements the developed method is performed as separate modules, etc.

8. Medical safety for humans is ensured by the fact that:

- completely exclude the use of chemicals for water purification and for sediment compaction;

- completely exclude the use of chemical disinfectants hazardous during transportation and storage;

- Acoustically compacted sediment containing BB is disposed of;

- the formation and emission of high-frequency electromagnetic waves (ultraviolet range) is carried out using commercially available and sanitary certified devices;

- the operation of the device that implements the developed method is controlled automatically and semi-automatically (without the constant presence of maintenance personnel);

- parameters (frequency, amplitude, waveform) of hydroacoustic waves are medically safe for humans.

- parameters (frequency, amplitude, waveform) of high-frequency waves are medically safe for humans, etc.

9. Ecological safety for the environment is ensured by the fact that:

- completely exclude the use of chemicals for water purification and for sediment compaction;

- completely exclude the use of chemical disinfectants hazardous during transportation and storage;

- Acoustically compacted sediment containing BB is disposed of;

- parameters (frequency, amplitude, waveform) of hydroacoustic waves are medically safe for OPS;

- parameters (frequency, amplitude, waveform) of high-frequency waves are medically safe for OPS, etc.

Distinctive features of the proposed method are:

1. As the main module for water purification, a water intake tip is used, in which they carry out: significant purification from KDVV, insignificant purification from ADV, insignificant purification from TDVV, minimal purification from FC and insignificant purification from BB.

2. As the first additional module for water purification, a water intake well is used, in which they carry out: significant cleaning from KDVV, significant cleaning from ADVV, minor cleaning from TDVV, insignificant cleaning from KP and insignificant cleaning from BB.

3. As a second additional module for water purification, a mixer is used, in which they carry out: complete purification from KDVV, almost complete purification from ADV, substantial purification from TDVV, significant purification of water from KP, and significant purification from BB.

4. As the third additional module for water purification, several - at least two, identical sumps are used.

5. As the fourth additional module for water purification, several - at least two, identical bulk filters (filters with a layer of granular filter material) are used.

6. As a special construction, several - at least two, identical to each other, transparent (for ultraviolet irradiation) conduits with several - at least four, identical to each other with ultraviolet lamps and with several - at least four, identical to each other sonar emitters are used as a special structure .

7. Additionally - for faster and better washing of the ZFM bulk filters, use the BHAV ZDCH and UZDCH, which are non-directionally (in all directions) emitted by a sonar emitter buried in the ZFM in the geometric center of the corresponding bulk filter.

The presence of distinctive features from the prototype features allows us to conclude that the proposed method meets the criterion of "novelty."

An analysis of the known technical solutions in order to detect the indicated distinctive features in them showed the following.

Symptoms: 1, 2 and 3 are new and their use for non-reagent treatment and disinfection of water is unknown.

Symptoms: 6 and 7 are new and their use for non-reagent cleaning and disinfection of water is unknown.

At the same time, it is known: for feature 6, the use of ultraviolet radiation to disinfect water; for trait 7, the use of acoustic waves to disintegrate materials.

Symptoms: 4 and 5 are well known.

Thus, the presence of new significant features, together with the known ones, ensures that the proposed solution has a new property that does not coincide with the properties of the known technical solutions - qualitatively - up to the requirements of SanPiN (2.1.4.1074-01 (Drinking water), physically - without using chemical reagents) to clean, as well as qualitatively and physically - without the use of chemicals, to disinfect large (up to 50 thousand m ³ per day or more) volumes of water taken from surface water sources (rivers, etc.), relative about a simple way with minimal financial and time costs, in any weather and climate conditions, ensuring medical safety for humans and environmental safety for OPS.

In this case, we have a new set of features and their new relationship, moreover, it’s not a simple combination of new features and already known ones, but the execution of operations in the proposed sequence leads to a qualitatively new effect. This circumstance allows us to conclude that the developed method meets the criterion of "significant differences".

An example implementation of the method.

Industrial tests of the developed method were carried out at water treatment enterprises: from 2004 to 2006 in Seoul and Busan (Republic of Korea), from 2007 to 2009 in the province of Borea-Vung-a (Republic of Vietnam), from 2016 to 2018 (Astrakhan, Arkhangelsk and Rostov regions of the Russian Federation).

