RU2431610C2 - Compound method for reagentless treatment of waste water and briquetting sludge - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: compound method for reagentless treatment of waste water and briquetting sludge comprises two steps. The following operations are performed at the first step: distributed discharge of water into the receiving section of a settling tank in which suspended particles and immiscible liquids are separated according to density which is higher or lower than density of water, suspended particles and immiscible liquids with density higher than density of water accumulate and are held at the bottom of the settling tank; intense deposition of suspended particles and immiscible liquids with density higher than density of water at the bottom of the settling tank in the next sections; physical-electrical treatment in order to intensify deposition of dirt in series-arranged clarification tank lying on the length of the settling tank with mechanical offloading of the deposited sludge with a drag drainage conveyor into a mixture, where binder, filler and a neutraliser are added, and the sludge is stirred and pressed, and the obtained briquettes are disinfected in microwave ovens. The second step, which is realised using series-arranged devices, involves additional physical-electrical treatment of water, deposition of suspended particles, aeration and ozonation of water, collection of the sludge deposited in the devices, and said sludge is sent to the disinfection part of the drag conveyor.

EFFECT: method increases efficiency of treating waste water.

12 cl, 1 dwg

Description

The invention relates to methods for reagent-free wastewater treatment and can be used in various industries.

Known water treatment complex [1], which contains sequentially interconnected receiving chamber, gratings, sand traps, primary sumps, aeration tank, secondary sumps, aerated bioreactor tanks with ruff loading, a pond system containing a pond of the 1st cleaning stage, pond 2- 1st stage of cleaning and a pond of the 3rd stage of cleaning, a mechanical cleaning device, an ultraviolet irradiation station (UV) and a pumping station. From the receiving chamber to the pumping station, sewage flows by gravity. The water treatment complex also contains a sludge tank and a mechanical sludge dewatering workshop, connected to the sand traps by a pipeline, a pipeline for supplying excess sludge from the pond of the 1st cleaning stage and a pond of the 2nd cleaning pipeline to the receiving chamber, a pipeline for feeding return activated sludge from the secondary settling tanks into the aeration tank and the pipeline for supplying excess sludge to the receiving chamber from the secondary settling tanks. Through the line, air from the compressor enters the aeration tank.

The disadvantages of the complex are complex mechanized unloading of sludge, the need to dry sludge, and ultraviolet lamps poorly disinfect muddy water.

Known block modular treatment plant [2], including multi-stage biological wastewater treatment tanks by microorganism communities attached to a fiber brush nozzle and consisting of free-floating activated sludge, sludge traps and sludge sealers, dewatering sewage sludge devices, communication systems for supplying and discharging sewage water, air supply, removal of accumulated sediments, floor layout of tanks, equipment and premises for work and stay a sewage treatment plant, characterized in that it is made in the form of a building of at least four-story, tower type with a separate arrangement of bioreactors, equipped with blowers located on the lower floor, connected by suction pipelines with a ventilation chamber passing from top to bottom through all floors of the treatment plant premises and equipped with floor ventilation ducts, equipped with fans from the premises of the bioreactors to remove the exhaust air from the bioreactors outside the sewage treatment plant through it and the disinfecting device are equipped with biocomposters for processing into biocompost dehydrated sewage sludge, ripening and drying by using the heat of the air heated in the blowers.

The disadvantages of the complete block modular treatment plant of the complex are the complex mechanized unloading of sludge and the need for its drying.

A known system for wastewater treatment [3], comprising a pump for supplying wastewater through a pipe to a vertical pipe, a blower, a pipe for supplying activated sludge; a lifting pipeline, a primary tank, then a pipe, a rain spray, a pressure pipe, a secondary tank, a pipe and an aeration tank, a pipe and a container for discharging and collecting waste, characterized in that an additional device for removing mechanical impurities is additionally introduced to improve the quality of wastewater treatment.

Wastewater initially enters the device for removing mechanical impurities through the cartridge into the annulus and through the windows into the conical part and then through the slit section formed by the conical part of the pipe and the container, and after flowing around the container, it is sent to the region of rarefaction and vortex flows above the container, which are formed due to a sharp change in the area of the bore, as a result of which mechanical and other heavy impurities due to the action of gravitational forces fall into the tank, from which lyayutsya in waste collection.

