RU2768873C1 - Method for reagentless treatment of mine water - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention relates to a method for reagentless treatment of mine water, which consists in hydroacoustic action on the treated mine water and on the compacted sediment by alternating: pulsed - with duration of less than 1 s, quasi-pulse - with duration from 1 s to 10 s and continuous - with duration of more than 10 s, waves of sound and ultrasonic frequency ranges in series-functionally connected: in the first, in the second, in the third, in the fourth and in the fifth, elements of the mine water treatment system, in acoustic coagulation of colloidal particles, suspended substances and heavy metals, in gravitational and gravitational-acoustic sedimentation on the bottom of previously acoustically coagulated colloidal particles, suspended substances and heavy metals, in acoustic compaction of sediment with its subsequent periodic extraction and disposal at the solid waste storage landfill, wherein the sound pressure amplitude of the sound and ultrasonic frequency ranges is not less than 10⁴ Pa at distance of 1 m from the corresponding hydroacoustic radiator, first element used is identical to each other section water collectors located on sections of mine, as the second element, identical to each other main water collectors are used, located in the near-shaft yard of the mine, as the third element, identical to each other settling ponds are used, as the fourth element, identical to each other filter chambers are used, as the fifth element, identical filters are used, additionally performing electrochemical coagulation of colloidal particles, suspended substances, heavy metals and disease-causing bacteria in the near field of hydroacoustic emitters in the process of converting electrical energy into acoustic energy, additionally, deposition of previously coagulated colloidal particles, suspended substances, heavy metals and pathogenic bacteria is carried out under the action of acoustic waves of sound and ultrasonic frequency ranges with sound pressure amplitude of 1 Pa at distance of 1 m from the corresponding acoustic radiator, directed from the air under the water at angle of 25 degrees, further cleaning from the pathogenic bacteria in the near field of the hydroacoustic radiators is carried out with the emission of acoustic waves with a sound pressure amplitude of 10⁴ Pa, additionally, in the fifth element, previously coagulated colloidal particles, suspended substances, heavy metals and pathogenic bacteria are extracted on filters.

EFFECT: disclosed is a method for reagentless treatment of mine water.

1 cl, 10 dwg, 1 ex

Description

The invention relates to the field of physics and can be used for: reagent-free purification of mine water (NTV) from: colloidal particles (CP) - size class "-0.5 microns", from suspended solids (SS) - size class "+0.5 microns", from heavy metal (HM), from pathogenic bacteria (BB); non-reagent disinfection - in the interests of ensuring environmental protection (OPS); reagent-free purification of circulating water from explosives - in the interests of ensuring high profitability of production; for reagentless purification of natural water from CN, BB, HM and BB - in the interests of preparing drinking water, and, as a result, ensuring health and high-quality (active) longevity; for sealing the bodies of water-resistant dams and reducing the parasitic filtration of water through them - in the interests of the safety of the operation of a hydraulic structure. Spp. 10 Fig.

A known method of non-reagent cleaning of mine (quarry, waste, etc.) waters (SHB) of mining enterprises, which consists in: insignificant - less than 10%, cleaning from fine explosives (TDVV) - size class "0.5-5 microns", significant - more than 50%, purification from medium dispersed explosives (SDVV) - size class "5-50 microns", almost complete - more than 90%, purification from coarse explosives (KDVV) - size class "50-500 microns" and complete - 100% , cleaning from super-coarse explosives (SKDVV) - size class "+500 microns" - in the main sedimentation tank; in significant purification from TDVV, almost complete purification from SDVV and complete purification from KDVV - in the first additional settler; almost complete purification from TDVV and complete purification from SDVV - in the second additional sump; in complete purification from TDVV and minor purification from HF - in a special facility, which is used as an acoustic filter /Acoustic technology in mineral processing //ed. B.C. Yamshchikov. - M.: Nauka, 1987, p. 225-228/.

The main disadvantages of this method are:

1. Low cleaning performance of SHB, due to the limited area of the filtering baffle of the acoustic filter.

2. High cost of purification of a unit volume of SHV.

3. The impossibility of sludge thickening in settling tanks, and, as a result, the impossibility of increasing the useful volumes of water in them.

4. Insufficient quality of cleaning of CM from CC.

5. The impossibility of using for cleaning SHV from HM.

5. The impossibility of using for cleaning ShV from BB, etc.

There is a known method of non-reagent purification of mine (quarry, circulating, etc.) waters, which consists in complete purification from SKDVV, almost complete purification from KDVV, significant purification from ADVV and insignificant purification from TDVV - by periodic - with alternating radiation and pause modes, as well as sequential in frequency, the formation in the main sedimentation tank of traveling hydroacoustic waves (BGAW) of the sound frequency range (ZDCH) - in the frequency range from 16 Hz to 16 kHz, and the ultrasonic frequency range (UZDCH) - in the frequency range above 16 kHz with a sound pressure amplitude of at least 10 Pa at a distance of 1 m from the corresponding emitter; in complete purification from KDVV, almost complete purification from SDVV and significant purification from TDVV in the first additional settling tank - by periodic and sequential formation of BGAV ZDCH and UZDCH frequencies; in complete purification from SDVV, almost complete purification from TDVV, insignificant purification from HF, HM and BB in the second additional settling tank - by periodic and sequential formation of intense standing hydroacoustic waves (SIAW) of SDCH and UZDCH frequencies with a sound pressure amplitude of at least 10 ² Pa at a distance of 1 m from the corresponding emitter; in complete purification from HF, almost complete purification from HF, HM and BB in the third additional settling tank - by periodically and sequentially generating intense SGAW SP and SPL frequencies, as well as additional purification from HF, HM and BB by filtering water through filter shafts (dams ), and passing through systems of natural aeration of water with oxygen, located between all sedimentation tanks; in complete purification from CN, HM and BB in a special facility - an acoustic hydrocyclone (AHC) - by mixing and degassing it at an excess static pressure of 3-5 atm., As well as by intense irradiation - with an amplitude of sound pressure of at least 10 ⁵ Pa at a distance of 1 m from the corresponding emitter, SGAW UZDCH at a frequency close to the resonant frequency of gas bubbles / 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 are:

1. Low productivity (for purified water and compacted sludge) due to the limited volume of the AGC working chamber.

2. The high cost of units: the volume of purified water (from CC, BB, HM and BB) and the volume of compacted (condensed) sludge.

3. Insufficiently rational use of the useful volume of the main and additional sedimentation tanks.

4. The impossibility of sludge thickening in settling tanks, and, as a result, increasing the useful volumes of water in them, etc.

