RU2691713C1 - Method of reagentless purification of wastewater and sediment dehydration - Google Patents

Abstract

FIELD: water treatment.SUBSTANCE: invention can be used in water treatment for preliminary purification of drinking water, circulating, industrial and household wastewater, during dehydration of sediments. In order to carry out the method successively, wastewater is treated from coarse waste, from coarse suspended substances – in sand trap (7), from medium-dispersed suspended substances and from part of pathogenic bacteria – in primary settlers (12), from finely dispersed suspended substances and soluble impurities – in aerotanks (16); from fine impurities, sludge flakes and from part of pathogenic bacteria – in secondary settlers (20); from remaining pathogenic bacteria – in ultraviolet disinfection unit. Sludge sites (32) are used to dehydrate and disinfect the formed sediment, as well as to decontaminate drainage waters to be separated from dehydrated residue. In primary settlers (12), in secondary settlers (20), as well as at sludge areas (32), traveling acoustic and acoustic waves of acoustic and ultrasonic frequency bands are emitted with amplitude of acoustic pressure of not less than 10Pa at 1 m from working surface of corresponding hydroacoustic radiator (40,48,56). Action of the emitters provides acoustic degassing, coagulation and deposition of suspended substances, compaction of sediment, disinfection of water and sediment. Purified and decontaminated wastewater is directed into a natural watercourse, and dehydrated and disinfected sediment is transported for further use, processing or recycling.EFFECT: method provides high-quality, reagentless purification of large volumes of water and sediment dehydration with complete environmental safety for the environment, and also increases efficiency of production of mining industry during ore dressing.1 cl, 11 dwg, 1 ex

Description

The invention relates to the field of physics and can be used for: reagent-free cleaning of mineral impurities (MP), biological impurities (BP) and pathogenic bacteria (BB) of domestic wastewater (BSV), as well as for reagent-free sludge dewatering in sewage treatment plants (KOS ) - in the interests of environmental safety of the population; reagent-free removal of suspended solids from industrial wastewater (for example, mining enterprises) - in the interests of ensuring the environmental safety of production (for example, in diamond mining, etc.); reagent-free treatment of sludge particles of recycled industrial water - in the interests of increasing production efficiency (for example, to reduce the loss of diamonds during their dressing, etc.); for the preparation of high-quality drinking water taken from surface and (or) groundwater sources - in the interests of the quality of life (health, etc.) of the population, etc. Cpp 11 Ill.

There is a method of reagent-free purification of CB, consisting in substantial - more than 75%, cleaning from coarse explosives (CDVV) - more than 50 microns in size, insignificant - less than 50%, cleaning from medium dispersed explosives (MDS) - from 5 microns to 50 microns, and minimum - less than 5%, cleaning from fine explosives (TDVV) - less than 5 microns in size in the main sediment; in almost complete - more than 95%, purification from KDVV, substantial purification from ADHD and insignificant - less than 25%, purification from TDVV in the first additional clarifier; in full - 100%, cleaning of the KDVV, almost complete cleaning of the ADHD and minor cleaning of the TDVV in the second additional clarifier; in full purification of ADL and almost complete purification of TDVV in a special building - in an acoustic filter / Acoustic technology in mineral processing // Ed. B.C. Yamschikova. - M .: Science, 1987, p. 225-228.

The main disadvantages of this method are:

1. Low cleaning efficiency of the SV, due to the limited area of the special structure - an acoustic filter.

2. Insufficient quality of cleaning of CB from TDVV.

3. The impossibility of compaction and dewatering sediment.

4. The impossibility of cleaning the CB from the BP.

5. Impossibility of water purification from BB (impossibility of water disinfection), etc.

There is a method of reagent-free purification of CB, consisting in substantial cleaning from QDVV, slight cleaning from ADHD and minimal cleaning from TDVV - by acoustic impact (continuous, quasi-impulse and impulse) traveling hydroacoustic waves (BGAV) sound frequency range (HRC) - in the frequency range from 16 Hz to 16 kHz, and the ultrasonic frequency range (UZDCh) - in the frequency range above 16 kHz in the main sump, as used by the old sump with several - at least two, drainage channels; in almost complete cleaning of QFWV, substantial cleaning of ADHB and insignificant - less than 25%, cleaning of TDVV in the first additional clarifier - which is used as a working sump, by acoustic impact of the AHC HFA and UZDCH; in full cleaning from QDVV, almost full cleaning from ADVV, slight cleaning from TDVV in the second additional clarifier, which is used as a rough clarifier of CB, by acoustic impact of BGV HLA and UZDCH on SV and sediment; in full purification of ADHD, in significant purification of TDVV in the third additional clarifier, which is used as a clarifier for fine purification of drywall, by acoustic impact of BGAV HLA and UZDCh on HL and sediment; in a substantial purification of TDVV in the fourth additional settling tank, as which the surface filtration fields are used, by acoustic impact of the BFU HLC and UZDC and HL on the sludge; additionally carry out periodic - as required, the selection of compacted sludge with its subsequent disposal / S. Bakharev. Method reagent-free pit water treatment. - RF patent №2560771, 2014, publ. 08/20/2015, Byul. №23 /.

The main disadvantages of this method include:

1. Insufficient quality of cleaning CB from TDVV.

2. The impossibility of sludge dewatering.

3. The impossibility of cleaning CB from BP, etc.

5. Impossibility of water purification from BB, etc.

There is a method of reagent-free purification of CB from explosives (MP, BP) and BB, which consists in the almost complete cleaning of KDVV, minor cleaning from ADHD and minimal cleaning of TDVV, by periodic with alternating radiation and pause modes, as well as sequential in frequency in the main settling tank BGAV HFC and UZDCH; in full QDVV cleaning, considerable cleaning from ADHD and insignificant cleaning from TDVV in the first additional settling tank, by periodic - with alternation of radiation and pause modes, as well as sequential in frequency, formation of the AHFS EHEC and UZDCH; in almost complete cleaning of ADHD and minor cleaning of TDS in the second additional sedimentation tank - by periodically and consistently forming BGAV EHFC and UZDCH frequencies; in full purification from ADHD and significant purification from TDVV in the third additional settling tank - by periodic and sequential formation of standing hydroacoustic waves (AGSV) HFC and UZDCH frequencies; in almost complete purification from TDVV and BB in a special structure - in an acoustic hydro cyclone (AGT), operating with an excess static pressure of 3-5 atm .; acoustic compaction of sediment in a special structure / Bakharev S.А. The method of cleaning and disinfection of recycled and waste waters. - Patent of the Russian Federation No. 2280490, 2005, publ. 27.07.2006, Byul. №21. Diploma of FIPS in the nomination: "100 best inventions of Russia".