The disadvantages of the wastewater treatment system are complex mechanized unloading of sludge, there are no further waste processing operations.

A known method of wastewater treatment [4], which consists in preliminary purification in the reactor of a coagulation active iron-containing precipitate of galvanic coagulant pulp obtained by subsequent wastewater treatment and a flocculant, further settling of pre-treated wastewater in a sump and subsequent purification of their clarified part in a galvanic coagulator with loading iron and coke. Deep treatment of wastewater is carried out by a series of sludge accumulator and filter press, the galvanic coagulator sludge output through a ferritor reactor is connected to a pretreatment reactor, and air supply lines are connected to the pretreatment reactor and ferritor reactor. EFFECT: reduced salinity of treated effluents to the level of water quality of recycled water supply and production of a truly utilized sludge during wastewater treatment.

The disadvantages of wastewater treatment are water treatment with chemical flocculants and coagulants, which leads to their pollution of purified water and the difficulty of their collection, the cost of chemicals.

A known method of water purification and a device for its implementation [5], which consists in the action of an electric current and a constant electric field on the volume of the processed fluid and the gas layer located above it. Moreover, a constant electric field is created with a pulsed nature of the change in current density, as a result, then transported to the processed fluid. The transport time of this mixture should be less than the time to establish a stationary concentration of radicals. Then, the ozone-hydroxyl mixture is mixed with the liquid to be treated and the mixture is saturated with air in a volume ratio of air / liquid of more than 1/1. A device for implementing the method consists of a reactor, an ejector pump and a mixer, equipped with connecting pipes. EFFECT: increased efficiency of water purification.

A known method of purification of natural and waste water [6], which includes filtering contaminated liquid through a non-uniform dispersed filter material placed in an alternating electric field and consisting of two or more components, one of which has an electrical conductivity, characterized in that it is introduced into the filter load metal conductive inclusions in the form of sawdust with a hydraulic particle size equal to the hydraulic particle size of the filter media.

A device for the treatment of natural and wastewater, consisting of a cylindrical body with semi-ring insoluble electrodes located in it, connected to a constant current source, supporting layer and filter load in the interelectrode space, drainage funnel, source, technical, washing and purified water pipelines, characterized the fact that it is additionally equipped with a drainage funnel for receiving and removing washing water, an ejector and a container for metal inclusions, are introduced in the filter load.

A known method of wastewater treatment with intensification of oxygen saturation and a device for its implementation [7], which are characterized in that a vertical pipe is installed on the bottom of the tank with a gap, equipped with a pipe for supplying wastewater, a vertical biological charge located in the center of the pipe, and installed with the possibility of moving along the pipe with a fine-bubble aerator, the air into which is supplied pulsed, while the tank is equipped with at least two pairs of airlifts that pump water from the tank into three boo, and the outlet pipes of the airlifts are placed tangentially along the inner perimeter of the pipe, the aerator is installed in the upper zone of the pipe, all airlifts are turned on, and the total performance of the airlifts is selected from the condition that the speed of movement of the overflowed water is greater than the speed of movement of the bubbles, as a result of which air bubbles move way down.

The method is characterized in that a vertical pipe is installed on the bottom of the tank with a gap, equipped with a pipe for supplying wastewater, a vertical sludge loading located in the center of the pipe and installed with the possibility of displacement along the pipe with a fine bubble aerator, into which air is supplied pulsed, while the tank supply at least two pairs of airlifts that pump water from the tank into the pipe, and the outlet pipes of the airlifts are placed tangentially along the inner perimeter of the pipe, the aerator is installed in the bottom it pipe zone in operation include a pair of airlifts and overall performance airlifts are selected from the condition that the overflow water flow rate is less than the speed of movement of bubbles, thereby allowing slow movement of the air bubbles upwards.

A device characterized in that a vertical pipe is installed in the tank with a gap relative to the bottom, equipped with a nozzle for supplying wastewater, and inside the center of the pipe are a biological load and a fine bubble aerator installed with the ability to move and fix in the installed position, while the tank is equipped at least two pairs of elevators, the outlet pipes of which are located tangentially along the inner perimeter of the pipe, and overflow pipelines located at different levels s connecting the tank to a sump provided with an aerator, the recirculation sludge pump and an outlet valve for the exit of purified water, and the overflow conduits are provided with locking valves interconnected.