Closest to the claimed method is the method of non-reagent cleaning of SHV (quarry waters), selected as the prototype method, which consists in hydroacoustic (under water) impact on the cleaned (from HF, BB, TM, BB) SHV and on the compacted (thickened) sediment by alternating among themselves: pulsed - with a duration of less than 1 s, quasi-pulsed - with a duration of 1 s to 10 s and continuous - with a duration of more than 10 s, signals of the ZDCH and UZDCH frequencies with a sound pressure amplitude of at least 10 ² Pa at a distance of 1 m from the corresponding hydroacoustic emitter: in the first element (repartition) of the water treatment facility (SVO) - in the first sump with at least two drainage ditches functionally connected to it; in the second element of the SVO - in the second sump with sump pumps; in the third element of the SVO - in the sump of coarse water treatment; in the fourth element of the WSS - in the sump of fine water purification and in the fifth element of the WSS - in the fields of surface filtration; in the purification of CM from CN, EM and HM - by their acoustic (reagentless) coagulation and due to the sorption properties of EM (in relation to purification from HM), acoustic (in addition to gravity) deposition of the original and previously acoustically coagulated CM and EM, as well as acoustic compaction (thickening) of the sludge with its subsequent (sludge) disposal at the solid waste storage site / Bakharev S.A. The method of non-reagent purification of quarry waters. - RF patent No. 2560771, publ. August 20, 2015, Bull. No. 23/.

The disadvantages of the prototype method include:

1. The impossibility of cleaning the SH from the BB (the impossibility of disinfecting the SH) - due to the use of ZDCH and UZDCH frequencies with a sound pressure amplitude of only 10 ² Pa at a distance of 1 m from the corresponding hydroacoustic emitter

2. Low efficiency of the fourth additional water treatment facility - due to the use of only gravitational settling (under the action of gravity) of explosives for cleaning the SH.

3. Insufficient efficiency of operation of the main and first additional water treatment facilities - due to the use of only acoustic coagulation and gravitational settling (under the action of gravity) of explosives for cleaning the SH.

4. Insufficient quality of NTV cleaning from HF and HM - due to the use of only hydroacoustic effects (under water) and gravity (gravity).

5. Insufficient quality of cleaning of the CW in the presence of ice on the water surface in the third and fourth additional water treatment facilities.

6. High cost of purifying ball screws from CN, HM and salts, etc.

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

The technical result of the proposed method consists in effective (up to the level of requirements of environmental legislation), reagent-free (without the use of chemical reagents) purification of large volumes of CW (CW consumption of at least 2000 m ³ /h) from CN, HE, HM and BB, in a relatively simple way, with minimal financial and time costs and expansion of the scope (work during the freeze-up period at surface water treatment facilities), ensuring medical safety for humans and environmental safety for the environmental protection system, in general.

This goal is achieved by the fact that in the known method of reagentless cleaning of the screw, which consists in a hydroacoustic (under water) effect on the cleaned screw and on the compacted (thickened) sediment, alternating with each other: pulse - with a duration of less than 1 s, quasi-pulse - with a duration of from 1 to 10 with and continuous - with a duration of more than 10 s, waves of ZDCH and UZDCH frequencies in series functionally connected: the first, second, third, fourth and fifth elements (repartitions) of the SVO SHV; in acoustic coagulation of CPs, explosives (due to an increase in the number of collisions between them and the mechanical attachment of more mobile CPs to less mobile explosives under the influence of acoustic waves) and TM (due to the sorption properties of explosives), in gravitational (under the action of gravity) and gravitational-acoustic ( under the action of gravity and a hydroacoustic wave propagating under water from top to bottom) settling on the bottom of previously acoustically coagulated HF, HE and HM; in the acoustic compaction (thickening) of the sludge, followed by its (sludge) extraction and disposal at the solid waste storage site, while the amplitude of the sound pressure of the waves ZDCH and UZDCH is at least 10 ⁴ Pa at a distance of 1 m from the corresponding hydroacoustic emitter, as the first element, identical to each other local water collectors located in the sections of the mine are used; filter chambers, identical filters with sorbents are used as the fifth element, they additionally carry out electrochemical coagulation of HF, BB, TM and BB in the near field of hydroacoustic emitters in the process of converting electrical energy into acoustic energy - a side effect, additional but they carry out the deposition of previously coagulated HF, BB, TM and BB - under the action of acoustic waves ZDCH and UZDCH with a sound pressure amplitude of at least 1 Pa at a distance of 1 m from the corresponding acoustic (surface) emitter, directed from air to water at an angle of not more than 30 degrees, additionally carry out cleaning from BB (disinfection of SHV) in the near field of hydroacoustic emitters - due to the bactericidal effect on the microflora of hydrogen peroxide and OH ° radicals, which form under water during the emission of acoustic waves with an amplitude of sound pressure of at least 10 ⁴ Pa; additionally, in the fifth element, extraction of previously coagulated (acoustically and electrochemically) CF, BB, TM and BB filters on sorbents is carried out.

Figure 1 - figure 5 shows the structural diagrams of the device that implements the developed method of non-reagent cleaning (from CC, explosives, TM and BB) SHV. At the same time: figure 1 illustrates a block diagram of the device in relation to the general principle of the implementation of the developed method of non-reagent cleaning of SHV; figure 2 illustrates a block diagram of the device in relation to the first element (repartition) of the water treatment system (SVO) SHV and the first complex of acoustic effects (CAV); figure 3 illustrates the block diagram of the device in relation to the second element of the CBO SHV and to the second KAV; figure 4 illustrates a block diagram of the device in relation to the third element of the CBO SHV and the third CAV; figure 5 illustrates a block diagram of the device in relation to the fourth element of the CBO SHV and the fourth CAV.

The device for non-reagent cleaning of SHV (for example, in the process of mining ore gold in the Kamchatka Territory of the Russian Federation) in the simplest case contains (figure 1): CBO (1) consisting of: several - at least two, identical to each other in their purpose of the first elements (2 ) SVO (1) ShV - district water collectors located in the mine areas; several - at least two, identical to each other in their purpose of the second elements (3) SVO (1) ShV - main water collectors located in the near-shaft yard of the mine; several - at least two third elements identical to each other in their purpose (4) SVO (1) SV - settling ponds located on the earth's surface, several - at least two fourth elements identical to each other in their purpose (5) SVO (1) ShV - working chambers, several - at least two fifth elements identical to each other in their purpose (6) SVO (1) ShV - sorbent filters. At the same time: each of the first elements (2) SVO (1) SV in the simplest case contains functionally connected: several - at least two drainage ditches (7) identical to each other in their purpose and a local water collector (8) located in the corresponding section mine, the output of which is connected, by means of the corresponding local pipeline (9) with the input of the corresponding second element (3) CBO (1) SHV; each of the second elements (3) SVO (1) SV in the simplest case contains functionally connected: several - at least two, mine workings (10), a pumping chamber (11), a water pump (12), the output of which, through the corresponding main pipeline (13), connected to the input of the corresponding third element (4) CBO (1) SHV; each of the third elements (4) SVO (1) SV in the simplest case contains the first receiving chamber (14) and the first clarification chamber (15) functionally connected in series, the outlet of the latter, through the corresponding first conduit (16), is connected to the input of the corresponding fourth element (5) SVO (1) SV; each of the fourth elements (5) SVO (1) SV in the simplest case contains a second receiving chamber (17) and a second clarification chamber (18) functionally connected in series, the output of the latter is contact connected to the input of the corresponding fifth element (6) SVO (1) SV ; each of the fifth elements (6) SVO (1) SV in the simplest case contains in series functionally connected: a filter element (19) and a sorbing element (20), the outlet of the latter, through the corresponding drainage pipeline (21), is connected to a natural watercourse - to a stream .

