RU182587U1 - INSTALLATION OF PHOTOCATALYTIC WATER TREATMENT - Google Patents

Abstract

The utility model relates to the field of water purification from harmful impurities, undesirable odors, etc. The objective of the proposed technical solution is to create a simple design of the installation for purification from bactericidal and organic pollutants of water, previously purified from mechanical impurities by known filtration methods.

The design of the installation uses containers for purified and purified water, a centrifugal pump for pumping water, commercially available ultraviolet (UV) sterilizers, pipe fittings and hoses. A difference of the utility model is that a membrane diffuser-aerator is installed in the bottom of the tank of water to be cleaned, connected to an air blower, and catalyst particles, for example, TiO ₂ , are introduced into the water to be cleaned, and a membrane filter is used to select purified water from the circulating stream, the particle size of the catalyst is larger than the pore size of the filter membrane septum. Manometers and valves are used to control and regulate water flows.

In the purification mode, water circulates through a cascade of UV-sterilizers connected in series and returns to the tank of purified water, after purification from organic pollutants, the water is sent to a membrane filter with the selection of purified water from the circulating stream, which is discharged into the tank of purified water.

The design of the installation is simple to manufacture, almost all of its components are mass-produced products.

Description

The utility model relates to the field of water purification from harmful impurities, which are often organic substances, from harmful microorganisms, to remove unwanted odors, etc. For purification of water from bactericidal pollution, lamps with ultraviolet (UV) radiation have been successfully used for a long time. UV sterilizers are designed for the disinfection of drinking water, pool water, water in food production, sea and industrial water. This equipment is mass-produced by both foreign and domestic manufacturers, for example, the company Industrial UV-disinfection systems LLC (St. Petersburg).

The main elements of the UV sterilizer is a housing with nozzles for water inlet and outlet, in which one or more quartz tubes with UV lamps inserted into them are installed. The purified water from the tank provided for it through the UV sterilizer is pumped by a centrifugal pump into the tank for disinfected water. For fastening elements of treatment plants, frame constructions made of rolled metal are usually used.

To remove water-soluble contaminants of organic origin (amino acids, phenols, glycols, etc.), photocatalysis processes based on the ability of catalysts to be activated by light or ultraviolet radiation and accelerate various reactions, in particular the oxidation of organic substances by oxygen to water, can be used carbon dioxide. Most often, titanium dioxide TiO ₂ is used as a catalyst in a suspended state or fixed on an inert carrier. In the first case, a large area of the illuminated surface of the catalyst particles is provided, but an additional stage of separating the catalyst on membrane filtration devices is required to return the catalyst particles to the process.

During optical pumping of the grains of the photocatalyst, electron-hole pairs are generated in the volume of the semiconductor, which is TiO ₂ , followed by diffusion of these chemically active particles onto the surface of the grains in contact with water. Upon reaching the surface, electron-hole pairs interact with pollutant molecules, giving rise to a sequence of oxidation reactions, which provides an intensive process of molecular destruction and water purification.

Known photocatalytic module for water purification according to the patent of the Russian Federation No. 2394772, which contains a porous photocatalytic reactor in the form of a cylinder made of quartz, glass, ceramic or glass ceramics, on the surface of which is applied nanocrystalline titanium dioxide, and a source of ultraviolet radiation. Water is taken by a pump from a tank and fed to a porous reactor. Flowing down it back into the tank, the water is exposed to the catalyst illuminated by a UV lamp.

The disadvantages of such a device include the difficulty in manufacturing a porous reactor, uneven lighting, since only the inner surface of the cylinder is directly illuminated, the remaining layers of sintered (glued) balls are obscured by previous layers. Obviously, part of the catalyst particles may crumble and fall into the purified water, thereby polluting it.