The device is equipped with a control unit interacting with each other, a compressor, a switching valve, a distributor with a regulator.

A known method of wastewater treatment and a device for its implementation [8], which is intended for wastewater treatment, relates to the field of domestic wastewater treatment using the combined biochemical method and has a wide range of uses, in particular it can be used in detached houses and small villages . Wastewater is supplied to a receiving tank, the purified water is pumped to the aeration tank, a secondary sump, and then the water flows from the secondary sump to an output tank. In the receiving tank, water circulates under the influence of activated sludge and fine bubble aeration of variable intensity. In the aeration tank, a vertically circular circulation of a mixture of water and activated sludge around the sump filter occurs. In the secondary sump, trapping of floating particles occurs. Next is the passage of water and additional filtration in a wet self-cleaning sand filter and from it the pumping of purified water to an outlet tank, where the water is subjected to ozone treatment, disinfection and circulating part of the ozonized water through a secondary sump and sand filter with an additional supply of ozonized water to the receiving tank and aeration tank. At the same time, the main airlifts are washed throughout the process. After ozone purification, a pressure discharge of purified water is carried out. Effect: intensification, improving the quality and reliability of the cleaning process through the use of vertical circular circulation and the organization of the process with the presence of a stage of post-treatment and automatic washing of the main elements.

A known method of treating wastewater and storm water from mechanical impurities and a device for its implementation [9]. A method of purifying liquids from mechanical impurities, comprising supplying a purified liquid through a gate to the internal cavity of the sand trap body, aeration of the cleaned liquid, sedimentation of mechanical impurities, transportation of deposited impurities to the sump, removal of sludge from the sump and removal of the cleaned liquid, characterized in that aeration is carried out until during and after the flow of the cleaned liquid over the sump, and more than half of all mechanical impurities precipitated over the sump due to aeration of the flow of cleaned liquid before and in emya cleaned fluid flow passage over the pit. Aeration is carried out to the entire depth of the hydraulic column of the flow of the liquid being cleaned.

Aeration of the liquid after passing the cleaned stream over the pit is carried out due to at least one main aerator installed in the cavity of the sand trap body on the bottom of the body along the longitudinal axis of symmetry of the bottom of the body, imparting a uniform spiral motion to the particles of liquid and impurities from the center to the periphery in the direction of travel flow, with the formation of two symmetrical flows of the liquid being cleaned.

Aeration before and during the passage of the liquid to be cleaned above the pit is carried out due to the action of at least one additional aerator installed perpendicular to the longitudinal direction of the flow rate of the liquid to be cleaned at the inlet of the liquid stream, with different intensities depending on the flow of the liquid to be cleaned and the content in it mechanical impurities in such a way that with a minimum value of the influx of liquid and with a minimum content of impurities in the liquid aeration before and during passage of the flow och device aboard the fluid region above the pit is carried out using one additional aerator, and when exceeding a certain value and the inflow of impurities connect second additional aerator.

The intensity of aeration before and during the passage of the liquid to be purified by the area above the pit is controlled by connecting a second additional aerator in the form of perforated pipes having the shape of a ring.

The intensity of aeration before and during the passage of the liquid to be purified by the area above the pit is controlled by connecting a second additional aerator in the form of perforated pipes having the shape of a polygon.

The transportation of deposited impurities to the pit is carried out simultaneously with the process of deposition of mechanical impurities using the mechanism for transporting sand to the pit in the form of a platform with mounted scrapers, which can perform reciprocating motion along the guides.

A horizontally located case with a bottom, gates for supplying the cleaned liquid and drainage of the cleaned liquid, sand channels, aerators in the form of perforated pipes, a pit, a mechanism for transporting sediment to the pit, a mechanism for removing sludge from the pit, characterized in that at least one main the aerator is installed in the body cavity on the bottom after the pit between the sand channels along the longitudinal axis of symmetry of the bottom, and at least one additional aerator is installed in the body cavity at the entrance to the body in front of the pit near the bottom surface perpendicular to the longitudinal axis of symmetry of the bottom of the body.

The main aerator is mounted on a support installed along the entire length of the body after the pit, which has a trapezoidal cross section, with inclined side walls that are both side walls of the sand channels, while the angle of inclination of the side walls exceeds the angle of sliding of the sand in the wet state.

The main aerator is installed at a height exceeding the height of the scraper of the mechanism for transporting deposited particles to the pit.