The main disadvantages of this method include:

1. Low productivity of cleaning of SV from explosives (MP, BP) and BB, as well as sludge dewatering, due to the limited volume of the working chamber of the AGC.

2. The high cost of cleaning a unit volume of SV (for example, 1 m) from explosives (MP and BP) and BB, as well as sludge dewatering.

3. Insufficient quality of cleaning CB from TDVV (MP and BP) and from BB, due to only one effective stage of their cleaning - in the AGC.

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

The closest to the claimed method is selected as the prototype method, the method of non-reagent purification of CB from explosives (MP, BP) and BB, as well as sludge dewatering, which consists in almost complete cleaning of KDVV, insignificant cleaning of ADVV and minimal cleaning of TDVV - by radiation of BGAV HSC and UZDCh with an acoustic pressure amplitude of at least 10 Pa at a distance of 1 m from the working surface of the corresponding sonar emitter in the main water purification module (GMOW); in full QDVV cleaning, substantial ADVV cleaning, insignificant TDVV cleaning and minimal BB cleaning - by emitting a BGAV EHF and UZDCH with acoustic pressure amplitude not less than 10 Pa at a distance of 1 m from the working surface of the corresponding hydroacoustic emitter, in the first additional module water purification (PDMOV); in almost complete cleaning of ADHD, significant cleaning of TDVV and insignificant cleaning of BB - by emitting BGAV EHF and ultrasonic ultrasound with an amplitude of acoustic pressure of at least 10 ² Pa at a distance of 1 m from the working surface of the corresponding hydroacoustic emitter (in the second additional module of water purification) VDMOV); in full cleaning from ADHD, substantial cleaning from TDVV, minor cleaning from BB - by emitting BGAV EHD and UZDCh with an acoustic pressure amplitude of at least 10 Pa at a distance of 1 m from the working surface of the corresponding hydroacoustic emitter in the third additional water purification module (TDMOV); in almost complete purification from TDVV and BB - by emitting a BGAV UZDCh with an acoustic pressure amplitude of not less than 10 ⁵ Pa at a distance of 1 m from the working surface of the corresponding sonar emitter and low-frequency electromagnetic waves in the first special structure (PSSB) - in a magneto-acoustic hydro cyclone ( MAGC); in acoustic sludge dewatering to transport humidity - 25 ... 30%; in the second special structure (HSSP) - in an acoustic drying chamber (AKSK) - by radiation of running acoustic waves (BAS) HSC and UZDCh with an amplitude of acoustic pressure of at least 10 ² Pa for 1 m distance from the working surface of the corresponding acoustic emitter; transportation of dehydrated sludge / Bakharev S.A. The method of cleaning and disinfection of water. - Patent of the Russian Federation No. 2487838, 2011, publ. 07/20/2013, Byul. No. 20 /.

The main disadvantages of the prototype method include:

1. The low productivity of the cleaning of SV from explosives (MP, BP) and BB, due to the limited volume of the working chamber of the MEGC.

2. Low productivity of sludge dewatering due to the limited volume of working chambers MAGTs and AKKS.

3. The high cost of cleaning a unit of volume SV (for example, 1 m ³ ) from explosives (MP and BP) and BB.

4. The high cost of dewatering per unit volume of sediment.

5. The impossibility of disinfecting the sludge in the process of dehydration.

6. The impossibility of disinfection of water separated in the process of sludge dewatering.

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

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

The technical result of the proposed method consists in quality - up to the requirements of environmental legislation (for example, up to the requirements of the MPC of _{fish farms} ), physical - without the use of chemical reagents (coagulants, flocculants) for the treatment of CB from explosives (MP and BP) and BB large (for example, at a flow rate SV of 3500 m ³ / h or more) volumes of contaminated (MT, BS and BS) NE with simultaneous dehydration of sludge, a relatively simple manner with minimal financial and time costs in any climatic conditions (e.g., during wind waves in settling basins, during the freezing-over period, etc.) and in any working conditions (for example, in the process of abrupt changes in the consumption of dry matter during the day, etc.) with ensuring medical safety for humans and environmental safety for the surrounding natural environment, in general.

This goal is achieved by the fact that in the known method of non-reagent purification of CB and sludge dewatering, which consists in cleaning KDVV and ADVV in GMO, in cleaning from KDVV, CDVV, ELV and BB in PDMO, by emitting BGV EHEC and UZDCH, in cleaning from DMVV , TDVV and BB in VDMOV, in cleaning from ADL, TDVV and BB in TDMOV - by emitting BGV EHD and UZDCH, in cleaning from BB - in PPSS, in sludge dewatering - in UPRSV, in transporting dehydrated sludge as GMOV several are used - at least two identical sand traps, in which (GOMVO) I perform full (100%) cleaning of KDVV and significant (more than 50%) cleaning from ADHD - by using the force of gravity, using several at least two identical water clarification tanks (primary settlers) identical to each other (PDMA) almost complete (more than 95%) purification of ADHD, minor (less than 50%) purification of TDVV and insignificant (less than 25%) purification of BB are carried out - by emitting BGAV EHF and UZDCH with amplitude of acoustic pressure not less than 10 ⁴ Pa at a distance of 1 m from the working surface of the corresponding hydro bushy radiator, as the WDMD, several at least two identical aero-tanks are used, in which (WDMOV) a complete purification of ADHD is carried out, a substantial (more than 75%) purification of TDP, a non-significant purification of BB and a complete purification of soluble impurities - through the use of special (SMO) microorganisms (microorganisms consuming oxygen) in the process of biological treatment of biological agents, several are used as TDMOV - at least two identical water clarification tanks (secondary clarifiers) identical to each other , in which (TDMOV) carry out almost complete cleaning from TDVV and significant cleaning from BB - by emitting BGAV EHD and UZDCh with an amplitude of acoustic pressure of at least 10 ⁴ Pa at a distance of 1 m from the working surface of the corresponding hydroacoustic emitter, an ultraviolet block is used as ESP water disinfection (BUFF), in which water disinfection is carried out - by irradiating it with ultraviolet light, several are used in the quality of the VPSS - at least three identical to each other sludge beds (PI) in which ohm (BCPC) carried dewatering sludge - by radiation BGAV ZDCH and UZDCH with acoustic pressure amplitude of at least 10 ⁴ Pa at a distance of 1 m from the working surface corresponding to the hydroacoustic transducer, an additional BCPC carried acoustic decontamination of sludge and acoustic disinfection of water (drain water) separated from the sludge in the process of its dehydration.

FIG. 1-fig. 7 shows a block diagram of a device that implements the developed method of reagent-free wastewater treatment and sludge dewatering (hereinafter referred to as the developed method). In this case: in FIG. 1 illustrates a block diagram of a device as applied to the general principle of the implementation of the developed method; in fig. 2 illustrates a block diagram of a device as applied to PDMOV; in fig. 3, illustrates a block diagram of a device as applied to TDMOV; in fig. 4 illustrates a block diagram of a device as applied to an ACTS; in fig. 5 illustrates a block diagram of a device as applied to a VSSS.