Known photocatalytic reactor [EAPO Bulletin (21) 200900592, authors Foster Neil Robert (GB), Bassiti Kurosh (FR), Dementiev V.N. (RU)]. The reactor is made in the form of a vertically arranged pipe with nozzles for supplying and discharging the liquid to be cleaned and a coaxially located lamp, to the walls of which are adjacent perforated elements located in different tiers. In perforated elements, a rising flow of air bubbles maintains a suspension of many moving particles of the photocatalyst, the size and density of which are such that during operation of the reactor they remain on the perforated element. Aeration air and the gas fraction of the reaction products accumulate in the upper part of the reactor. A special valve is provided for the release of gases from the reactor. A titanium dioxide photocatalytic reactor can be used for wastewater treatment.

The disadvantage of this device is that when it is used, it is necessary to maintain an accurate balance of the activity of the flow supplied to purify the water in the reactor and the air flow supplied to bubble water and to keep particles in suspension in perforated elements. If this condition is not met, the particles will either be pressed against the grid (membrane), poorly illuminated and minimally participate in photocatalytic reactions, or thrown out of the perforated elements, which leads to the elimination of catalyst particles from the process and contamination of purified water with catalyst particles.

The objective of the proposed technical solution is to create a simple design of the installation for purification from bactericidal and organic pollutants of water, previously purified from mechanical impurities by known filtration methods. In this case, commercially available equipment available for use can be used in the design of the installation.

The proposed installation is shown in FIG. one.

A frame 1 electric centrifugal pump is mounted on a frame 1 welded from metal rolling of standard profiles. The suction line of the pump by means of a pipe and a hose is connected to a tank of purified water 3, in the bottom of which a membrane diffuser aerator 4 is connected, connected by a hose to an air blower 5. Above the membrane level in the wall of the tank there is a pipe connected to the suction line of a centrifugal pump. A container of purified water 6 is located nearby. A cascade, for example, of three vertically located UV sterilizers 7, is located above the containers (OVV-5-1 sterilizers are shown in real geometric proportions.). A threaded angle 8 is screwed onto the lower pipe of the UV sterilizer, through which the first UV sterilizer is connected to the discharge line of the centrifugal pump through a hose. Similarly, the upper pipe of the first UV sterilizer is connected to the lower pipe of the second UV sterilizer. The latter is also connected in the cascade of the UV sterilizer, the upper pipe of which is connected to a three-way valve 9. One line of the crane is connected by hoses through a tee 12 to the pipe in the upper part of the tank of purified water, and the other line is connected to the inlet pipe of the membrane filter with the selection of purified water from circulating flow 10 (for example, ceramic filters Metawater, KMF-0.7, KMF-1.4 - manufacturer "NTTs-VODA", AquaKON-0.15 - LLC "Binacor-HT"). The central outlet pipe of the membrane filter with hoses through the load valve 11 and the tee 12 is also connected to the upper pipe of the tank of purified water. The lateral outlet pipe of the membrane filter through the valve 13 and the hose is connected to the tank for purified water. Installation elements are mounted on the frame.

In the water to be purified, particles of a catalyst, for example titanium dioxide, are in a finely dispersed state, the size of which is larger than the pore size of the filter membrane septum.

Between the outlet pipes of the membrane filter and the valves respectively connected to them, pressure gauges 14 and 15 are installed, which allow controlling the differential pressure of the water in the filter set by the valves before and after the filter membrane partition. The control units for the pumping unit, the air blower into the aerator and the UV-sterilizer lamps are mounted on the control panel 16.

A membrane filter with the selection of purified water from the circulating stream 10 is mounted on the frame 1 at an angle to the horizon in such a way as to ensure its most complete emptying, that is, the discharge of water in it in the mode when the filter is not used.

The installation of photocatalytic water treatment as follows. The purified water is poured into the tank 3 (technical means of pouring water are not shown in Fig. 1), the valves 11 and 13 are completely closed, the three-way valve 9 is moved to the position to drain the water into the tank 3. After that, the UV lamps, an air blower and a centrifugal pump are turned on for pumping water. After the start of water circulation, the prepared aqueous suspension of the catalyst powder is poured into the container 3, which is mixed in the whole volume of the container by the stream of water poured into the container and rising air bubbles. Saturation of purified water with air is also necessary to activate the oxidation of organic pollutants by catalyst particles under the influence of UV radiation.