An additional aerator is made in the form of a straight pipe, ring or polygon.

The mechanism for transporting sand to the pit is made in the form of a platform with hinged scrapers, which can reciprocate parallel to the longitudinal axis of symmetry of the bottom along the guides installed in the sand channels from the gear motor drive through a system of connecting levers and a crank mechanism, and hinged scrapers mounted on the platform perpendicular to the direction of movement of the platform with the possibility of rigid fixation with translational (working) movement of the platform to the pit and with spine deflection in the direction opposite to the movement of the platform when it is returnable (idling) movement.

The disadvantages of treating wastewater and storm water from mechanical impurities and the device are the complexity of the design, the difficulty of unloading sludge from the sand trap.

Known wastewater treatment station [10], which can be used for biological wastewater treatment. It includes: a grill, aerated sand trap, sand platform, primary and secondary sedimentation tanks, a filter, a wash water storage tank, two booster pumps, a vertically tubular system, a jet apparatus, an auger-shaped blade, a source of technical oxygen, a float-operated valve, a dissolved concentration meter. oxygen in wastewater, setting device, comparing device, servo drive, valve, pressure sensors, electrified valves, position sensors of electrified valves, control unit Eden. Moreover, the station additionally contains a turbidimeter, a functional converter, a switch, a second inkjet apparatus, the mixing chamber of which is made of quartz glass, an ultraviolet emitter, an ozonizer, and a concentration meter of dissolved ozone in wastewater. Moreover, the ultraviolet emitter consists of individual ultraviolet lamps located axially relative to the quartz mixing chamber. A turbidimeter is installed at the filter output. The output of the turbidimeter is connected to the input of the functional transducer and through the control unit and the switch with ultraviolet lamp. The technical result is an increase in the efficiency of wastewater treatment with time-varying characteristics of the input fluid stream.

A known installation of biological treatment of domestic wastewater [11], which can be used in the communication economy of small towns. The installation contains sequentially located in the direction of movement of the treated water drive-averager, sand trap, two biological treatment units, a tertiary sedimentation tank and a system of process pipelines. Each of the biological treatment units contains a two-section submersible drum biofilter with a flat loading and a secondary sump. The biofilter is made in the form of a two-section submersible drum biofilter, in which the sections are separated by a continuous partition, with each section having 4 loading sector chambers. The secondary sump is made of an open tank, including 2-4 transverse cassette filters with a fixed load of clinoptilolite composition from the fractionated zeolite and sedimentation chambers. Cartridge filters are installed in an open container with the possibility of height adjustment or their complete removal from the tank. The number of secondary sedimentation tanks in each block is 1-3. The technical result is the rapid increase in the biomass of microorganisms and the most complete use of the load for the placement of microorganisms.

The disadvantages of the wastewater treatment plant are the need to have a sludge site, the difficulty of discharging sludge and supporting the viability of the strains.

A known installation for wastewater treatment [12], which contains a tertiary treatment unit, the housing of which is made in the form of a container, inside which there is a receiving chamber with trash holding devices, an aeration tank and a secondary settling tank, while the aeration tank circulation water pipe is placed inside the receiving chamber housing, and the pipe clarified water of the secondary sump is taken outside the housing of the receiving chamber; moreover, the post-treatment unit contains a system of drainage pipes located inside the sand-gravel filter, interconnected by a common collector, which is connected by a pipe to a reservoir containing a dispenser with a disinfecting solution and a pipe of purified water. The nozzles of the circulation flow of the aeration tank and the clarified water of the secondary sump are established from the condition of ensuring aeration of the water in the receiving chamber and the after-treatment unit. The technical result is an increase in the quality of wastewater treatment and the efficiency of the installation due to the additional saturation of wastewater with oxygen and their after-treatment in a sand and gravel filter.

The disadvantages of the installation for wastewater treatment are the use of filters that need cleaning or replacement, the complexity of the design and unloading of sludge.

A device for cleaning water and wastewater [13], including a sump containing a reservoir, nodes for supplying and discharging liquid, a flocculation chamber, a sump for collecting sludge, a device for removing sludge, transverse partitions, characterized in that the transverse partitions are installed in the settling zone are made slotted and placed along the length of the sump so as to exclude longitudinal mixing of the stream of clarified liquid, while the number of transverse slotted partitions should be at least 3 and not more than 8, and to exclude pepper stirring further longitudinal flow sump, do not reach the bottom of the blind baffles placed in sedimentation zone is divided into a number of parallel sections.