In FIG. 7 - FIG. 11 illustrates the test results of the developed method of reagent-free cleaning and disinfection of water.

In this case: Fig. 7 shows the results of non-reagent water purification from explosives for the developed method (histograms with solid lines) and for the prototype method (histograms with dashed lines). In this case, by indices: I, II, II, IV and V in FIG. 7 is indicated: average content (SS) of explosives (mg / l) in water at the exits from: GMO, PDMOV, VDMOV, TDMOV, ChDMOV and ATP.

As can be seen from FIG. 7 in the process of implementing the prototype method, the content of CERV (mg / l) in the KOV was successively reduced from 1063 mg / l to: 610 mg / l, 210 mg / l, 112 mg / l, 98 mg / l and 37 mg / l (purification efficiency 96.5%). While in the process of implementing the developed method (Fig. 7), the content of explosives (SS, mg / L) in the OWL was successively reduced from 1063 mg / L to: 370 mg / L, 117 mg / L, 68 mg / L, 25 mg / L and 8.7 mg / L (99.2% purification efficiency).

That is, the effect of the developed method amounted to 28.3 mg / l (37 mg / l - 8.7 mg / l), or 2.7% (99.2% - 96.5%), and the quality of the DOC fully met the requirements (9.0 mg / l) MPC of _{fish farm.}

In FIG. 8 and in FIG. 9 presents the results of non-reagent (hydroacoustic) purification of KOV from HM — on the example of iron, (initial iron content in KOV - 4.8 mg / l) for the prototype method (Fig. 8) and for the developed method (Fig. 9), respectively .

Moreover, in FIG. 8 and in FIG. 9, the index I denotes the initial content of HM (SS, mg / l) in the KOV at the entrance to the GOT; index II denotes the content of HM in the HLW at the exit of the VDO, index III denotes the content of HM in the HLW at the exit of the PTO.

As can be seen from FIG. 8, in the process of implementing the prototype method, the content of HM (iron) in KOV was successively reduced from 4.8 mg / L to: 0.6 mg / L and to 0.1 mg / L (purification efficiency 97.0%).

While in the process of implementing the developed method (Fig. 9) the content of HM (iron) in KOV was successively reduced from 4.8 mg / L to: 0.1 mg / L and to 0.05 mg / L (efficiency purification 98.9%).

That is, the effect of the developed method was 0.05 mg / L (0.1 mg / L - 0.05 mg / L), or 1.9% (98.9% -97.0%), and the quality of the KOV is completely _{Meets the} requirements (0.05 mg / l) of the MPC for _fish

In FIG. 10 shows the results of non-reagent (hydroacoustic) cleaning of CWB from BB (quality index of OKB CFU in 100 ml) for the prototype method (bar chart with index I) and for the developed method (bar chart with index II) in GOT.

As can be seen from FIG. 10, the quality index of OKB CFU in 100 ml for the prototype method (histogram with index I) was 12.0, while for the developed method (histogram with index II) it was 0.0 (the effect of the developed method is 12.0, or one hundred%).

In FIG. 11 shows the results of non-reagent (hydroacoustic) cleaning of COV from BB (quality index of OMCU CFU in 1 ml) for the prototype method (histogram with index I) and for the developed method (histogram with index II) in GOT.

As can be seen from FIG. 11, the quality index of OMC CFU in 1 ml for the prototype method (histogram with index I) was 73.0, while for the developed method (histogram with index II) it was 44.0 (the effect of the developed method is 29.0, or 39.7%).

In this way:

1. Qualitative - up to the requirements of SanPiN (2.1.4.1074-01 (Drinking water), water was purified and disinfected due to the fact that:

- purification and disinfection of water was carried out at several stages;

- coagulation of explosives, CN and BB was carried out in several ways;

- deposition of the original and acoustically coagulated explosives, cores and BBs was carried out in various ways;

- carried out the delay (capture) of coagulated explosives, CFC and BB in the FMS bulk filters;

- regular compaction of sediment;

- regular removal of sediment, etc.