The device for reagent-free wastewater treatment and sludge dewatering (for example, at sewage treatment facilities of one of the cities in the Arkhangelsk region) in the simplest case contains: functionally connected in series: the main pipeline (1) polluted (MP, BP - in the form of KDVV, ADVV and TDVV , as well as BB) of wastewater (WSP) of waters, pumping station (2) WSP and distributor (4) WSP, which is the entrance to the sewage treatment plant (CW) of the structure (3), which, in turn, includes in series and in parallel functionally soy Inonii: distributor (4) ZSV; GMO (5) in the composition of parallel and sequentially functionally connected: several - at least two (to ensure continuous operation of one in the process of maintenance of the other), sand traps (7) identical to each other, several - at least two identical first water lines ( 8) - for the further transportation of dry cargo and which are, on the one hand, the exits of the GMO (6) and the entrances to the PDMOV (11), on the other hand, several - at least two sludge identical to each other first pipelines (9) - for further transportation sediment being I, in turn, are the first entrances to the main pipeline (10) of the WWTP sediment (3); PDMOV (11) in the composition of parallel and sequentially functionally connected: several - at least two (to ensure continuous operation of one in the process of maintenance of the other), identical settling tank (12) for rough cleaning of the tank, several - at least two, identical to each other second conduits (13) - for the further transportation of dry cargoes and which, on the one hand, are the outlets of the PFWP (11) and the entrances to the VDMA (15), on the other hand, several - at least two identical second pipelines (14) of the draft - for further transport irovki precipitate, which are, in turn, the second inputs of the main conduit (10) CBS pellet (3); VDMOV (15) in the composition of parallel and sequentially functionally connected: several - at least two (to ensure continuous operation of one in the process of maintenance of the other), aeration tanks identical to each other (16) of biological treatment of solar cells, several - at least two, identical to each other third conduits (17) - for the further transportation of dry cargoes and being, on the one hand, the outlets of the VDMA (15) and the entrances to the TDMOV (19), on the other hand, several - at least two third pipelines (18) identical to each other - for further sediment transportation, which, in turn, are the third entrances to the main pipeline (10) of the CBS (3) draft: TDMOV (19) consisting of parallel and sequentially functionally connected: several - at least two (to ensure continuous operation of one during maintenance another), identical settling tanks (20) for fine cleaning of dry mud tanks, several at least two identical fourth water lines (21) - for further transportation of dry mud and being, on the one hand, outlets of TDMOV (19) and entrances to the SSPS ( 23), on the other hand several, at least two identical fourth pipelines (22) of the sludge - for further transportation of the sludge, which in turn are the fourth entrances to the main pipeline (10) of the KOS (3) sludge: SPS (23) consisting of and in parallel functionally connected: separator (24) - with several - at least two, entrances and with several - at least four, exits, streams of cleaned water; several - at least four identical transparent - for ultraviolet light, conduits (25) , combiner (26) cleared and decontaminated CB, and the main conduit (27) for treated and decontaminated CB with a pump (28) for treated and wastewater, which is (the main conduit), on the one hand, the output of the TSF (23) KOS (3) and the entrance to the natural watercourse - river (two wavy lines in FIG. 1), on the other hand; VSPS (29) composed of series and parallel functionally connected: the main pipeline (10) sludge, pump (30) for transporting sludge (sand pump, slurry pump, etc.), separator (31) sludge, a few - at least three ( one - for filling, the second - for sludge dewatering, the third - for sludge removal) identical sludge beds (32) with several mutually identical each other - at least three for each sludge bed (one is on the left, the second is in the center of the sludge bed, third - to the right) identical to each other, drainage pipes and (33) intended to drain the drainage water formed during sludge dewatering, and which are the outlets of the high-altitude network (29).

The WWTP (3) also contains a combiner (34) for drainage water, the first pipeline (35) for drainage water, a pump (36) for drainage water and a second pipeline (37) for drainage water, which is the second inlet of the distributor (4) TSVS KOS (3) .

The device also contains functionally connected: the first movable module (38) for collecting dehydrated sludge (excavator, etc.) and several - at least two (one for loading dehydrated sludge, the second - for transporting dehydrated sludge), identical to each other mobile modules (39) for transportation of dehydrated sludge (dump truck, etc.) in the interests of its further processing (for example, for fertilizer, etc.), or recycling (if it contains harmful substances for human health, OPS, and t .d., substances).

The device also contains (Fig. 1 and Fig. 2) the first hydroacoustic (PHAM) module (40), consisting of functionally connected in series: the first (41) multichannel - at least two channels, the generator of the HRC signals and the UZDCh F ₁ , the first multichannel ( according to the number of channels of the corresponding generator) of the power amplifier (42) signals of the HRC and UZDCh F ₁ , the first multichannel (by the number of channels of the corresponding power amplifier) matching device (43), several (by the number of channels of the corresponding matching device) identical to each other the first signal cables (44) and several (according to the number of corresponding cables) identical first non-directional (directed in all directions) hydroacoustic emitters (45) HFC and UZDCh F ₁ , attached with several (by the number of emitters) identical each of the first cables (46) to several (according to the number of cables) identical first buoyancy (47) identical to each other, ensuring the location of the corresponding sonar transmitter (45) on the middle horizon (regardless of the water level in this septic tank) and in the geometer in the center of the corresponding sedimentation tank (12) of coarse purification ST.

The device also contains (Fig. 1 and Fig. 3): the second sonar (VGAM) module (48), as a part of functionally connected in series: the second (49) multichannel - at least two channels, the generator of the HRC signals and the UZDCh F ₂ , the second multichannel (according to the number of channels of the corresponding generator) of the power amplifier (50) of the signals of the HRC and UZDCh F ₂ , the second multi-channel (by the number of channels of the corresponding power amplifier) matching device (51), several (by the number of channels of the corresponding matching device) identical to each other second signal cables (52) and several (according to the number of corresponding cables) identical second non-directional (directed in all directions) hydroacoustic emitters (53) HFC and UZDCh F ₂ attached with several (by the number of emitters) identical to each other second cables (54) to several (by the number of cables) identical second buoyancy conditions (55), ensuring that the corresponding sonar transmitter (53) is located on the middle horizon (regardless of the water level in this sump) and in the geometer in the center of the appropriate clarifier (20) for the fine cleaning of the CB.