The size of the slits in the transverse partitions is chosen so that the water flow rate in the slits of the partition is 10-100 mm / s.

The transverse partitions are set so that the distance between them is 2-4 depths of the settling zone, and the immersion depth of the partitions is 70-90% of the total depth of the tank.

The longitudinal partitions are set so that the ratio of the width of the section of the sump to its length is 1: 4-1: 40, and the immersion depth of the partitions is 75-95% of the total depth of the tank.

The sump contains thin-layer modules and prefabricated trays installed in the upper part of the sludge zone, and they can be installed both over the entire area of the water mirror and only at a distance of 1 / 3-2 / 3 from the input device.

The disadvantages of the device for treating wastewater and storm water from mechanical impurities are the presence of slotted walls, which periodically need to be cleaned, and the use of coagulants.

A known method of clarification of water [14], adopted as a prototype in local devices, including treating water with a constant electric field with gravity sludge, characterized in that the water is pre-treated with an electric field, and after using water in the process lasting longer than its “memory” 50 -100 h water is treated additionally.

Treated water is fed into the technological process periodically in portions or continuously with a flow rate that ensures its replacement in the technological process during the “memory” of water.

An electric field is created with a voltage of 5-10 V, and the water is treated for at least 0.5 hours and not more than 2 hours.

A known method of clarification of process water in underground water collectors [15], adopted as a prototype, which includes transporting hydraulic mixtures and mine inflow from the faces, their accumulation, gravitational sedimentation of suspended solids, mechanized cleaning of the reservoir, the issuance of settled sludge for dehydration, its shipment and the issuance of clarified water to the surface or for reuse, characterized in that the method is carried out in three stages in a uniformly moving stream of water along the length of the path of deposition of particles on the first In the second stage, floating foreign objects are released in the pulp reception zone, in the next stage, the process of natural deposition of solid suspended particles of various sizes and specific gravities is intensified, and at the last stage, clarified water is accumulated before it is released to the surface or for reuse.

At the first stage, the separation of large solid particles and the accumulation of floating objects, such as wood chips, shavings, films of oil products, etc., are carried out by stopping the upper layer of water, for example, by enclosing transverse partitions installed in the upper part of the catchment near the water mirror.

At the second stage, for the precipitation of medium-sized particles, the stream is passed through thin-layer water-clarifying partitions, on which solid particles are accumulated and sent to the bottom of the catchment with mechanized cleaning.

At the third stage, the process of deposition of fine suspended particles is intensified by passing water through a transverse removable filtering cassette-type partition with a filler, for example, metal shavings.

After clarification, the water flow is directed to the water intake, the bottom of which is made with a minimum mechanically not cleaned bottom surface, where the pump suction is installed.

To intensify the process of cleaning the partitions from adhering small particles during the deposition of the partitions, they are connected to the vibrating mechanism of the mechanized cleaning of the catchment.

The disadvantages of the method of clarifying process water in underground water tanks are spaced conveyor branches that prevent the installation of treatment modules, the complexity of maintenance.

The objective of the invention is to increase the efficiency of wastewater treatment at minimal cost.

The solution of this problem is achieved in that: the method is carried out in two stages: in the first stage, the following operations are performed: distributed discharge of water into the receiving section of the sump, in which suspended particles and immiscible liquids are separated by a density higher and lower than the density of water, accumulate and hold suspended and immiscible liquids with a density lower than the density of water in the upper layer; suspended particles and immiscible liquids with a density higher than the density of water to the bottom of the sump; suspended particles and immiscible liquids with a density higher than the density of water are precipitated intensively to the bottom of the sump in subsequent sections; conduct physical and electrical processing to intensify the deposition of contamination on sequentially installed clarifiers, located along the length of the sump with mechanized unloading of settled sludge with a scraper dewatering conveyor into the mixer, to which binder, filler and neutralizer are added, mixed and subjected to compression, and the resulting briquettes are disinfected in microwave ovens, in the second stage, implemented by a series of technical devices, conduct additional physical and electrical treatment of water, wasp waiting for suspended particles, aeration and ozonation of water, collection of sludge settled in the devices, which is sent to the dewatering part of the scraper conveyor.