SVO (1) also contains several - in terms of the number of first elements (2), identical to each other in their purpose of the first complexes of acoustic (PCAV) impact (22) on the SH; several - according to the number of second elements (3), identical to each other in their purpose of the second complexes of acoustic (VKAV) impact (23) on the SH; several - according to the number of third elements (4), identical to each other in their purpose of the third complexes of acoustic (TKAV) impact (24) on the SH; several - according to the number of fourth elements (5), identical to each other in their purpose of the fourth complexes of acoustic (CHKAV) impact (25) on the SH.

At the same time, each PCAV (22), in the simplest case, contains: the first channel of hydroacoustic (PCHAK) coagulation (26) HF, BB, TM and BB containing functionally connected in series: the first removable digital carrier (PSTSNS) of signals (27) at a frequency of F ¹ _HAK - the first flash drive; multi-channel - at least 2 channels, the first signal amplification unit (MPBUS) (28) - a multi-channel digital power amplifier, at a frequency of F ¹ _SAC and multi-channel - at least 2 channels, the first emission unit (MPBIS) of signals (29) at frequency F ¹ _HAK - a group of non-directional, placed under water at different horizons, hydroacoustic emitters ZDCH and UZDCH; the first channel of gravitational-hydroacoustic (PKGGO) deposition (30) HF, BB, TM and BB containing functionally connected in series: the second removable digital carrier (VSCNS) of signals (31) at a frequency of F ¹ _GGO - the second flash drive, multi-channel - at least 2- x channels, the second amplification unit (MVBUS) of signals (32) is a multi-channel digital power amplifier, at a frequency of F ¹ _GGO and multi-channel - at least 2 channels, the second signal emission unit (MVBIS) at a frequency of F ¹ _GGO - a group of directional and oriented heed, placed under water on the same horizon in the upper layer of water, hydroacoustic emitters ZDCH and UZDCH; the first channel of gravitational-acoustic (PKGAO) deposition (34) HF, BB, TM and BB containing functionally connected in series: the third removable digital carrier (TSTSNS) signals (35) at a frequency of F ¹ _GAO - the third flash drive; multi-channel - at least 2 channels, the third amplification unit (MTBUS) of signals (36) - a multi-channel digital power amplifier, at a frequency of F ¹ _GAO and multi-channel - at least 2 channels, the third emission unit (MTBI) of signals (37) at frequency F ¹ _GAO - a group of acoustic emitters ZDCH and UZDCH directed and oriented downwards at an angle of no more than 30 degrees, placed above the water.

At the same time, each VKAV (23), in the simplest case, contains: the second channel of hydroacoustic (VKHAK) coagulation (38) HF, BB, TM and BB containing functionally connected in series: the fourth removable digital carrier (RSTSNS) of signals (39) at a frequency of F ² _HAK - the fourth flash drive; multi-channel - at least 2 channels, the fourth amplification unit (MCHBUS) of signals (40) - a multi-channel digital power amplifier, at a frequency of F ² _SAC and multi-channel - at least 2 channels, the fourth emission unit (MCHBIS) of signals (41) at a frequency of F ² _HAK - a group of non-directional, placed under water at different horizons, hydroacoustic emitters ZDCH and UZDCH; the second channel of gravitational-hydroacoustic (VKGGO) deposition (42) HF, BB, TM and BB containing functionally connected in series: the fifth removable digital carrier (PTSCNS) of signals (43) at a frequency of F ² _GGO - the fifth flash drive; multi-channel - at least 2 channels, the fifth amplification unit (MPTBUS) of signals (44) - a multi-channel digital power amplifier, at a frequency of F ² _GGO and multi-channel - at least 2 channels, the fifth emission unit (MPBIS) of signals (45) at frequency F ² _GGO - a group of directed and oriented heed, placed under water on the same horizon in the upper layer of water, hydroacoustic emitters ZDCH and UZDCH; the second channel of gravitational-acoustic (VKGAO) deposition (46) HF, BB, TM and BB containing functionally connected in series: the sixth removable digital carrier (SHSTSNS) of signals (47) at a frequency of F ² _GAO - the sixth flash drive; multi-channel - at least 2 channels, the sixth amplification unit (MSBIS) of signals (48) - a multi-channel digital power amplifier, at a frequency of F ² _GAO and multi-channel - at least 2 channels, the sixth block of radiation (MSBIS) of signals (49) at frequency F ² _GAO - a group of acoustic emitters ZDCH and UZDCH directed and oriented downwards at an angle of no more than 30 degrees, placed above the water.

At the same time, each TKAV (24), in the simplest case, contains: the third channel of hydroacoustic (TKHAK) coagulation (50) HF, BB, TM and BB containing functionally connected in series: the seventh removable digital carrier (SSTSNS) of signals (51) at a frequency of F ³ _GAK - the seventh flash drive; multi-channel - at least 2 channels, the seventh amplification unit (MSBUS) of signals (52) - a multi-channel digital power amplifier, at a frequency of F ³ _SAC and multi-channel - at least 2 channels, the seventh emission unit (MTBI) of signals (53) at frequency F ³ _HAK - a group of non-directional, placed under water at different horizons, hydroacoustic emitters ZDCH and UZDCH; the third channel of gravitational-hydroacoustic (TKGGO) deposition (54) HF, BB, TM and BB containing functionally connected in series: the eighth removable digital carrier (VOSCNS) of signals (55) at a frequency of F ³ _GGO - the eighth flash drive; multi-channel - at least 2 channels, the eighth block of amplification (MVOBUS) of signals (56) - a multi-channel digital power amplifier, at a frequency of F ³ _GGO and multi-channel - at least 2 channels, the eighth block of radiation (MVOBIS) of signals (57) at frequency F ³ _MGO - a group of directed and downward-oriented, placed under water on the same horizon in the upper layer of water, hydroacoustic emitters ZDCH and UZDCH; the third channel of gravitational-acoustic (TKGAO) deposition (58) HF, BB, TM and BB containing functionally connected in series: the ninth removable digital carrier (DSTSNS) of signals (59) at a frequency of F ³ _GAO - the ninth flash drive; multichannel - at least 2 channels, the ninth amplification unit (MDBUS) of signals (60) - a multichannel digital power amplifier, at a frequency of F ³ _GAO and multichannel - at least 2 channels, the ninth emission unit (MDBIS) of signals (61) at a frequency F ³ _GAO - a group of acoustic emitters ZDCH and UZDCH directed and oriented downwards at an angle of no more than 30 degrees, placed above the water; the first channel of hydroacoustic thickening (PKGSO) of the sediment (62) containing in series functionally connected: the tenth removable digital carrier (DESDNS) of signals (63) at a frequency of F ¹ _GSO - the tenth flash drive; multi-channel - at least 2 channels, the tenth signal amplification block (MDEBUS) (64) - a multi-channel digital power amplifier, at a frequency of F ¹ _GSO and multi-channel - at least 2 channels, the tenth emission block (MDEBIS) of signals (65) at a frequency of F ¹ _GSO , placed in a sealed and sound-transparent container (66), completely filled with clean water - a group of non-directional, placed in the bottom layer of water at different horizons, hydroacoustic emitters ZDCH, placed in sealed and sound-transparent containers, completely filled with clean water.