The device also contains (Fig. 1 and Fig. 5): the third sonar (TGAM) module (56), as a part of functionally connected: the third (57) multichannel - at least three channels, the generator of HRC signals and the UZDCh F ₃ , the third multichannel (the number of channels corresponding generator) power amplifier (58) and signals ZDCH UZDCH F _3, the third multi-channel (in the number corresponding to the power amplifier channel) matching device (59), several (the number of channels corresponding to the matching device) identical to each other gu third signal cable wires (60) and a number (the number of respective cable wires) identical to each other third omnidirectional (directed in all directions) sonar emitters (61) ZDCH and UZDCH F ₃ attached by means of several (according to the number of emitters) third cables (62) identical to each other to several (according to the number of cables) third buoyancy identical (63) to each other, ensuring that the corresponding hydroacoustic emitter (61) is located on the middle horizon (regardless of the level of sediment in this silt ke) and the geometric center of the corresponding area of sludge (32).

The device for the non-reagent treatment of dry mud and sludge dewatering (for example, for the WWTP of one of the cities in the Arkhangelsk region) in the simplest case functions (works) as follows.

Contaminated - with mechanical impurities (MP) and biological impurities (BP), both in the form of suspended solids (KDVV, ADVV and TDVV), and in the form of solutions, as well as contaminated (infected) with pathogenic bacteria (BB), waste (household, industrial etc.) water (WSC) is transported, by means of a pump station (2) WSC, through the main pipeline (1) to the WWTP (3).

In the distributor (4), which has two entrances and several at least two, identical to each other, outlets, SCW is evenly distributed over several - at least two (to ensure continuous operation of one during maintenance, or repair of another sand trap), identical to each other. other sand traps (7) GMOs (6) KOS (3), in which, under the action of gravity carry out the extraction (from GWS) and deposition (in the lower parts of sand traps under the action of gravity): all - 100%, KDVV, a small part - less than 50%, ADV and the minimum part - less than 5%, TDVV .

In the future: wastewater (CB), containing a significant part - more than 50%, almost all - more than 95%, TDVV and all - 100%, BB, sent by several - at least two (by the number of sand traps), identical to each other first conduits (8) for the dry water in PDMOV (11) - for further purification; sediment containing mainly KDVV is directed along several - at least two identical first pipelines (9) of GMO sediment (6) to the main pipeline (10) of CBS (3) sediment.

In parallel several functionally connected at least two (according to the number of sand traps) identical settling tanks (12) of coarse purification of ST DMS (11) identical to each other under the action of gravity carry out extraction (from ST) and sedimentation (under the action of force gravity) parts of explosives. Further: CBs are sent along several second conduits (13) of CB, which are identical with each other, to VDMA (15) -for further purification; the sludge containing predominantly ADHD is sent along several second pipelines (14) of the substation DITCH (11) identical to each other (11) to the main pipeline (10) of the WWTP sludge (3).

However, significant parts of the ADL, almost all TDWS and all BBs can remain in the NE.

To minimize this negative phenomenon in PDMOV (11), the first hydroacoustic (PHAM) water purification module (40) is used, in which with the help of the functionally connected first multichannel generator (41), first multichannel power amplifier (42) and first multichannel matching device (43) provide formation, amplification and transmission (practically without energy loss) through several first signal cable cables (44) to several first non-directional hydroacoustic emitters (45) attached and means of several first wires (46) to the first several buoyancy (47) of sonar signals and ZDCH UZDCH F _1.

As a result, in each settling tank (12) the coarse cleaning of the ST PDMOV (6) KOS (3) under the influence of the hydroacoustic wave (GAV) of the HDC and UZDCh at the frequency F ₁ (hereinafter referred to as GAV F ₁ ) with an amplitude of acoustic pressure of at least 10 ⁴ Pa at a distance of 1 m from the working surface of the corresponding hydroacoustic emitter carry out: acoustic (non-reagent) coagulation of the SDVV and TDVV between themselves and with the BB in the entire working volume of the corresponding sump (12), in which the FIR F ₁ spreads; acoustic (forced - additional to the force of gravity) deposition of the initial and previously acoustically coagulated explosives - in the sectors of directional (towards the bottom) propagation of HAV F ₁ ; acoustic compaction (due to forced displacement of sludge particles) of sediment - in the propagation sectors (including as a result of rereflection, diffraction, etc.) of the SAW F ₁ .

At the same time, under the influence of hydrogen peroxide and OH ° radicals, which are formed during the dissociation of water molecules in cavitation formations, physical destruction (bactericidal action) of an insignificant part — less than 25% —BB found in water within a radius of 2 m from the working surface corresponding sonar transmitter (45).

Subsequently, almost completely (more than 95%) purified from ADHB, insignificantly (less than 50%) purified from TDVV and insignificantly (less than 25%) purified from BB (decontaminated) CB are sent as already noted above, along several second conduits (13) SV in VDMOV (15) - for further purification (including from dissolved impurities); the sludge containing predominantly ADHD is sent along several second pipelines (14) of the substation DITCH (11) identical to each other (11) to the main pipeline (10) of the WWTP sludge (3).

Then, in parallel: several at least two (to ensure continuous operation of one aeration tank during the maintenance of the other), aerotanks identical to each other (16) of the WIDWS (15) carry out biological treatment (in the traditional way) by using special (CMS) microorganisms (microorganisms that consume oxygen in the process of biological treatment of CB). As a result, under the action of the SMO, the explosives are extracted (from the NE) and deposited (in the lower parts of these aerotanks under the action of gravity).

Further: CB is sent along several third lines to each other (17) CB in TDMOV (19) - for further purification; the sludge containing predominantly TDVV is sent along several third pipelines (18) of the VDMA sludge (15) identical to each other (15) to the main pipeline (10) of the KOS sludge (3).

However, a significant part of the TDVV and a significant part of the BB can remain in the NE.

In addition, due to the processes: swelling (arising due to the low capacity of activated sludge to sedimentation), foaming and ascent (due to the attachment of gas bubbles to the agglomerations of pops of activated sludge) of activated sludge, the eventually (due to the increased turbidity of water) will lead to a significant deterioration in the quality of water disinfection with ultraviolet light. Moreover, for the above three reasons, there may be situations of direct removal of activated sludge to the surface of the water in the septic tanks of fine water purification. In this case, the turbidity of the turbine increases many times and, as a result, the quality of the disinfection of the turbine deteriorates many times. Moreover, situations involving the direct discharge of activated sludge directly into water bodies (natural watercourses — rivers) are possible.

To minimize, or even completely eliminate these negative phenomena in TDMOV (19), a second hydroacoustic (HGAM) water purification module (48) is used, in which using sequentially functionally connected: the second multichannel generator (49), the second multichannel power amplifier (50 ) and the second multi-channel matching device (51) provide for the formation, amplification and transmission (almost without energy loss) along several second signal cables (52) to several second non-directional sonar and recipients (53) attached by means of a plurality of second cables (54) to several second buoyancy (55) of sonar signals ZDCH UZDCH and F _2.

