RU2792230C1 - Wastewater treatment method with biomass production - Google Patents

Abstract

FIELD: biotechnology.

SUBSTANCE: method of wastewater treatment with biomass production is proposed, which includes pumping carbon dioxide produced during the oxidation of biological wastewater pollution in a separate container through a suspension of photosynthetic organisms in a liquid medium located in a separate tank under the rays of light with the production of exhaust oxygen and biomass production, and in advance empirically determine the required volume of wastewater and number of photosynthetic organisms. The levels of photosynthetic organisms in the liquid nutrient medium and wastewater, respectively, in the tank and vessel are maintained automatically; the biomass of photosynthetic organisms is taken from the tank, and purified water - from a separate section of the tank; oxygen is pumped from the tank above the level of the liquid medium to be supplied to the tank by a dosing pump with control oxygen concentration. Control of the concentration of carbon dioxide is carried out by increasing or decreasing the supply of wastewater to the tank.

EFFECT: invention provides biological wastewater treatment due to oxygen obtained by photosynthetic organisms.

3 cl, 1 dwg

Description

The invention relates to methods for purifying liquid human or animal waste products with the utilization of the resulting carbon dioxide during treatment with oxygen obtained from carbon dioxide-absorbing microalgae cultured.

A known method of cleaning livestock effluents and obtaining biomass (patent RU No. 2005789, IPC C12P 01/00, C02F 03/34, publ. fraction followed by the second stage of anaerobic fermentation of the liquid fraction and obtaining a fermented suspension biomass, combining the biogas formed at the I and II stages of fermentation, and, in order to reduce environmental pollution, increase the efficiency of wastewater treatment and biomass yield, the biogas formed during the fermentation ammonia by transferring it into a solution of ammonia water, separated into methane and carbon dioxide, the dense fraction of fermented effluents after the I stage of fermentation is hydrolyzed, the hydrolyzate is separated into liquid and dense fractions, the liquid fraction of the hydrolyzate is directed to the cultivation of yeast, the suspension biomass obtained after the II stage of anaerobic fermentation, separated into a liquid fraction and a sludge, the liquid fraction is taken, ammonia is removed from it by blowing with methane extracted from biogas, aerobic fermentation is carried out, a mixture is obtained containing a liquid fraction and a sludge, a liquid fraction, as well as carbon dioxide and ammonia water obtained in the biogas purification process is sent to grow microalgae and then macroalgae, the resulting algae suspension is separated into green biomass used as a feed additive and purified water, and the yeast suspension obtained from the yeast cultivation process is combined with a dense fraction obtained from the hydrolysis process , sludge obtained after stage II, anaerobic fermentation and aerobic fermentation, the resulting mixture is subjected to plasmolysis and used as a feed additive.

The disadvantages of this method are the additional costs for the disposal of ammonia obtained during the oxidation of organic matter in wastewater, which is released on a separate membrane separator of carbon dioxide and methane, and then absorbed in a separate absorber and introduced into the photobioreactor (algal cultivator) in the form of ammonia water, a high probability of contamination algal culture by predators and competitors due to the lack of filtration before entering the photobioreactor, incomplete utilization of carbon dioxide (CO ₂ ), therefore, part of the carbon dioxide is supplied to the surrounding air, and the oxygen released during the cultivation of biomass (O ₂ ) is not used in the process of wastewater oxidation , which requires additional costs for the purchase and introduction of oxidizers into wastewater, while photosynthesis is not used to accelerate the utilization of CO ₂ and the growth of microalgae for biomass.

The closest in technical essence is a biofermentation photosynthetic device for gas production (patent for PM RU No. 86185, IPC C12R 01/00, C12M 01/04, A01C 03/00, publ. 27.08.2009 Bull. No. 24) in the form of a reactor with environment circulation system, which contains a biofermentation block, a biomixer, a biophotosynthetic oxygen generator and a biodegradation tank, interconnected by pipeline systems, the biofermentation block consists of a tank with water, in which a fermentation reactor is located with openings for nozzles, one of which serves to supply the initial mixture for fermentation, the other - to remove the resulting gas mixture, the third is located in the lower part of the fermentation reactor, the water tank is placed in a chamber that provides a vacuum layer around the specified tank, and has a hole for water supply, the chamber has a hole for pumping air out of it, fermentation the reactor is connected by a pipe to a gas storage tank, which is also It is not connected by air ducts to a container in which turbine blades are located around the central axis, the container with a turbine has a branch pipe for a transport pipe, the biofermentation unit is connected to a biophotosynthesis oxygen generator using a biomixer with a mixing mechanism and a pipe system, the biophotosynthesis oxygen generator is made in the form of a reservoir made of translucent material with a system for supplying initial components to it and selecting the target product, the specified oxygen generator can be equipped with an optical system of mirrors, consisting of a folding mirror, an upper reflector, a lens and an internal reflection mirror, while the biodegradation tank is a container, inside which a piston with rod, the end of which is located outside the container, the piston rod is equipped with a spring located between the outer surface of the piston and the inner surface of the upper wall of the container.