Moreover, each CHKAV (25), in the simplest case, contains: the fourth channel of hydroacoustic (CHKGAK) coagulation (67) HF, BB, TM and BB containing functionally connected in series: the eleventh removable digital carrier (OSSNS) of signals (68) at a frequency of F ⁴ _HAK - the eleventh flash drive; multi-channel - at least 2 channels, the eleventh block of amplification (MOBUS) of signals (69) - a multi-channel digital power amplifier, at a frequency of F ⁴ _GAK and multi-channel - at least 2 channels, the eleventh block of radiation (MOBIS) of signals (70) at a frequency of F ⁴ _HAK - a group of non-directional, placed under water at different horizons, hydroacoustic emitters ZDCH and UZDCH; the fourth channel of gravitational-hydroacoustic (ChKGGO) deposition (71) HF, BB, TM and BB containing functionally connected in series: the twelfth removable digital carrier (DVTSNS) of signals (72) at a frequency of F ⁴ _GGO - the twelfth flash drive; multi-channel - at least 2 channels, the twelfth amplification unit (MDVBUS) of signals (73) - a multi-channel digital power amplifier, at a frequency of F ⁴ _GGO and multi-channel - at least 2 channels, the twelfth emission unit (MDVBIS) of signals (74) at frequency F ⁴ _GGO - a group of directed and downward-oriented, placed under water on the same horizon in the upper layer of water, hydroacoustic emitters ZDCH and UZDCH; the fourth channel of gravitational-acoustic (ChKGAO) deposition (75) HF, BB, TM and BB containing functionally connected in series: the thirteenth removable digital carrier (TRSCNS) of signals (76) at a frequency of F ⁴ _GAO - the thirteenth flash drive; multi-channel - at least 2 channels, the thirteenth amplification unit (MTRBUS) of signals (77) - a multi-channel digital power amplifier, at a frequency of F ⁴ _GAO and multi-channel - at least 2 channels, the thirteenth emission unit (MTRBIS) of signals (78) at frequency F ⁴ _GAO - a group of acoustic emitters ZDCH and UZDCH directed and oriented downwards at an angle of no more than 30 degrees, placed above the water; the second channel of hydroacoustic thickening (VKGSO) of the sediment (79) containing in series functionally connected: the fourteenth removable digital carrier (ChTSTSNS) of signals (80) at a frequency of F ² _GSO - the fourteenth flash drive; multi-channel - at least 2 channels, the fourteenth amplification unit (MCHTBUS) of signals (81) - a multi-channel digital power amplifier, at a frequency of F ² _GSO and multi-channel - at least 2 channels, the fourteenth emission unit (MCHTBIS) of signals (82) at a frequency of F ² _GSO , placed in a sealed and sound-transparent container (83), completely filled with clean water - a group of non-directional, placed in the bottom layer of water at different horizons, hydroacoustic emitters ZDCH, placed in sealed and sound-transparent containers, completely filled with clean water.

The method of non-reagent cleaning of SHV is implemented as follows (figure 1 - figure 5).

In the process of production activities (for example, when mining ore gold in the Kamchatka Territory - in an "ecologically vulnerable area"), there is an objective need to clean up (from CN, HV, HM and BB) SH - waters formed as a result of the influx of groundwater and surface natural waters into mine workings, where they are polluted during various mining operations (gold, etc.). “Technological pollution” of SHV KCh and TDVV occurs when drilling blast holes and boreholes, crushing rocks in an explosive way, the operation of tunneling machines, etc. "Natural pollution" of SH occurs in groundwater, which almost always contains HM (HM ions). “Bactericidal contamination” of SHV BB occurs as a result of rotting of wooden supports, etc.

Catchment of SHV, dewatering of SHV and cleaning of SHV (from KCh, VV, TM and BB), in the process of implementing the developed method, is carried out as follows.

Mine waters (with KCh and with VV: TDVV, SDVV, KDVV and SKDVV, as well as with TM and with BB) are collected from the mine site using several - at least 2, identical to each other in their purpose, drainage ditches (7 ) and sent to several - at least 2, identical to each other in their purpose, local water collectors (8), in which, due to the force of gravity (gravity), they carry out: significant (more than 50%) cleaning of SHV from KDVV, insignificant (less than 50%) cleaning of SHV from SDVV and insignificant (less than 10%) cleaning of SHV from TDVV. However, all (100%) of CN, TM, and BB, as well as almost all (more than 90%) of TDEP, a significant part (more than 50%) of ADD, a minor part (less than 59%) of CVD, and a small part (less than 10%) of ATEP remain in SW.

To improve the efficiency (quality) of the gravitational cleaning of the SHV in the first elements (2) of the SVO (1), in the process of implementing the developed method, PCAV is used (22). At the same time: with the help of functionally connected in series: PSCNS (27), MPBUS (28) and MPBIS (29) PCGAK (26) perform playback (playback of previously recorded specially synthesized signals - with high frequency and level gradients, etc.), amplification (up to the required level) and non-directional (in all directions) radiation of signals (hydroacoustic waves) at the frequency F ¹ _HAC , and, as a result, hydroacoustic coagulation of HF and differently dispersed explosives at a great distance (tens of meters) from MPBIS (29). At the same time, in the process of converting electrical energy into acoustic energy, in the immediate vicinity (tens of cm) from MPBIS (29), electrochemical (due to the induced electromotive force) coagulation of HF and differently dispersed explosives is carried out. At the same time, due to the sorption properties of explosives, TM and BB are extracted (in the process of acoustic and electrochemical coagulation) from SHV by their acoustic-sorption coagulation with explosives. Due to the increased mass of new (coagulated) explosives (aggregators), and (as a result) increased gravity, newly formed (coagulated) particles (aggregators) are more intensively (at a higher speed) deposited in the lower horizons of the explosives (below the water intake horizon) and on bottom. At the same time, with the help of serially functionally connected: VSCNS (31), MVBUS (32) and MVBIS (33) PKGGO (30) carry out reproduction, amplification and directed (from the upper layer of the SHV towards the bottom) radiation of signals (hydroacoustic waves) at a frequency F ¹ _GGO , under the influence of which forced (in addition to gravity) and accelerated (at an increased speed) gravitational-hydroacoustic sedimentation into the lower layers of the SH and onto the bottom of the initial CC and HE, as well as previously coagulated (in various ways) differently dispersed explosives are carried out. At the same time, with the help of serially functionally connected: TSCNS (35), MTBUS (36) and MTBIS (33) PKGAO (34) they reproduce, amplify and direct (from above the surface layer of the SHV - from the air, towards the bottom at an angle of no more than 30 degrees - to ensure maximum penetration of acoustic energy under water) emission of signals (acoustic waves) at a frequency of F ¹ _GAO , under the influence of which forced (in addition to gravity) and accelerated (at an increased speed) gravitational-acoustic sedimentation into the lower layers of the SH original CF and explosives, as well as previously coagulated (in various ways) differently dispersed explosives. As a result, the following is carried out: complete cleaning of the SHV from SKDVV, almost complete purification of the SHV from KDVV, significant purification of the SHV from SDVV, insignificant purification of the SHV from TDVV and insignificant purification of the SHV: from CN, HM and BB.