2. Physical purification and disinfection of water was carried out due to the fact that:

- did not use chemicals and chemicals (chlorine);

- water purification was carried out at several stages (conditional acoustic boundaries) and due to: changes in the trajectories of the explosive and cn in the water flow in the area of the head of the water intake; coagulation of explosives, CN and BB; deposition of source and acoustically coagulated particles; sediment compaction;

- water disinfection was carried out at several stages due to physical destruction of BB under the influence of nonlinear acoustic effects;

- carried out the delay (capture) coagulated (with explosives and CN) BB in the FMS bulk filters;

- regular compaction of sediment with BB;

- regularly removed the sediment from the BB, etc.

3. Cleaning and disinfection of large (up to 50 thousand m per day or more) volumes of water was carried out due to the fact that:

- carried out the purification and disinfection of water by changing the trajectories of the explosives, CFC and BB in the water flow in the area of the head of the water intake;

- purification and disinfection of water was carried out at several stages;

- several different physical mechanisms of coagulation of explosives were simultaneously implemented for water purification;

- simultaneously implemented several different physical mechanisms for the deposition of the original and previously acoustically coagulated explosives, cores and BB;

- carried out the delay of explosives, cf and BB in the FMS bulk filters;

- carried out regular compaction of sediment;

- carried out regular removal of sediment, etc.

4. The simplicity of the method was provided due to the fact that:

- the formation and emission of sonar waves of the ZDCh and UZDCH were carried out using commercially available electronic devices, as well as sonar emitters;

- the formation and radiation of high-frequency electromagnetic waves was carried out using commercially available electronic devices;

- equipment maintenance was carried out with great discretion and directly during the operation of the treatment plant;

- control of the operation of the device was carried out automatically and semi-automatically, etc.

5. The minimum financial costs provided due to the fact that:

- excluded the consumption of expensive chemicals;

- excluded the cost of expensive and dangerous during transportation and storage of disinfectants (chlorine);

- reduced (at least 30%) the land area allocated for the construction of treatment facilities;

- water purification was carried out in several stages;

- water purification and disinfection started directly in the river;

- the formation and emission of hydroacoustic waves was carried out using commercially available electronic and acoustic devices;

- the formation and emission of high-frequency waves was carried out using commercially available electronic devices;

- the power consumption of the acoustic devices of the device was relatively small (less than 0.5 W / m);

- the time for installation of all acoustic and electromagnetic equipment did not exceed 5 days;

- equipment maintenance was carried out with great discretion and directly during the operation of the treatment plant, etc.

6. The minimum time costs provided due to the fact that:

- excluded the time spent on the preparation of solutions of chemical reagents and disinfectants;

- water purification and disinfection started directly in the river;

- the time for installation of all acoustic and electromagnetic equipment did not exceed 5 days;

- equipment maintenance was carried out with great discretion and directly during the operation of the treatment plant, etc.

7. The implementation of the method in any weather and climate conditions was ensured due to the fact that:

- the formation and emission of sonar waves of the ZDCh and UZDCH was carried out using commercially available hydroacoustic emitters capable of operating in any weather and climate conditions;

- a device that implements the developed method was performed in the form of separate modules, etc.

8. Medical safety for humans was ensured by the fact that:

- completely eliminated the use of chemicals for water purification and for sediment compaction;

- completely excluded the use of hazardous chemical disinfectants during transportation and storage;

- acoustically compacted sediment containing BB was disposed of;

- the formation and emission of hydroacoustic waves was carried out using commercially available and sanitary certified devices;

- the formation and emission of high-frequency electromagnetic waves was carried out using commercially available and sanitary certified devices;

- device operation was controlled automatically and semi-automatically (without the constant presence of maintenance personnel);

- parameters (frequency, amplitude, waveform) of hydroacoustic waves were medically safe for humans.

- parameters (frequency, amplitude, waveform) of high-frequency waves were medically safe for humans, etc.

9. Ecological safety for the environment was ensured due to the fact that:

- completely eliminated the use of chemicals for water purification and for sediment compaction;

- completely excluded the use of hazardous chemical disinfectants during transportation and storage;

- acoustically compacted sediment containing BB was disposed of;

- parameters (frequency, amplitude, waveform) of hydroacoustic waves were medically safe for OPS;

- parameters (frequency, amplitude, waveform) of high-frequency waves were medically safe for OPS, etc.