The complex non-reagent method of wastewater treatment and briquetting of sludge is characterized in that the distributed discharge of water into the sump with mechanized unloading is carried out with a flat stream from the springboard into the upper layer of water in order to extinguish the flow energy in the direction of water movement in the sump, where a transverse jumper is installed that provides water bypass suspended particles in density higher than the density of water under the lower edge above the bottom of the sump.

The complex non-reagent method of wastewater treatment and sludge briquetting is characterized in that “blinds” type devices are installed sequentially behind the partition, providing intensive sedimentation of suspended particles with a density higher than water density to the bottom of the sump with mechanized unloading of sludge.

A comprehensive non-reagent method for wastewater treatment and sludge briquetting, characterized in that a constant pulsating voltage is supplied to the physicoelectric water treatment device.

A comprehensive non-reagent method for wastewater treatment and sludge briquetting is characterized in that the water is discharged from the sump with mechanized unloading of sludge through a device that provides additional sedimentation of suspended particles and works on the principle of communicating vessels.

A comprehensive non-reagent method for wastewater treatment and briquetting of sludge is characterized in that the water is discharged from the sump with mechanized discharge through a device that controls the depth of water intake and / or emergency spillway by gravity and / or pumps into the intermediate sump, which serves to coordinate the performance of the first water treatment and second stage.

The complex non-reagent method for wastewater treatment and sludge briquetting is characterized in that a stand-alone aeration device, which is a container that provides dispersion of water through nozzles, and above the conical bottom there is an air inlet connected to a fan, taking air from the atmosphere and having an ejector to supply excess ozone from the reactor, and excess air is removed through a pipe at the top of the tank.

The complex non-reagent method for wastewater treatment and sludge briquetting is characterized in that in an autonomous ozonation device representing a container above which an ozone generator is located, and an ozonation chamber is placed inside the tank, water for ozonation is supplied at a pressure of 0.5-1.0 MPa.

The complex non-reagent method of wastewater treatment and sludge briquetting is characterized in that the final water treatment is carried out in a U-shaped container physically-electrically above a thin-layer clarifier, the plates of which are pivotally and movably fixed with an oscillation amplitude at the ends of 2-3 mm, while the plates have neutral coating.

The complex non-reagent method for wastewater treatment and sludge briquetting is characterized in that the intermediate sump and autonomous second-stage water treatment devices have conical bottoms with a wall angle of 55 ° to the horizontal plane.

A comprehensive non-reagent method for wastewater treatment and sludge briquetting is characterized in that the water from the intermediate sump is used for technical needs, and the second stage water is used for domestic purposes and / or discharged into external reservoirs.

A comprehensive non-reagent method for wastewater treatment and sludge briquetting is characterized in that the obtained dehydrated sludge with a moisture content of 20-30% is fed to the mixer, where they are added, wt.%: Binder 5-10, neutralizer 5-10, filler 20-30, and the rest , the mass is mixed and subjected to pressing, and the resulting briquettes are disinfected in microwave ovens for 3-4 minutes when they are heated to a temperature of 150-200 ° C.

The essence of a comprehensive reagentless method for wastewater treatment and sludge briquetting is illustrated by the drawing and is as follows.

Drawing - Technological scheme for implementing an integrated method of reagentless deep wastewater treatment and sludge briquetting.

The system that implements the proposed method of non-reagent wastewater treatment and sludge briquetting, is divided into two stages.

At the first stage, contaminated wastewater through the inlet pipe 1 having a flat nozzle is tangentially discharged onto the expanding springboard 2, which extinguishes the flow energy into the upper water layer of the sump 3, made in the form of a ditch 4 with a slope of 0.03 in the direction of the flow of water, where dewatering conveyor 5 with containers on scrapers 6 for settled sludge, a bobbin sieve 7 in the raised dewatering part of the conveyor and sump 8 for returning the under-sieve water to the sump 3, with mechanized unloading of settled sludge in the opposite direction Oron water flow. The discharge of contaminated effluents from the flat nozzle onto the springboard into the surface water layer of the sump and the installed transverse jumper 9 form surface circular flows in the receiving section 10 of the sump 3, where suspended particles with a density below the density of water are accumulated (oil products, sawdust, wood chips, etc.) and discharged together with settled sludge when turning on the scraper dewatering conveyor 5 due to sedimentation in containers 6 having a wedge shape, and immiscible liquids, suspended particles and substances with a density higher than density water is precipitated and under the lower edge of the transverse partition 9 are transferred to the working section of the sump 3, where water purification devices are installed in series.