Subsequently, the "pre-cleaned" in the corresponding first element (2) of the SVO (1) of the SV is sent through the corresponding local pipeline (9) to the corresponding mine working (10) of the secondary element (3) of the SVO (1), and the "rough cleaning" of the SV is carried out by analogy with the “preliminary cleaning” of the SHV in the first element (2) of the CBO (1).

At the same time, in several - at least 2, identical to each other in their purpose, the second elements (3) of the CBO (1) use the VKAV (22), in which: with the help of functionally connected in series: CHSTsNS (39), MCHBUS (40 ) and MCHBIS (41) VKGAK (38) perform playback (playback of previously recorded specially synthesized signals), amplification (to the required level) and non-directional (in all directions) radiation of signals (hydroacoustic waves) at a frequency of F ² _HAC , and, as a result , hydroacoustic coagulation of HF and differently dispersed explosives at a great distance (tens of meters) from the MCHLIS (41). At the same time, in the process of converting electrical energy into acoustic energy, in the immediate vicinity (tens of cm) from the MCHLSI (41), electrochemical (due to the induced electromotive force) coagulation of HF and differently dispersed explosives is carried out. At the same time, due to the sorption properties of explosives, TM and BB are extracted (in the process of acoustic and electrochemical coagulation) from SHV by their acoustic-sorption coagulation with explosives. Due to the increased mass of new (coagulated) explosives (aggregators), and (as a result) increased gravity, newly formed (coagulated) particles (aggregators) are more intensively (at a higher speed) deposited in the lower horizons of the explosives (below the water intake horizon) and on bottom. At the same time, with the help of serially functionally connected: PTSTSNS (43), MPTBUS (44) and MPTBIS (45) VKGGO (42) carry out reproduction, amplification and directed (from the upper layer of water towards the bottom) radiation of signals (hydroacoustic waves) at a frequency F ² _GGO , under the influence of which forced (in addition to gravity) and accelerated (at an increased speed) gravitational-hydroacoustic sedimentation into the lower layers of the SH and onto the bottom of the initial CC and HE, as well as previously coagulated (in various ways) differently dispersed explosives, is carried out. At the same time, with the help of sequentially functionally connected: SSCNS (47), MSHBUS (48) and MSHBIS (49) VKGAO (46) reproduce, amplify and direct (from above the surface layer of the SHV - from the air, towards the bottom at an angle of no more 30 degrees - to ensure maximum penetration of acoustic energy under water) radiation of signals (acoustic waves) at a frequency of F ² _GAO , under the influence of which forced (in addition to gravity) and accelerated (at an increased speed) gravitational-acoustic sedimentation into the lower layers of the SH original CF and explosives, as well as previously coagulated (in various ways) differently dispersed explosives. As a result, the following is carried out: complete cleaning of the SHV from KDVV, almost complete cleaning of the SHV from SDVV, significant purification of the SHV from TDVV, significant purification of the SHV from TDVV and significant purification of the SHV: from CN, HM and BB.

Subsequently, the "coarsely cleaned" in the corresponding second element (3) SVO (1) ShV, with the help of a water pump (12) through the corresponding main pipeline (9), the mines are sequentially sent to the surface of the earth - into the corresponding first receiving chamber (14), in the first clarification chamber of the third element (4) CBO (1), and “fine cleaning” of the CW is carried out - by analogy: with the “preliminary cleaning” of the CW in the first element (2) of the CBO (1) and with the “coarse cleaning” of the CW in the second element (3) SVO (1), and also (additionally) carry out the first hydroacoustic sediment thickening.

To do this, in the third element (4) of the CBO (1), TKAV (24) is used, in which: with the help of serially functionally connected: SSCNS (51), MSCHUS (52) and MLSIS (53) TKGAK (50) perform reproduction, amplification and omnidirectional emission of signals at a frequency of F ³ _HAC , and, as a result, hydroacoustic coagulation of HF and differently dispersed explosives at a great distance from the MSBIS (53). At the same time, in the process of converting electrical energy into acoustic energy, electrochemical coagulation of CP and differently dispersed explosives is carried out in the immediate vicinity of the MSBIS (53). At the same time, due to the sorption properties of explosives, TM and BB are extracted from SHV by their acoustic-sorption coagulation with explosives. Due to the increased mass of new (coagulated) explosives, and the increased force of gravity, the newly formed particles settle more intensively into the lower horizons of the explosives and onto the bottom. At the same time, with the help of functionally connected in series: VOSCNS (55), MVOBUS (56) and MVOBIS (57) TKGGO (54) reproduce, amplify and direct radiation of signals at a frequency of F ³ _GGO , under the influence of which forced and accelerated gravitational hydroacoustic sedimentation in the lower layers of SH and on the bottom of the original CC and HE, as well as previously coagulated differently dispersed HE. At the same time, with the help of functionally connected in series: DSCNS (59), MDBUS (69) and MDBIS (70) TKGAO (58) reproduce, amplify and direct radiation of signals at a frequency of F ³ _GAO , under the influence of which forced and accelerated gravitational acoustic deposition into the lower layers of water of the original CS and explosives, as well as previously coagulated differently dispersed explosives. As a result, the following is carried out: complete cleaning of the SHV from TDVV and almost complete cleaning of the SHV from: KCh, TM and BB.

At the same time, with the help of functionally connected in series: DESCNS (63), MDEBUS (64) and MDEBIS (65), placed in a sealed and sound-transparent container (66), completely filled with clean water, PKGSO (62) perform reproduction, amplification and non-directional (in all directions in the bottom layer) radiation of signals (hydroacoustic waves) at a frequency of F ¹ _GSO , and, as a result, hydroacoustic sediment thickening (by acoustic coagulation of sediment particles, by acoustic displacement of water from microspaces between sediment particles, etc. ) at a great distance from MDEBIS (65), without siltation (and subsequent decrease in efficiency) of MDEBIS (65). At the same time, on the hydroacoustically thickened sludge in the first receiving chambers (14) - with vertical turbulence (formed when the ball is released), the third element (4) of the SVO (1) is hydraulically settling particles. Subsequently, periodically (as needed), hydroacoustically thickened sediment (saturated with HM and BB) is removed (by mechanical or hydraulic method) from the bottom to the surface, and sent to a solid waste storage site, or for deep processing. In the future, the "finely cleaned" in the corresponding third element (4) SVO (1) SV through the corresponding first conduit (16) is sequentially sent to the corresponding second receiving chamber (17) and to the second clarification chamber (18) of the fourth (5) SVO (1 ), and carry out "complete cleaning" (100%) of the CW and hydroacoustic thickening of the sediment - by analogy with the "fine cleaning" of the CW in the third element (4) of the CBO (1).