As a result, in each settling tank (20) of fine cleaning of the SV TDMOV 19) CBS (3) under the influence of the HHR HRC and UZDCh at the frequency F ₂ (hereinafter referred to as HAR F ₂ ) with an amplitude of acoustic pressure of at least 10 ⁴ Pa at 1 m from the working surface of the corresponding hydroacoustic emitter carry out: acoustic (non-reagent) coagulation of the TDBB between themselves and with the BB - in the entire working volume of the corresponding sump (20), in which the FIR F ₂ spreads; acoustic deposition of the initial and previously acoustically coagulated explosives - in the sectors of the directional (towards the bottom) propagation of the HAV F ₂ ; acoustic compaction of sediment - in the sectors of distribution in the lower layer of water and sediment WOOF F ₂ .

In addition, in each settling tank (20) of fine cleaning of SV TDMOV 19) CBS (3) under the influence of HAV F ₂ with an acoustic pressure amplitude of at least 10 ⁴ Pa at a distance of 1 m from the working surface of the corresponding hydroacoustic emitter: acoustic degassing of the three-phase medium ( water, mechanical and biological impurities, as well as gas inclusions) in the corresponding settling basin (20), acoustic coagulation of sludge claps (active - live and passive - dead) - in the whole working volume of the corresponding settling tank (20) tranyaetsya HAV F _2; acoustic sedimentation of sludge in the sectors of directional propagation of HAV F ₂ ; acoustic compaction of sludge (including sludge) in the distribution sectors in the lower layer of water and sediment.

At the same time, under the influence of hydrogen peroxide and OH ° radicals, which are formed during the dissociation of water molecules in cavitation formations, a significant part of more than 50% is physically destroyed, BB in the water within a radius of 2 m from the working surface of the corresponding sonar transmitter 53).

Further: CBs are sent along several fourth conduits (21) CB, identical to each other, in the SPSS (23) - for further purification from the BB (for disinfection); a sludge containing mainly TDVV is sent through several fourth pipes identical to each other (22) of the TDMOV sludge (12) to the main pipeline (10) of the KOS sludge (3).

In the SPSS (23), the disinfected (cleaned from the BB) CB in the separator (24) of the disinfected CB are divided into several - at least four, streams of disinfected CB and sent to several - at least four, transparent to each other - for ultraviolet light, water lines ( 25), in which the standard (for the ultraviolet method) method performs disinfection of previously cleaned (from MP and BP - in the form of explosives of different dispersion and in the form of solutions) ST.

Subsequently, in the combiner (26), purified and disinfected CBs are combined into one stream and through the main conduit (27) for purified and disinfected CB, which is the output of the CBS (3) SS (23), using a pump (28) for purified and disinfected CB , transported to a natural watercourse (for example, to a river) and dumped into it.

At the same time, the precipitate transports the precipitate by means of a pump (30) for transporting the sludge via the main pipeline (10) of the sludge to transport the sludge to the sludge separator (31) for the sludge ) of several - at least three, sludge beds (32).

With the help of gravity, sediment separation is carried out: to the solid fraction and to the liquid fraction. Subsequently, the liquid fraction in the form of drainage water is discharged through several - at least three drainage pipes (33) and sent to the drainage combiner (34). Then all the drainage water, using a pump (36) for drainage water, through the first drainage water pipeline (35) and through the second drainage water pipeline (37), is sent to the second inlet of the distributor (4) of the WWTP KOS (3).

Then, after a complete drainage water removal, from this sludge platform (32), using the first movable module (36) - an excavator, the sludge is dried (solid sediment fraction) and loaded into one of several - at least two, second movable modules (37) - dump trucks, for transportation to the place of processing (for example, for fertilizers) or to the place of disposal.

However, the sediment located on the filled sludge platform contains not only the liquid and solid fraction, but also gas inclusions that prevent: gravitational compaction of the sediment - in the lower part of the sludge platform (due to the loose structure of the sediment); gravitational dewatering of sediment - in the entire volume of the sludge bed (due to unconsolidated sediment and due to poor dehumidification); natural moisture transfer (due to the crust formed by gas inclusions on the surface of the sludge bed) - in the upper part of the sludge bed.

To minimize, or even to completely eliminate these negative phenomena, a third hydroacoustic (TGAM) module (56) is used in the VSPS (29), in which, using sequentially functionally connected: the third multi-channel generator (57), the third multi-channel power amplifier (58) and The third multi-channel matching device (59) provides for the formation, amplification and transmission (almost without energy loss) of several third signal cables (60) to several - at least three, third non-directional acoustic signals emitters (61) attached with several third cables (62) to several third buoyancy (63), hydroacoustic signals of HRC and AFC F ₃ with an amplitude of acoustic pressure of at least 10 ⁴ Pa at a distance of 1 m from the working surface of the corresponding hydroacoustic radiator.

As a result, in the corresponding silt site (32) of the VSPS (29) of the WWTP (3), under the influence of the HHF HRC and UGDU, at a frequency F ₃ with an amplitude of acoustic pressure of at least 10 ⁴ Pa at a distance of 1 m from the working surface of the corresponding hydroacoustic emitter: acoustic (non-reagent) coagulation of explosives between themselves, with BB, and with claps of sludge (active - live and passive - dead) - in the whole working volume of the corresponding sludge bed (32), in which the FIR F _{2 is} distributed; acoustic deposition of baseline and previously acoustically coagulated explosives (including those with BB and slam slam) in the directional (bottom) propagation sectors of the HAW F ₃ ; acoustic compaction of sediment - in the propagation sectors in the lower layer of the corresponding sludge bed of the GAV F ₃ ; acoustic degassing of a three-phase medium (moisture-saturated sediment and gas inclusions); acoustic destruction of the surface gas crust, which impedes moisture transfer.