Devices of water purification of the "blinds" type 11, installed at a distance of 0.5 m from each other, provide intensive deposition of suspended particles with a density higher than the density of water on the bottom of the sump 3 into containers 6 of the scraper conveyor 5, where they are accumulated and periodically discharged to the dewatering part conveyor by turning it on.

Behind the water purification devices of the "blinds" type 11, at a distance of not more than 0.5 m from each other, electrodes 12 are installed for physically-electric water treatment with a constant pulsating electric field.

Physicoelectric water treatment devices are installed at a distance of not more than 0.2 m from each other to the flooded end of the scraper dewatering conveyor 5.

Behind the flooded end of the scraper conveyor 5, at a distance greater than the width of the container 6 of the scraper conveyor, a water bypass device 14 is installed, operating on the principle of communicating vessels, separating the working and accumulating sections in the sump with mechanized cleaning, having a longitudinal opening on the central partition above the water level of the sump for bypass water on horseback, indicating the accumulation of sludge and the need to clean the device.

To maintain the laminar flow of water and its level at the outlet of the sump of the accumulating section of purified water, a device is installed for dumping and regulating the depth of water intake 15 and accident spillway 16, through which water is supplied by pumps 17 to the intermediate sump 18, which serves to coordinate the performance of the first and second water treatment stages, having the length of the conical bottom 19, separated from the sump lattices 20.

The second stage of water purification is carried out by autonomous devices assembled into the system using pipelines and air ducts with shutoff valves, which provide physical and electrical treatment of water, its mechanical purification, aeration and ozonation, removal of dissolved gases, organic substances and saturation of purified water with oxygen.

In a stand-alone device for physically-electric water treatment 21, representing a container, inside which are placed the electrodes 12 of a device for physical-electric water, having a conical bottom 19, separated from the tank by a grill 20, from where water is supplied to a stand-alone device for mechanical treatment of water 22, representing a closed chute, having a slope of 15-25 °, inside of which there is a device for water purification of the "blinds" type.

In a stand-alone aeration device 24, having an exhaust pipe 25, representing a container, inside which there are nozzles 26 for dispersing water, having a conical bottom 19, separated from the tank by a grill 20, while over the grill 20 there is an air duct 27 connected to a fan 28 equipped with a fence pipe 29 and an ejector 30 for supplying excess ozone from the generator 31, which has an air supply pipe 32 to the ozonation chamber 33, which is located in a tank 34 with a conical bottom 19 and a grill 20, while water is supplied to the tank 34 by a pump 35, and the excess ozone from the ozonation chamber 33 is fed through a throttle to the ejector 30 of the inlet of the aeration fan 28. Water from the ozonation device 31 is fed to a stand-alone device for physicoelectric water treatment 36, which is a dual tank, inside which electrodes 37 for physicoelectric water treatment and a thin layer are placed clarifier 38, with conical bottoms 19, separated from the tank by a grill 20, while the plates of a thin-layer clarifier 38 are pivotally and movably fixed with an oscillation amplitude at the ends of 2-3 mm and are neutral coating for preventing adhesion of suspended particles and ions of chemicals and water from the device is supplied to the sump of clean water 39, from where it is supplied to consumers and / or shed into external reservoirs.

Dehumidified on a scraper dewatering conveyor 5 sludge in containers 6 with a moisture content of 20-30% is fed to a mixer 40, where it is added from batchers 41: a binder of 5-10%, a filler of 20-30%, a neutralizer of 5-10%, and the rest is sludge mix and subjected to pressing on the press 42, and the resulting briquettes are disinfected in microwave ovens 43 by heating for 3-4 minutes to a temperature of 150-200 °.

The sludge settled in the conical bottoms through a pipe 44 by a slurry pump 45 is pumped to the head of the first stage and dumped onto the dewatering part of the conveyor 5.