To do this, in the fourth element (5) CBO (1), CHKAV (25) is used, in which: using the following functionally connected in series: OSCNS (68), MOCHUS (69) and MOBIS (70) CHKGAK (67) perform reproduction, amplification and non-directional emission of signals at a frequency of F ⁴ _HAC , and, as a result, hydroacoustic coagulation of HF and differently dispersed explosives at a great distance from MOBIS (70). At the same time, in the process of converting electrical energy into acoustic energy, in the immediate vicinity of MOBIS (70), electrochemical coagulation of CP and differently dispersed explosives is carried out. At the same time, due to the sorption properties of explosives, TM and BB are extracted from SHV by their acoustic-sorption coagulation with explosives. Due to the increased mass of new (coagulated) explosives, and the increased force of gravity, the newly formed particles settle more intensively into the lower horizons of the explosives and onto the bottom. At the same time, with the help of serially functionally connected: DVSTSNS (72), MDVBUS (73) and MDVBIS (74) CHKGGO (71) reproduce, amplify and directional emit signals at a frequency of F ⁴ _GGO , under the influence of which forced and accelerated gravitational hydroacoustic sedimentation in the lower layers of SH and on the bottom of the original CC and HE, as well as previously coagulated differently dispersed HE. At the same time, with the help of serially functionally connected: TRSCNS (76), MTRBUS (77) and MTRBIS (78) ChKGAO (75) carry out reproduction, amplification and directional radiation of signals at a frequency of F ⁴ _GAO , under the influence of which forced and accelerated gravitational acoustic deposition into the lower layers of the SH of the original CS and explosives, as well as previously coagulated differently dispersed explosives. As a result, the following is carried out: complete (100%) cleaning of the SH from CN, BB, HM and BB.

At the same time, with the help of functionally connected in series: CHTSTSNS (80), MCHTBUS (81) and MCHTBIS (82), placed in a sealed and sound-transparent container (83), completely filled with clean water, PKGSO (62) carry out reproduction, amplification and non-directional emission of signals at the frequency F ² _GSO , and, as a result, hydroacoustic sediment thickening at a great distance from MDEBIS (82) and without siltation of MDEBIS (82). At the same time, on the hydroacoustically thickened sediment in the second receiving chambers (17) - with vertical turbulence (formed during the discharge of the SHV), the fourth element (5) of the SVO (1) is hydraulically settling particles. Subsequently, periodically hydroacoustically thickened sediment is removed from the bottom to the surface, and sent to a solid waste storage site, or for deep processing.

However, during periods of spring floods and intense rains (cyclones, typhoons, etc.), a situation may arise with a sharp (within several hours) and multiple (2 times or more) increase in the flow rate of CW, and, as a result, with a possible decrease quality of non-reagent cleaning of SHV.

To exclude this, the SHV from the fourth element (5) of the SVO (1) is sent to the fifth (6) element of the SVO, in which, thanks to the filter elements (19), which additionally capture UCH and TDVV, and sorbing elements (20), with the help of which HM and BB are additionally extracted; At the same time, due to preliminary acoustic coagulation (KCh and VV), preliminary acoustic sorption (VV and TM) and preliminary acoustic disinfection (destruction of BB), filter elements (19) and sorbing elements (20) of the fifth element (6) of the SVO (1). In the future, a completely cleaned SHV (including at its increased costs) is sent through a drainage pipeline (21) to a natural surface watercourse - to a stream (or to a river). Wherein:

1. Efficient (to the requirements of the maximum concentration limit _{for fish farms} ), cleaning of SHV (from HF, BB, TM and BB) is ensured due to the fact that:

- purification of SHV is carried out at 5 stages (in five elements of SVO) and using various physical mechanisms (settling, filtering, sorption, etc.);

- carry out (in a large volume of SHV) acoustic coagulation (due to a multiple increase in the number of collisions between particles, mechanical attachment of less massive and more mobile HF and TDVV to more massive and less mobile SDVV, KDVV, etc.);

- carry out (in the immediate vicinity of hydroacoustic emitters) electrochemical coagulation in the process of converting electrical energy into acoustic energy (accompanying effect of electromotive force);

- carry out acoustic-sorption (due to the physical and chemical properties of explosives) coagulation;

- carry out gravitational sedimentation of the original and previously coagulated particles;

- carry out gravitational-acoustic sedimentation of the original and previously acoustically coagulated particles;

- carry out acoustic thickening of the sediment, and, thereby, increase the working volume of the corresponding sump;

- carry out a mechanical delay of impurities in the filter elements;

- carry out physico-chemical retention of impurities in sorbing elements;

- carry out periodic (as necessary) removal of sediment from the elements (repartitions) of the water treatment system, etc.

2. Physical cleaning of SHV (from CC, BB, TM and BB):

- do not use chemical reagents (coagulants and flocculants) for coagulation of CN and TDBB;

- do not use chlorine-based chemicals for disinfection of SHV;

- use acoustic, electrochemical and acoustic-sorption coagulation of HF and explosives among themselves, as well as with TM and BB;

- use the sorption properties of explosives to extract HM and BB;

- use non-linear effects (acoustic cavitation, etc.) for the disinfection of air filters;

- use gravitational settling of the original and previously coagulated particles;

- use gravitational-acoustic sedimentation of the original and previously coagulated particles;

- hydraulic settling of particles on gravitational-hydroacoustic thickened sludge is used, etc.

3. Cleaning of large (at a flow rate of 2000 m ³ /hour and more) volumes of screws is ensured due to the fact that:

- purification of SHV is carried out at 5 stages and using various physical mechanisms (settling, filtering, etc.);

- carry out (in a large volume of SHV) acoustic coagulation (due to a multiple increase in the number of collisions between particles, mechanical attachment of less massive and more mobile HF and TDVV to more massive and less mobile SDVV, KDVV, etc.);

- carry out (in the immediate vicinity of hydroacoustic emitters) electrochemical coagulation in the process of converting electrical energy into acoustic energy (accompanying effect of electromotive force);

- carry out acoustic-sorption (due to the physical and chemical properties of explosives) coagulation;

- carry out gravitational sedimentation of the original and previously coagulated particles;

- carry out gravitational-acoustic sedimentation of the original and previously acoustically coagulated particles;

- carry out acoustic thickening of the sediment, and, thereby, increase the working volume of the corresponding sump;

- carry out a mechanical delay of impurities in the filter elements;

- carry out physico-chemical retention of impurities in sorbing elements;

- carry out periodic (as necessary) removal of sediment from the elements (repartitions) of the water treatment system, etc.

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

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

- 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 the equipment is carried out with great discreteness (once every 7 days) and directly during the operation of the water treatment system, so no special time is required to stop water treatment and maintenance of the device, etc.

5. The minimum financial and time costs are ensured due to the fact that:

- reduce (by at least 30%) the area allotted for the construction of surface elements of the WSS;

- SHV cleaning is carried out in five stages;

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

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

- time for installation of all equipment does not exceed 5 days;

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

6. Expansion of the scope (work during the freeze-up period at surface water treatment facilities) is provided due to the fact that:

- SHV cleaning is carried out at 5 stages and using various physical mechanisms;

- carry out gravitational-acoustic sedimentation of the original and previously acoustically coagulated particles;

- carry out acoustic thickening of the sediment, and, thereby, increase the working volume of the corresponding sump;

- carry out a mechanical delay of impurities in the filter elements;

- carry out physico-chemical retention of impurities in sorbing elements;

- use means of conversion hydroacoustics, etc.

7. Medical safety for a person is ensured due to the fact that:

- completely eliminate the use of chemical reagents for cleaning SHV;

- gravitationally-acoustically compacted sediment containing a large amount of HM and BB is disposed of;

- the formation and emission of hydroacoustic waves is carried out using mass-produced 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, etc.