At the same time, under the influence of hydrogen peroxide and OH ° radicals, which are formed during the dissociation of water molecules in cavitation formations, as well as under the influence of alternating acoustic pressure, BB is destroyed in the drainage water and sediment. Wherein:

1. Quality - up to the requirements of environmental legislation (for example, up to the requirements of the maximum permissible concentration of _fish . _Households ), the purification of dry matter and dewatering of sediment is ensured by the fact that:

- cleanup SV (from MP, BP and BB) is carried out at five stages (in GMOV, PDMO, VDMO, TDMO and in PSPS);

- carry out acoustic - a direct effect, as well as acoustic-sorption (due to the physicochemical properties of natural sorbents - MP and BP) and electric (electromotive force on the body and around the radiator body - a consequence of electrical energy conversion - the voltage applied to the hydroacoustic radiator reaches 1000 V and more)

- associated effects, coagulation of explosives (with each other and with BB) at three stages (in PDMOV, TDMOV and VSPS);

- carry out acoustic (at three stages - in PDMOV, TDMOV and VSPS) and acoustic-gravitational (at four stages - in PDMOV, VDMOV, TDMOV and VSPS) deposition of initial explosives and previously acoustically coagulated explosives;

- carry out acoustic compaction of sediment in three stages (in PDMOV, TD MOV and VPSS);

- carry out acoustic disinfection of water in three stages (in PDMOV, TDMOV and VPSS);

- carry out ultraviolet disinfection of water in the block ultraviolet disinfection of water;

- carry out acoustic disinfection of water in three stages (in PDMOV, TDMOV and VPSS);

- carry out acoustic degassing of water in three stages (in PDMOV, TDMOV and VPSS);

- carry out the acoustic destruction of the surface bubble layers (floating gas bubbles with impurities on their outer shells) in the sludge beds of the SPEC;

- carry out periodic (as necessary) removal of sediment from GMOV, PDMOV, VDMOV, TDMOV and VSPS);

- carry out regular transportation of dewatered sludge from KOS (for direct use, for processing or for disposal), etc.

2. Physical - without the use of chemical reagents, purification of dry matter and dewatering of the sludge is ensured by:

- do not use chemical reagents for coagulation of explosives, for compaction and dehydration of sludge;

- do not use chemical preparations for the disinfection of SV and sediment;

- use acoustic, acoustic sorption and electrical coagulation of explosives between themselves, as well as with BB;

- use of acoustic deposition of the original and previously acoustically coagulated explosives between themselves, as well as with BB;

- use of gravitational deposition of previously acoustically coagulated explosives with BB;

- use acoustic disinfection - for pre-disinfection of CB and sediment;

- use ultraviolet irradiation for the final disinfection of CB;

- use acoustic compaction of sediment, etc.

3. Purification of large (up to 3000 m ³ / h and more) volumes of dry matter and sludge dewatering is ensured by:

- cleaning CB carried out in several stages;

- at the same time implement several different physical mechanisms of coagulation of explosives between themselves and with BB (acoustic, acoustic-sorption, electric);

- simultaneously implement several different physical mechanisms (acoustic, acoustic-gravity) deposition of the original and previously acoustically coagulated explosives;

- carry out acoustic compaction of the sediment;

- carry out periodic (as necessary) removal of sediment;

- carry out regular transportation of sludge from KOS, etc.

4. The relative simplicity of the method of reagent-free purification of SV and sludge dewatering is ensured by:

- the formation and emission of hydroacoustic waves of HSC and UZDCh are carried out with the help of mass-produced electronic devices, as well as hydroacoustic emitters (including those removed from service, which contributes to the conversion of enterprises of the military-industrial complex);

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

- control of the operation of the device implementing the developed method is carried out automatically and semi-automatically (without the constant presence of the attendants);

- equipment maintenance is carried out with great discreteness (once every 7 days) and directly during the operation of the sewage treatment plant, therefore no special time is required for maintenance of the device, etc.

5. Minimum financial and time costs during the cleaning of dry mud and sludge dewatering are ensured due to the fact that:

- exclude the consumption of expensive chemical reagents (for cleaning CB);

- exclude the consumption of expensive chemicals (for disinfection of dry matter and sediment);

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

- cleaning CB carried out in several stages;

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

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

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

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

6. The possibility of implementing the method in any weather and climatic conditions (for example, in the process of wind waves on the settling tanks, during the freezing-up period, etc.) and in any working conditions (for example, in the process of abrupt changes in the consumption of dry matter during the day and so on. d.) provide due to the fact that:

- use modules for cleaning of SV and for sludge dewatering;

- the formation and emission of hydroacoustic waves is carried out with the help of commercially available electronic and acoustic devices capable of functioning under any climatic conditions;

- carry out the compaction of sediment in PDMOV and TDMOV, which excludes its removal to the surface of the settling tanks in the process of wind waves;

- carry out the compaction of the sediment in PDMOV, TDMOV and VSPS, which contributes to an increase in their working volumes and, ultimately, improves the performance of cleaning the SV and sludge dewatering;

- at the same time implement several different physical mechanisms of coagulation of explosives between themselves and with BB;

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

- carry out periodic (as necessary) removal of sediment;

- carry out regular transportation of sludge from KOS, etc.

7. Medical safety for a person during the non-reagent treatment of dry matter and sludge dewatering is ensured due to the fact that:

- exclude the consumption of expensive chemical reagents (for cleaning CB);

- exclude the consumption of expensive chemicals (for disinfection of dry matter and sediment);

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

- control of the operation of the device implementing the developed method is carried out automatically and semi-automatically (without the constant presence of the attendants);

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

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

- control of the operation of the device implementing the developed method is carried out automatically and semi-automatically (without the constant presence of the attendants);

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

8. Ecological safety for OPS during purification of dry matter and dewatering of sludge is ensured by the fact that:

- exclude the consumption of expensive chemical reagents (for cleaning CB);

- exclude the consumption of expensive chemicals (for disinfection of dry matter and sediment);

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

- control of the operation of the device implementing the developed method is carried out automatically and semi-automatically (without the constant presence of the attendants);

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

Distinctive features of the proposed method are:

1. As GMOs, several - at least two identical sand traps are used.

2. As PDMOV use several - at least two, identical to each other septic tanks of rough water purification (primary septic tanks).

3. As VDMOV use several - at least two identical aero tanks.

3. As TDMOV use several - at least two identical clarifiers for water purification (secondary clarifiers), identical to each other.

4. As the SPSU use a block of ultraviolet disinfection of water.

5. As VSPS use several - at least three, sludge beds.

6. Radiation BGAV HSC and UZDCH carried out with an amplitude of acoustic pressure of at least 10 ⁴ Pa at a distance of 1 m from the working surface of the corresponding sonar emitter.

7. Additionally, in PDMOV, TDMOV and VSPS, acoustic (forced - additional to the force of gravity) deposition of initial and previously acoustically coagulated impurities (MP, BP, BB, etc.) is carried out.

8. Additionally, acoustic sludge compaction is performed in PDMOV and TDMOV.

9. Additionally, in TDMOV carry out acoustic degassing of water.

10. Additionally, in TDMOV and VSPS, acoustic sedimentation is carried out.

11. Additionally, in the VSPS, the acoustic decontamination of the sediment and the acoustic decontamination of water separated from the sediment in the process of its dehydration (drainage water) are carried out.

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

Analysis of the known technical solutions in order to detect the indicated distinguishing features in them showed the following.

Signs: 10 and 11 are new and their use is unknown for the non-reagent treatment of ST and sludge dewatering.