The flow of water supplied to the UV sterilizers by a centrifugal pump, passing through the threaded angle 8, makes a sharp 90 ° rotation and abuts against the wall of the quartz tube, which is accompanied by the creation of an active turbulent water flow rising in an annular section to the outlet of the UV sterilizer. Catalyst particles having a specific gravity greater than the specific gravity of water, under the influence of gravity and inertia forces arising from the curvilinear motion of particles together with turbulent swirls of water flows, constantly move relative to water, colliding with molecules of organic contaminants. In this case, the catalyst particles activated by UV radiation destroy organic pollution, converting them into carbon dioxide and water. Since the volume of gas generated in one pass of water through the sterilizer is small, in the state dissolved in water, the gas is discharged into the tank 3, where it is released into the atmosphere.

It should be noted that a cascade of several relatively short UV sterilizers connected in series is more efficient than a single UV sterilizer of the same total length, since the turbolization of the water flow resumes in each sterilizer of the cascade.

As water circulates through UV sterilizers, the concentration of organic contaminants decreases. Upon reaching the standard concentration values, open valve 11 and transfer the valve 9 to the position of water supply to the membrane filter 10. After that, open valve 13 smoothly, observing the readings of pressure gauges 14 and 15, creating a pressure drop of not more than the value specified in the technical characteristics of the membrane filter, - the pressure that the filter membrane (membrane) can withstand without damaging it. In this mode of operation of the installation, the catalyst particles together with water are discharged into the tank 3, and the purified water is discharged into the tank 6.

After filling the tank 6, close the valve 13, and the tap 9 is switched to the position of draining the water into the tank 3, and the tank is filled with the next portion of the purified water. Since the catalyst particles remained in the system, adding them is not required.

To determine the time of one cycle of water purification during the process, water samples are taken from tank 3 for analysis. When the state of water is stable in the composition of contaminants, the installation can operate in automatic mode, for which it must be equipped with automatically operating actuators for controlling valves, a three-way valve, devices for filling the tank of purified water and draining of purified water.

Preventive maintenance of the installation is reduced to periodically monitoring the operation of UV lamps, washing quartz tubes with a solution of oxalic acid, and cleaning the filter membrane with a reverse flow of clean water. If necessary, a catalyst is added to the tank of purified water of the installation.

Thus, the claimed utility model solves the tasks and effectively removes the bactericidal and organic contaminants of the water that has undergone preliminary purification by known filtration methods from mechanical particles. The design of the installation is simple to manufacture, almost all of its components are mass-produced products.

Claims (4)

1. Installation of photocatalytic water treatment, containing a centrifugal pump with an electric drive, a container of purified water and a container of purified water, ultraviolet sterilizers, pipe fittings, hoses and a frame on which the elements of the installation are mounted, characterized in that a membrane diffuser is installed in the bottom of the tank for purified water an aerator connected to an air blower, and above the level of the membrane in the tank wall there is a nozzle connected to the suction line of a centrifugal pump, the discharge line of which is connected to by the first ultraviolet sterilizer in series from the cascade, the output of which is connected to the inlet of the subsequent sterilizer, while the last outlet in the cascade of the sterilizer is connected to a three-way valve, one line of which is connected to the pipe in the upper part of the tank of water to be purified, and the second line to the inlet pipe of the membrane filter with the selection of purified water from the circulating stream, the central outlet of which through the load valve and hose is also connected to the upper nozzle of the tank my water, while the outlet side of the membrane filter via a valve and a hose connected to the tank for purified water. 2. The photocatalytic water treatment plant according to claim 1, characterized in that particles of catalyst, for example titanium dioxide, which are larger than the pores of the filter membrane filtration partition, are in a finely dispersed state in the water being purified. 3. The photocatalytic water treatment plant according to claim 1, characterized in that pressure gauges are installed between the outlet pipes of the membrane filter and the valves connected to them accordingly to control the differential pressure of the water set by the valves before and after the filter membrane baffle. 4. The photocatalytic water treatment plant according to claim 1, characterized in that the membrane filter with the selection of purified water from the circulating stream is installed at an angle to the horizon in such a way as to ensure its most complete discharge, that is, the discharge of water in it in the mode when no filter is used.

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