8. Ecological safety for the environment (OPS) is ensured due to the fact that:

- completely exclude the use of chemical reagents (for cleaning of SHV) and chemicals (for decontamination of SHV);

- gravitational-acoustic method compacts the sediment and bodies of impervious dams of settling ponds, which excludes parasitic drainage of polluted SHV;

- gravitationally-acoustically thickened sediment containing a large amount of HM and BB is disposed of;

- parameters (frequency, amplitude, signal shape) of hydroacoustic waves are environmentally safe for the OPS as a whole, etc.

Distinctive features of the proposed method are:

1. The amplitude of the sound pressure of the ZDCH and UZDCH waves is at least 10 ⁴ Pa at a distance of 1 m from the corresponding hydroacoustic emitter.

2. As the first element, local water collectors, identical to each other, located in the sections of the mine, are used,

3. As the second element, identical main water collectors are used, located in the near-shaft yard of the mine,

4. Settling ponds identical to each other are used as the third element.

5. As the fourth element, filter chambers identical to each other are used.

6. As the fifth element, filters with sorbents identical to each other (with filtering and sorbing elements) are used.

7. Additionally, electrochemical coagulation of HF, BB, TM and BB is carried out in the near field of hydroacoustic emitters in the process of converting electrical energy into acoustic energy.

8. Additionally, the previously coagulated HF, BB, TM and BB are deposited - under the action of acoustic waves ZDCH and UZDCH with a sound pressure amplitude of at least 1 Pa at a distance of 1 m from the corresponding acoustic (surface) emitter, directed from the air under the water at an angle not over 30 degrees

9. Additionally, NTV is cleaned from BB (disinfection of SHV) in the near field of hydroacoustic emitters - due to the bactericidal effect on the microflora of hydrogen peroxide and OH ° radicals, which are formed under water during the emission of acoustic waves with an amplitude of sound pressure of at least 10 ⁴ Pa;

10. Additionally, in the fifth element, the previously coagulated (acoustically and electrochemically) filters HF, BB, TM and BB are extracted on sorbents.

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

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

Signs: 2, 3, 5, 7 and 8 are new, and their use for non-reagent cleaning of SH (from HF, BB, TM and BB) is unknown.

Signs: 1 and 4 are new and it is not known to use them for reagent-free cleaning of SHV. At the same time, it is known: for sign 1 - the use of acoustic waves with a sound pressure amplitude of at least 10 ⁴ Pa (at a distance of 1 m from the corresponding hydroacoustic radiator) to ensure the operation of parametric radiating antennas in nonlinear hydroacoustics; for attribute 4 - use of settling ponds for clarification of water.

Signs: 6, 9 and 10 are known.

Thus, the presence of new essential features, in conjunction with the known ones, ensures the appearance of a new property in the proposed solution that does not coincide with the properties of known technical solutions - effectively (qualitatively - up to the level of environmental legislation requirements), reagentless (without the use of chemical reagents) to clean large volumes ShV (ShV consumption is not less than 2000 m ³ / h) from KCh, VV, TM and BB, in a relatively simple way, with minimal financial and time costs and expansion of the scope (work during the freeze-up period at ground water treatment facilities, during the spring flood, during periods of intense rains, typhoons, etc.), ensuring medical safety for humans and environmental safety for the environment in general. In this case, we have a new set of features and their new relationship, and not a simple combination of new features and already known ones, but it is the execution of operations in the proposed sequence that leads to a qualitatively new effect. This circumstance allows us to conclude that the developed method meets the criterion of "significant differences".

An example of the implementation of the method.

Industrial tests of the developed method were carried out: in the period from 2002 to 2006 - at a platinum deposit in the Kamchatka Territory; in the period from 2006 to 2008 - at a coal deposit in South Korea; in the period from 2009 to 2011 - at a copper deposit in Vietnam; in the period from 2912 to 2020 - at a diamond deposit in the Arkhangelsk region, etc.

In Fig.6 - Fig.10 illustrates the test results of the developed method of non-reagent cleaning of CM.

At the same time, Fig.6 shows the results of a 4-stage reagent-free purification of SM (initial content of explosives in SM - 1017 g/l) for the developed method (histograms with solid lines) and the prototype method (histograms with a dotted line). In this case: the index I denotes the content of explosives (mg/l) in the SH at the outlet of the first element (2) CBO (1); index II - the content of explosives in SHV at the outlet of the second element (3) CBO (1); index III - the content of explosives in SHV at the output of the third element (4) CBO; index IV - the content of explosives in the SH at the output of the fourth element (5) CBO (1).

As can be seen from Fig.6, in the process of implementing the prototype method (histograms indicated by a dotted line) the content of explosives in the SM (SS, mg/l) was successively reduced from 1017 mg/l - the initial content of the explosives in the SM at the inlet of the first element ( 2) SVO (1), up to 10 mg/l (private purification efficiency 99.0%). While (at MPC _{fish farm} = 4.5 mg/l) in the process of implementing the developed method (histograms marked with a solid line), the content of SM in SM (SS, mg/l) was consistently reduced from 1017 mg/l - the initial content of explosives in SHV at the inlet of the first element (2) SVO (1), up to 3 mg/l (private purification efficiency 99.7%). That is, the quality indicators of SH (SS, mg/l) at the outlet of the WSS (1) only in the process of implementing the developed method met the requirements of environmental legislation (MAC _fish.xoz. = 4.5 mg/l), and the private efficiency (gain) of the developed method left 79.0% (TWR=10 mg/l and TWR=3 mg/l).

Figure 7 presents the results (in the form of density, t/m ³ ) reagent-free thickening of the sediment in the third (index III) element (4) CBO (1) and in the fourth (index IV) element (5) CBO (1) for the developed method (histograms with a solid line) and for the prototype method (histograms with a dotted line). As can be seen from Fig.7 in the process of implementing the prototype method (histograms indicated by a dotted line), the sediment density in the third element (4) CBO (1) and in the fourth element (5) CBO (1) was 1.4 t/m ³ and 0.7 t/m ³ , respectively. While for the developed method (histograms indicated by a solid line) - 2.1 t/m ³ (the effect of the developed method is 33.3%) and 1.2 t/m ³ (the effect of the developed method is 41.6%), respectively .

Figure 8 illustrates the values of the first indicator of the bactericidal quality of SHV (OMC CFU in 1 ml) for the prototype method (histograms with dotted lines) and for the developed method (histograms with solid lines) at the input (index I) and at the output (index II ) of the third element (4) SVO (1). As can be seen from Fig.8, this quality indicator for the prototype method improved (decreased) from 73 to 44 (by 39.7%), while for the developed method it improved (decreased) from 73 to 0 (by 100%) . That is, the private efficiency (gain) of the developed method was 60.3%.

Figure 9 illustrates the values of the second indicator of bactericidal water quality (OKB CFU in 100 ml) for the prototype method (histograms with dotted lines) and for the developed method (histograms with solid lines) at the inlet (index I) and at the outlet (index II ) of the third element (4) SVO (1). As can be seen from Fig.9, this indicator of the quality of the WB for the prototype method improved (decreased) from 12 to 2 (by 83.3%), while for the developed method it improved (decreased) from 12 to 0 (by 100%). That is, the private efficiency of the developed method was 16.7%.