Literature

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Claims (12)

1. A comprehensive method of non-reagent wastewater treatment and sludge briquetting, including the supply of wastewater to the sump with mechanized unloading of settled sludge, characterized in that it is carried out in two stages, in the first stage, the following operations are performed: distributed water discharge into the receiving section of the sump, which separates suspended particles and immiscible liquids at a density above and below the density of water, accumulate and hold suspended particles and immiscible liquids with a density below the density of water in the upper layer e recirculation suspended solids and immiscible liquid with a density higher than the density of water at the bottom of the settler; suspended particles and immiscible liquids with a density higher than the density of water are precipitated intensively to the bottom of the sump in subsequent sections; conduct physical and electrical processing to intensify the deposition of contamination on sequentially installed clarifiers, located along the length of the sump, with mechanized unloading of settled sludge with a scraper dewatering conveyor into the mixer, to which binder, filler and neutralizer are added, mixed and subjected to compression, and the resulting briquettes are disinfected in microwave ovens , at the second stage, implemented by a sequential series of technical devices, conduct additional physical and electrical treatment of water, os REPRESENTATIONS suspended particles, aeration and ozonation of water collecting devices deposited in the mud, which is sent to the dewatering part of the scraper conveyor. 2. The complex non-reagent method of wastewater treatment and briquetting of sludge according to claim 1, characterized in that the distributed discharge of water into the sump with mechanized discharge is carried out by a flat jet from the springboard into the upper layer of water in order to extinguish the flow energy in the direction of movement of water in the sump, where it is installed a transverse jumper providing a bypass of water and suspended particles in density higher than the density of water under the lower edge above the bottom of the sump. 3. The complex non-reagent method for wastewater treatment and briquetting of sludge according to claim 1, characterized in that devices of the "blinds" type are installed sequentially behind the partition, providing intensive sedimentation of suspended particles with a density higher than the density of water to the bottom of the sump with mechanized unloading of sludge. 4. The comprehensive non-reagent method for wastewater treatment and sludge briquetting according to claim 1, characterized in that a constant pulsating voltage is supplied to the physicoelectric water treatment device. 5. The complex non-reagent method for wastewater treatment and sludge briquetting according to claim 1, characterized in that the water is discharged from the sump with mechanized unloading of sludge through a device that provides additional sedimentation of suspended particles and works on the principle of communicating vessels. 6. The complex non-reagent method for wastewater treatment and briquetting of sludge according to claim 1, characterized in that the water is discharged from the sump with mechanized discharge through a device that controls the depth of water intake and / or emergency spillway by gravity and / or pumps into the intermediate sump, serving to coordinate the performance of water purification of the first and second stages. 7. The complex non-reagent method for wastewater treatment and briquetting of sludge according to claim 1, characterized in that the stand-alone aeration device, which is a container that provides dispersion of water through the nozzles, and above the conical bottom there is an air inlet connected to a fan, taking air from the atmosphere and having an ejector to supply excess ozone from the reactor, and the excess air is discharged through a pipe at the top of the tank. 8. The complex non-reagent method for wastewater treatment and briquetting of sludge according to claim 1, characterized in that the stand-alone ozonation device represents a container over which the ozone generator is located, and the ozonation chamber is located inside the tank, while water for ozonation is supplied under a pressure of 0.5 -1.0 MPa. 9. The complex non-reagent method for wastewater treatment and sludge briquetting according to claim 1, characterized in that the final water treatment is carried out in a U-shaped container physically-electrically above a thin-layer clarifier, the plates of which are pivotally and movably fixed with an oscillation amplitude at the ends of 2- 3 mm, while the plates have a neutral coating. 10. The complex non-reagent method for wastewater treatment and sludge briquetting according to claim 1, characterized in that the intermediate sump and autonomous second-stage water treatment devices have conical bottoms with a wall angle of 55 ° to the horizontal plane. 11. The integrated non-reagent method for wastewater treatment and sludge briquetting according to claim 1, characterized in that the water from the intermediate sump is used for technical needs, and the second stage water is used for domestic purposes and / or discharged into external water bodies. 12. The complex non-reagent method for wastewater treatment and sludge briquetting according to claim 1, characterized in that the obtained dehydrated sludge with a moisture content of 20-30% is fed to the mixer, where it is added, wt.%: Binder 5-10, neutralizer 5-10, filler 20-30, and the rest of the sludge, the mass is mixed and subjected to pressing, and the resulting briquettes are disinfected in microwave ovens for 3-4 minutes when they are heated to a temperature of 150-200 ° C.

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