With this biofermentation photosynthesis device, a method for obtaining biomass is carried out, which includes pumping carbon dioxide through a solution of bacteriophylls in water located in a tank under sunlight to activate photosynthesis with the production of exhaust oxygen and obtaining biomass, which is fed with oxygen to a biodegradation tank for decomposition and fragmentation with the release of carbon dioxide, which is also sent to the tank for photosynthesis.

The disadvantages of this method are a narrow scope due to the inability to treat wastewater with the consumption of oxygen (O ₂ ) released during photosynthesis, additional costs for the delivery and injection of carbon dioxide (CO ₂ ), since this gas is not enough during drying and fragmentation of biomass to maintain photosynthesis, the need to select and store the resulting oxygen due to the lack of its use in the method, while photosynthesis is not used at night to accelerate the utilization of CO ₂ and the growth of microalgae for biomass (only sunlight), which increases the unproductive implementation of the method (for night time account).

The technical objective of the proposed invention is to create a method for treating wastewater with biomass production, which allows to purify wastewater, completely utilize carbon dioxide and oxygen in a closed cycle with an increase in the time of illumination of photosynthetic organisms through the use of round-the-clock lighting in the form of mirrors, optical lenses and / or artificial lighting and adjusting the supply of sewage, as well as adjusting for the removal of treated water and biomass obtained from photosynthetic organisms, that is, preventing the emission of greenhouse gases during biological wastewater treatment and improving the efficiency of biological wastewater treatment by photosynthetic oxygen.

The technical problem is solved by a method of wastewater treatment with biomass production, which includes pumping carbon dioxide through a suspension of photosynthetic organisms in a liquid medium located in a separate tank under light rays to activate photosynthesis with the production of exhaust oxygen and biomass production.

What is new is that the required volume of wastewater supplied to a separate tank for the production of carbon dioxide and complete absorption of the released oxygen, and the required amount of photosynthetic organisms placed in the tank to receive oxygen after pumping all the carbon dioxide produced in the tank, are preliminarily empirically determined, and moreover, the levels of photosynthetic organisms in the liquid nutrient medium and wastewater, respectively, in the tank and tank are maintained automatically, the biomass obtained by photosynthetic organisms is taken from the tank, and the purified water is taken from a separate section of the tank, communicated below the upper edge of the water at a distance from the oxygen injection, sufficient for settling waste water after reaction with oxygen during the flow of water into a separate section, oxygen is pumped from the tank above the level of the liquid medium to be supplied to the tank by a dosing pump with oxygen concentration control, with a decrease in the optimal concentration in oxygen is added to the air, when the oxygen concentration decreases, the number of photosynthetic organisms removed from the tank is reduced until the optimal oxygen concentration is obtained, and carbon dioxide is supplied through the purification system from biologically aggressive for photosynthetic organisms and / or substances by a dosing pump with control of the carbon dioxide concentration, to increase or decrease supplying wastewater to the tank to increase or decrease the concentration of carbon dioxide, respectively, to maintain it at the optimum concentration.

It is also new that the purification system from biologically aggressive for photosynthesizing organisms and / or substances is produced mechanically by pumping gases with carbon dioxide from a tank through at least one filter with pores of no more than 0.2 μm, or chemically - by pumping through a liquid reagent that neutralizes completely biologically aggressive organisms and/or substances, or a combination of mechanical and chemical treatment.

What is also new is that the tank is equipped with a round-the-clock lighting system in the form of mirrors, optical lenses and / or artificial lighting, which is turned on at night.

The drawing shows a diagram of the implementation of the method of wastewater treatment with obtaining biomass. Structural elements, technological connections, uraniums and taps that do not affect the implementation of the method are not shown in the drawing or are shown conditionally.