Figure 10 presents (in the form of a table) the results of the extraction of HM from the SHV (and their subsequent precipitation under the influence of acoustic waves) in the third element (4) of the SVO (1), both immediately after the acoustic impact on the SHV, and after a day gravitational settling of CW (in a settling pond) after acoustic impact on CW. As can be seen from figure 10, after the acoustic impact on the CM, the content of HM in them decreased many times over. In particular, the content of copper in the screw was reduced by 36 times, the content of nickel in the screw was reduced by 23 times, the content of zinc in the screw was reduced by 10 times, etc.

In this way:

1. Efficient (to the requirements of the maximum concentration limit _{for fish farms} ), cleaning of SHV (from CN, BB, HM and BB) was ensured due to the fact that:

- purification of SM was carried out at 5 stages and using various physical mechanisms (settling, filtering, etc.);

- carried out acoustic coagulation;

- carried out electrochemical coagulation in the process of converting electrical energy into acoustic energy;

- carried out acoustic-sorption coagulation;

- carried out gravitational sedimentation of the original and previously coagulated particles;

- carried out gravitational-acoustic sedimentation of the original and previously acoustically coagulated particles;

- acoustic thickening of the sludge was carried out, and, thereby, the working volume of the corresponding sump was increased;

- carried out a mechanical delay of impurities in the filter elements;

- carried out physico-chemical retention of impurities in sorbing elements;

- carried out periodic (as needed) removal of sediment from the elements (repartitions) of the water treatment system, etc.

2. The physical cleaning of the SHV was ensured due to the fact that:

- did not use chemical reagents (coagulants and flocculants) for coagulation of CN and TDBB;

- did not use chlorine-based chemicals for disinfection of SHV;

- used acoustic, electrochemical and acoustic-sorption coagulation of HF and explosives with each other, as well as with HM and BB;

- used the sorption properties of explosives to extract HM and BB;

- used non-linear acoustic effects (acoustic cavitation, etc.) for the decontamination of air filters;

- used gravitational settling of the original and previously coagulated particles;

- used gravitational-acoustic sedimentation of the original and previously coagulated particles;

- used hydraulic sedimentation of particles on gravity-hydroacoustic thickened sediment, etc.

3. Cleaning of large (at a flow rate of 2000 m ³ /hour and more) volumes of screws was ensured due to the fact that:

- purification of SM was carried out at 5 stages and using various physical mechanisms (settling, filtering, etc.);

- carried out (in a large volume of SH) acoustic coagulation;

- carried out electrochemical coagulation in the process of converting electrical energy into acoustic energy;

- carried out acoustic-sorption coagulation;

- carried out gravitational sedimentation of the original and previously coagulated particles;

- carried out gravitational-acoustic sedimentation of the original and previously acoustically coagulated particles;

- acoustic thickening of the sludge was carried out, and, thereby, the working volume of the corresponding sump was increased;

- carried out a mechanical delay of impurities in the filter elements;

- carried out physico-chemical retention of impurities in sorbing elements;

- carried out periodic (as needed) removal of sediment from the elements (repartitions) of the WSS, etc.

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

- the formation and emission of hydroacoustic waves ZDCH and UZDCH was carried out using commercially available electronic devices, as well as hydroacoustic emitters;

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

- maintenance of the equipment was carried out with great discreteness (every 7 days) and directly during the operation of the water treatment plant, so no special time was required to stop water treatment and equipment maintenance, etc.

5. The minimum financial and time costs were ensured due to the fact that:

- reduced (by at least 30%) the area allotted for the construction of ground elements of the NWO;

- cleaning of SHV was carried out in five stages;

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

- power consumption of electronic devices of the device that implements the developed method, provided small (less than 0.5 W/m ³ );

- time for installation of all equipment did not exceed 5 days;

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

6. The expansion of the scope (work during the freeze-up period at surface water treatment facilities) was ensured due to the fact that:

- purification of SH was carried out at 5 stages and using various physical mechanisms;

- carried out gravitational-acoustic sedimentation of the original and previously acoustically coagulated particles;

- carried out acoustic thickening of the sediment, and, thereby, increased the working volume of the corresponding sump;

- carried out a mechanical delay of impurities in the filter elements;

- carried out physico-chemical retention of impurities in sorbing elements;

- used means of conversion hydroacoustics, etc.

7. Medical safety for a person was ensured due to the fact that:

- completely eliminated the use of chemical reagents for cleaning SHV;

- completely eliminated the use of chemicals for the disinfection of SHV;

- gravity-acoustically compacted sediment containing a large amount of HM and BB was disposed of;

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

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

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

8. Environmental safety for the NSO was ensured due to the fact that:

- completely eliminated the use of chemical reagents (for cleaning the CW) and chemicals (for disinfecting the CW);

- the gravitational-acoustic method compacted the sediment and the bodies of impermeable dams of settling ponds, which excluded parasitic drainage of polluted SH;

- gravitationally-acoustically thickened sediment containing a large amount of HM and BB was disposed of;

- used medically safe parameters (frequency, amplitude, signal shape) of hydroacoustic waves for humans, etc.

Claims (1)

The method of non-chemical treatment of mine waters, which consists in hydroacoustic action on the cleaned mine water and on the compacted sediment, alternating with each other: pulsed - with a duration of less than 1 s, quasi-pulsed - with a duration of 1 to 10 s and continuous - with a duration of more than 10 s, sound and ultrasonic waves frequency ranges in sequentially functionally connected: in the first, second, third, fourth and fifth elements of the mine water treatment system, in acoustic coagulation of colloidal particles, suspended solids and heavy metals, in gravitational and gravitational-acoustic sedimentation to the bottom earlier acoustically coagulated colloidal particles, suspended solids and heavy metals, in the acoustic compaction of the sludge, followed by its periodic extraction and disposal at the solid waste storage site, characterized in that the amplitude of the sound pressure of the waves of the sound and ultrasonic frequency ranges is at least 10 ⁴ Pa at a distance 1 m from the corresponding hydroacoustic emitter, as the first element, identical to each other local water collectors located in the sections of the mine are used; settlers, as the fourth element, identical filter chambers are used, as the fifth element, identical filters are used, additionally, electrochemical coagulation of colloidal particles, suspended solids, heavy metals and pathogenic bacteria in the near field of hydroacoustic emitters in the process of converting electrical energy into acoustic energy, additionally carry out the deposition of previously coagulated colloidal particles, suspended solids, heavy metals and pathogenic bacteria under the action of acoustic waves in the sound and ultrasonic range at frequencies with a sound pressure amplitude of 1 Pa at a distance of 1 m from the corresponding acoustic emitter, directed from the air under water at an angle of 25 degrees, additionally, pathogenic bacteria are cleaned in the near field of hydroacoustic emitters when acoustic waves are emitted with a sound pressure amplitude of 10 ⁴ Pa, additionally, in the fifth element, previously coagulated colloidal particles, suspended solids, heavy metals and pathogenic bacteria are extracted on filters.

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