Signs: 6, 7, 8, and 9 are new and their use is unknown for non-reagent ST treatment and sludge dewatering.

At the same time, it is well known: for feature 6, the use of the BGAV ESC and UZDC with an amplitude of acoustic pressure of at least 10 ⁴ Pa at a distance of 1 m from the working surface of the corresponding sonar radiator in naval activities, industrial fishing, etc .; for feature 7, the use of acoustic waves for acoustic coagulation of impurities in air and in water; for feature 8, the use of acoustic cavitation for water degassing.

Symptoms: 1-5 are known.

Thus, the presence of new essential features, in conjunction with the known ones, ensures that the proposed solution introduces a new property that does not coincide with the properties of the known technical solutions - qualitatively - up to the requirements of environmental protection legislation, physically - without the use of chemical reagents, clean the CB (MP, BP and BB) large (for example, when the consumption of dry matter is up to 300 m ³ / hour and more) volumes of contaminated wastewaters with simultaneous sludge dewatering, in a relatively simple way with minimal time and money, in any weather and climatic conditions and in any working conditions with the provision of medical safety for humans and environmental safety for OPS, in general.

In this case, we have a new set of features and their new interrelation, and not just a combination of new features and those already known, namely, the performance of operations in the proposed sequence leads to a qualitatively new effect. This circumstance allows to make a conclusion about the compliance of the developed method with the criterion of "significant differences".

An example implementation of the method.

Industrial tests of the developed method were carried out: in the period 2002-2006 - on industrial sites of Koryakgeoldobycha CJSC, located in the valleys of spawning rivers: Levtyrinivam, Vetviy and Vyvenka (RF, Kamchatka Peninsula); in 2006-2008 - at water treatment plants in the Republic of Korea; in 2008-2010 - at water treatment plants in the Republic of Vietnam; in 2013-2018 - on the industrial site of PJSC «Someramaz», located in the valley of the spawning river Zolotitsa (RF, Arkhangelsk region); in 2016-2018 - on KOS water treatment enterprises in the Astrakhan and Arkhangelsk regions (RF).

FIG. 6 of FIG. 11 illustrates the results of tests of the developed method of non-reagent cleaning of dry deposits and sludge dewatering.

In this case: in FIG. 6 presents the results of the non-reagent purification of CB from explosives for the prototype method (histograms highlighted by a dotted line) and for the developed method (histograms marked with a solid line), respectively. The indices: I, II, II and IV in FIG. 6 denotes the average content (SS) of the explosives (mg / l) in the DM, respectively, at the exits from: GMOV, PDMOV, VDMOV and TDMOV.

As can be seen from FIG. 6 in the process of implementation of the developed method of SS BB explosives (SS, mg / l) in the CB at the exits from PDMOV (rough settling tanks of CB with PAM), from VDMOV (aerotanks) and from TDMOV (settling tanks of fine purification of CB with YOU) were sequentially reduced with 88.7 mg / l to: 24.1 mg / l, 12.1 mg / l and 3.1 mg / l (total cleaning efficiency 96.5%). While in the process of implementation of the prototype method SS BB (SS, mg / l) in the CB, it was successively reduced from 88.7 mg / l to: 45.5 mg / l, 27.3 mg / l and 9.9 mg / l (total cleaning efficiency 88.8%). That is, the effect of the developed method was 6.8 mg / l (9.9 mg / l - 3.1 mg / l), or 7.7% (99.5% -88.7%), and the quality of CB fully complied with the requirements (5 , 0 mg / l) MAC of _{fish ryg.}

FIG. 7 illustrates graphs of SS BB explosives (SS, mg / l) in the CB at the exits from the TDMOV for 30 days in the process of implementing the developed method (solid line) and the prototype method (dashed line).

As can be seen from FIG. 7 in the process of implementation of the developed method SS BB explosives (SS, mg / l) in the CB at the exits from TDMOV (settling tanks for fine purification of CB with BAM) for 30 days of industrial testing was: 3.1 mg / l for the developed method and 9, 9 mg / l for the prototype method. That is, the effect of the developed method was 6.8 mg / l (9.9 mg / l-3.1 mg / l), or 7.7% (99.5% -88.7%). In the process of implementing the prototype method, within 30 days, three cases (No. 1, No. 2 and No. 3 in Fig. 7) were recorded for removal of sludge from the bottom layer of the sedimentation tank of fine water purification to its surface. As a result, the CC of the BB in these three days was: 161.0 mg / l (exceeding 16.2 times the CC of the BB), 181.0 mg / l (exceeding 18.2 times the CC of the BB) and 173.0 mg / l (17.4 times excess of SS BB).

FIG. 8 presents the results of non-reagent (hydroacoustic) cleaning of CB from BB at the outputs of TDMOV for indicators of CB disinfection quality: “TBC of CFU in 1 ml” (histograms with index I) and “OKB of CFU in 100 ml” (histograms with index II) - for the developed method (histogram with a solid line) and for the prototype method (histogram with a dotted line). As can be seen from FIG. 8: the quality indicator "TBC CFU in 1 ml" for the prototype method was 73.0, while for the developed method it was 44.0 - the particular efficiency of the developed method was 39.7%; the quality indicator "OKB CFU in 100 ml" for the prototype method was 12.0, while for the developed method it was 0.0 - the private efficiency of the developed method was 100%.

FIG. 9 presents empirical data characterizing the effectiveness of ultraviolet disinfection of CB, depending on their turbidity (explosive content in CB - SS). In this case: asterisks indicate the conditional limits of the permissible efficiency of the ultraviolet CB disinfection method (disinfection efficiency 75% at CC BB in CB 18 mg / l, disinfection efficiency 100% with CC BB in CB 3 mg / l): dots indicate CC BB at the exit from VDMOV for the developed method - 3.1 mg / l and for the prototype method - 9.9 mg / l. As can be seen from FIG. 9, based on empirical data, the particular efficiency of ultraviolet disinfection of CBs was: 92% for the prototype method and 99% for the developed method. That is, the private efficiency of the developed method was 7%.

In this case: in FIG. 10 presents the results of compaction of the precipitate in PDMOV for the prototype method (histogram highlighted by a dotted line) and for the developed method (histogram highlighted by a solid line), respectively. As can be seen from FIG. 10 density (P) of sediment (histograms with index I) in the process of implementing the developed method amounted to 2.17 t / m ³ , while for the prototype method it was 1.25 t / m ³ . That is, the private efficiency of the developed method was 0.92 t / m ³ , or 43.4%.