Claims (1)

The method of non-reagent purification and disinfection of water, which consists in cleaning from coarse, medium and finely divided suspended solids by emitting traveling hydroacoustic waves of sound and ultrasonic frequency ranges in the main water treatment module, in cleaning from coarse, medium and fine suspended particulate matter and bacteria by emitting traveling sonar waves of sound and ultrasonic frequency ranges in the first additional module, in purification of medium-sized and finely divided suspended solids, colloidal particles and pathogenic bacteria by radiation of traveling hydro-acoustic waves of sound and ultrasonic frequency ranges in the second additional module, cleaning of fine-dispersed suspended matter, colloidal particles and pathogenic bacteria by radiation of traveling hydro-acoustic waves of sound and ultrasonic frequency ranges in the third additional module, in the cleaning of colloidal particles and pathogenic bacteria in a special facility in gravitational deposition in the main module, the first additional module, the second additional module and the third additional module, as well as in the special construction of previously acoustically coagulated coarse, medium, fine suspended solids and colloidal particles, in the acoustic compaction of sediment, in irradiation of disinfected water ultraviolet light, characterized in that in the main module of water purification, which is used as the tip of the water intake, carry out a significant, more than 50%, purification from coarse suspended solids, insignificant, less than 50%, purification from coarse suspended solids, insignificant, less than 25%, purification from fine suspended solids, minimal, less than 5%, purification from colloidal particles and insignificant purification from pathogenic bacteria by upward directed and flow down towards the water surface in a natural radiation watercourse sonar traveling sound waves and the ultrasonic frequency ranges from the acoustic pressure amplitude of at least 10 ⁴ Pa H a distance of 1 m from the surface of the corresponding sonar emitter, in the first additional module of water purification, which is used as a water intake well, a substantial, more than 75%, purification of coarse suspended solids is carried out, significant purification of medium-dispersed suspended solids, minor purification of fine suspended solids, insignificant cleaning of colloidal particles and insignificant cleaning of pathogenic bacteria by directed into a gravity pipe, as well as non-direct of radiation of traveling hydroacoustic waves of sound and ultrasonic frequency ranges with an amplitude of acoustic pressure of at least 10 ⁴ Pa at a distance of 1 m from the surface of the corresponding hydroacoustic emitter at the middle horizon of the water receiving well, in the second additional water treatment module, which is used as a mixer, they are completely cleaned from coarse suspended solids, almost complete purification from medium-dispersed suspended solids, substantial purification from finely divided x suspended solids, significant purification from colloidal particles and significant purification from pathogenic bacteria by means of radiation of traveling hydro-acoustic waves of sound and ultrasonic frequency ranges with an amplitude of acoustic pressure of at least 10 ⁴ Pa at a distance of 1 m from the surface of the corresponding hydro-acoustic emitter, not directed in the middle horizon of the mixer, the third additional water treatment module, which is used as a few - at least two identical sumps, thorough cleaning of medium size of suspended solids, virtually complete cleaning of fine suspended solids and a substantial purification of water from the colloidal particles and precipitate seal by non-directional on average horizon corresponding settler radiation traveling hydroacoustic waves of sonic and ultrasonic frequency ranges from the acoustic pressure amplitude at least February ¹⁰ Pa at a distance of 1 m from the surface of the corresponding sonar emitter, in the fourth additional module, as They use at least two bulk filters that are identical to each other, completely clean from fine suspended solids, and also almost completely clean from colloidal particles by radiation of traveling sonar waves of sound and ultrasonic frequency ranges with an acoustic pressure amplitude not less than directed at the upper horizon of the corresponding bulk filter 10 ² Pa at a distance of 1 m from the surface of the corresponding sonar emitter, as well as by holding acoustically to fine-particulate suspended particles and colloidal particles in a granular filter material in a special structure, which use at least two identical to each other transparent for ultraviolet irradiation conduits using at least four identical ultraviolet lamps and using at least four identical sonar acoustics emitters of the ultrasonic frequency range, they completely purify water from pathogenic bacteria by radiation of ultraviolet light, as well as by directional radiation of traveling hydroacoustic waves of the ultrasonic frequency range with an amplitude of acoustic pressure of at least 10 ⁵ Pa at a distance of 1 m from the surface of the corresponding hydroacoustic emitter, traveling hydroacoustic waves of sound and ultrasonic frequency ranges with an amplitude of acoustic pressure of at least 10 ⁴ Pa at a distance of 1 m from the surface of the corresponding sonar emitter buried in a granular filter th material in the geometric center of the corresponding bulk filter.

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