In this case: in FIG. 11 shows the results of sludge dewatering in the VSPS for the prototype method (histogram highlighted by a dotted line) and for the developed method (histogram highlighted by a solid line), respectively. As can be seen from FIG. 11, the relative humidity (W,%) of the sediment (histograms with index I) in the process of implementing the developed method was 28.8%, while for the prototype method it was 53.0%. That is, the private efficiency of the developed method was 24.2% (53.0% .- 28.8%). In this way:

1. High-quality purification of SV and sludge dewatering was provided due to the fact that:

- cleaning SV carried out in five stages;

- carried out acoustic, acoustic sorption and electric coagulation of explosives (with each other and with BB) in three stages;

- carried out acoustic and acoustic-gravity precipitation of the original explosives and previously acoustically coagulated explosives;

- carried out acoustic compaction of sediment in three stages;

- carried out acoustic disinfection of water in three stages;

- carried out the ultraviolet disinfection of water in the block ultraviolet disinfection of water;

- carried out acoustic disinfection of water in three stages;

- carried out the acoustic degassing of water in three stages;

- carried out the acoustic destruction of the surface of the bubble layers in the silt pods of the high-voltage vertical;

- carried out periodic removal of sediment;

- carried out the regular transportation of dehydrated sludge, etc.

2. Physical purification of dry matter and sludge dewatering was provided due to the fact that:

- did not use chemical reagents for coagulation of explosives, for compaction and dehydration of the sediment;

- did not use chemical preparations for the disinfection of CB and sediment;

- used acoustic, acoustic sorption and electrical coagulation of explosives between themselves, as well as with BB;

- used the acoustic deposition of the original and previously acoustically coagulated explosives between themselves, as well as with BB;

- used the gravitational deposition of previously acoustically coagulated explosives with BB;

- used acoustic disinfection - for preliminary disinfection of CB and sediment;

- used ultraviolet irradiation for the final disinfection of SV;

- used acoustic compaction of sediment, etc.

3. Purification of large volumes of SV and sludge dewatering was provided due to the fact that:

- cleaning CB was carried out in several stages;

- simultaneously implemented several different physical mechanisms of coagulation of explosives among themselves and with BB;

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

- carried out acoustic compaction of the sediment;

- carried out periodic (as required) removal of sediment;

- carried out regular transportation of sediment from the WWTP, etc.

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

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

- the formation and emission of ultraviolet light was carried out using commercially available devices;

- the operation of the device that implements the developed method was controlled automatically and semi-automatically;

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

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

- eliminated the consumption of expensive chemicals (for cleaning CB);

- eliminated the consumption of expensive chemicals (for disinfection of dry matter and sediment);

- reduced (by at least 30%) the area of land allotted for the construction of WWTP;

- cleaning CB was carried out in several stages;

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

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

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

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

6. The ability to implement the method in any climatic and production conditions provided due to the fact that:

- used the modules for cleaning the SV and for sludge dewatering;

- the formation and emission of hydroacoustic waves was carried out using commercially available electronic and acoustic devices capable of functioning under any climatic conditions;

- carried out the compaction of sediment in PDMOV and TDMOV, which excluded its removal to the surface of the settling tanks in the process of wind waves;

- carried out the compaction of the sediment in PDMOV, TDMOV and VSPS, which contributed to the increase in their working volumes and, ultimately, allowed to increase the productivity of the treatment of ST and sludge dewatering;

- simultaneously implemented several different physical mechanisms of coagulation of explosives among themselves and with BB;

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

- carried out periodic (as required) removal of sediment;

- carried out regular transportation of sediment from the WWTP, etc.

7. Medical safety for a person during the non-reagent treatment of dry matter and sludge dewatering was ensured due to the fact that:

- eliminated the consumption of expensive chemicals (for cleaning CB);

- eliminated the consumption of expensive chemicals (for disinfection of dry matter and sediment);

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

- control of the operation of the device implementing the developed method was carried out automatically and semi-automatically (without the constant presence of the attendants);

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

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

- control of the operation of the device implementing the developed method was carried out automatically and semi-automatically (without the constant presence of the attendants);

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

8. Ecological safety for fire and dust treatment plants during the purification of dry matter and sludge dewatering was ensured due to the fact that:

- eliminated the consumption of expensive chemicals (for cleaning CB);

- eliminated the consumption of expensive chemicals (for disinfection of dry matter and sediment);

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

- control of the operation of the device implementing the developed method was carried out automatically and semi-automatically (without the constant presence of the attendants);

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

Claims (1)

The method of reagent-free wastewater treatment and sludge dewatering, which consists in cleaning from coarse and medium-dispersed suspended substances in the main water purification module, in cleaning from coarse, medium-dispersed, finely dispersed suspended solids and pathogenic bacteria in the first additional water purification module — by emitting hydrographic dispersed particles and disease-causing bacteria in the first additional water treatment module — by radiating dispersed water solids and pathogenic bacteria. and ultrasonic frequency ranges, in cleaning from medium-dispersed, finely dispersed suspended substances and pathogenic bacteria in the second water purification module, in purification from medium-dispersed, finely dispersed suspended substances and pathogenic bacteria in the third additional water purification module — by emitting traveling acoustic waves of the sound and ultrasonic frequency ranges, in purifying from pathogenic bacteria — in the first special structure, in dewatering sludge the second special structure, in the transportation of dehydrated sludge, characterized in that several, at least two, ident sand traps, which are identical to each other, in which they are completely cleaned from coarse suspended solids and significantly cleaned from moderately suspended particulate matter - by using the force of gravity, as the first additional water purification module they use several, at least two identical coarse water purification tanks which carry out almost complete purification from medium-dispersed suspended substances, insignificant purification from fine suspended substances and insignificant purification from bo eznetvornyh bacteria - by radiation traveling hydroacoustic waves of sonic and ultrasonic frequency ranges from the acoustic pressure amplitude is not less than 10 ⁴ Pa at a distance of 1 m from the working surface corresponding sonar emitter, as a second additional water cleaning unit is used more, at least two, identical to each other aeration tanks, in which they carry out full purification from medium-dispersed suspended substances, substantial purification from finely dispersed suspended substances, insignificant purification from pathogenic bacteria and complete purification from soluble impurities through the use of special microorganisms in the process of biological wastewater treatment, as the third additional module use several, at least two identical water clarification settlers, which carry out almost complete purification from fine dispersed suspended solids and significant clearance of pathogenic bacteria - by irradiating traveling sonar acoustic and ultrasonic waves with an acoustic pressure amplitude of at least 10 ⁴ Pa at a distance of 1 m from the working surface of the corresponding sonar emitter, a UV disinfection unit for water is used as the first special facility, in which water is disinfected — by irradiating it with ultraviolet light; , at least three mutually identical sludge beds in which sludge dewatering is carried out - by radiation of hydroacoustic their 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 working surface of the corresponding sonar transmitter, additionally in the second special structure, acoustic decontamination of the sludge and acoustic decontamination of water separated from the sludge is performed during dewatering.

Images