Preliminarily, empirically, the required volume of wastewater supplied through inlet 1 to a separate container 2 is determined for the production of carbon dioxide and the complete absorption of released oxygen supplied from the upper part of the reservoir 3 through the gas pipeline 4 by the dosing pump 5 through the perforated pipe 6, and the required number of photosynthetic organisms, placed in a tank 3 with a living - nutrient medium to produce oxygen when illuminated by light sources 7 after pumping through a perforated pipe 8 and a second gas pipeline 9 using a second dosing pump 10 of all carbon dioxide, swirled from the top of the tank 2. Since these processes are taken separately purification of wastewater and the production of oxygen from photosynthetic organisms are known, then, based on practice, it is easy to choose the proportions of the volume of wastewater supplied to tank 2 and the number of photosynthetic organisms placed in tank 3. For each type of photosynthetic organism and wastewater e, respectively, their volume and quantity are selected individually (the authors do not claim this).

Suspension levels 11 and 12 of photosynthetic organisms in a liquid nutrient medium and wastewater, respectively, in tank 3 and tank 2 are maintained automatically (not shown, for example, using piezo sensors, floats, wings, or the like) to maintain a constant cyclic exchange of oxygen and carbon dioxide gas. A large number of automatic systems (automation) for maintaining liquid levels are known from open sources, so the authors do not pretend to be. Above these levels 11 and 12, respectively, oxygen and gas (CO ₂ , NO _x , NH ₃ , etc.) are taken away, which also includes carbon dioxide (CO ₂ ) involved in photosynthesis in tank 2.

The biomass obtained by photosynthetic organisms from reservoir 3 is withdrawn through pipeline 13, after cleaning and drying (using screw-extractors, filters, centrifuges and / or the like - not shown), the biomass is used as “feeding” plants, food for livestock, or the like. P. The squeezed out liquid nutrient medium is analyzed, if necessary, nutrients are added and fed back to tank 3 through the inlet pipeline 14.

Purified water is taken through the outlet pipe 15 from a separate section 16 of the container 2, which is connected below the upper edge of the water at a distance L from the oxygen injection through the perforated pipe 6, sufficient to settle the waste water after reaction with oxygen and sedimentation of sludge and particles during the flow of water into a separate section 16. Solid heavy particles of biological contaminants, which turn into sludge after reaction with oxygen, settle from the water to the bottom of the tank 2, from where they are taken for disposal at outlet 17.

Oxygen is pumped from the reservoir 3 above the level 11 of the liquid medium to be supplied to the container 2 by a dosing pump 5 with oxygen concentration control by a dispenser (not shown) installed on the gas pipeline 4. When the optimum concentration decreases, atmospheric air is added to the oxygen to maintain the circulation process. When the oxygen concentration decreases, the number of photosynthetic organisms with biomass removed from the tank 3 through the pipeline 13 is reduced to obtain an oxygen concentration that is optimal for maintaining continuous cyclic operation (determined empirically).

During the oxidation of biological contaminants in tank 2, gases are produced, including carbon dioxide. However, microorganisms and/or substances that are biologically aggressive for photosynthetic organisms also enter the composition of the gas, which can cause the death of the latter. Therefore, before pumping with pump 10, they are driven through the cleaning system 18, which is used as at least one filter with pores of no more than 0.2 μm, to prevent the passage of microorganisms, or chemically - by pumping through a liquid reagent (alkaline, acid - depending on the type of harmful microorganisms and/or substances) that completely neutralizes biologically aggressive microorganisms and/or substances, or by a combination of mechanical and chemical cleaning (for example, successively installed cleaning methods; spraying filter pores with liquid reagents, etc.).

At the same time, carbon dioxide from tank 2 is supplied by pump 10 to tank 3 through perforated pipe 8 with control of carbon dioxide concentration by a dispenser (not shown) installed on gas pipeline 9. To increase or decrease the concentration of carbon dioxide, increase or decrease the supply through inlet 1, respectively. wastewater into tank 2 to maintain the carbon dioxide concentration optimal for maintaining continuous cyclic operation (determined empirically).

To increase work efficiency due to more uniform light dispersion and longer operation time of illumination of light sources 7, tank 3 is equipped with a round-the-clock lighting system in the form of mirrors, optical lenses 19 (shown conditionally) and / or artificial lighting, switched on at night. It is also possible to make one or more walls of the tank 3 transparent to increase illumination.

Due to the constant monitoring of the concentration of oxygen and carbon dioxide and effective round-the-clock lighting, the oxygen and carbon dioxide produced are fully used during the implementation of the method and are not released into the environment, that is, without greenhouse gas emissions.

The proposed method of wastewater treatment with the production of biomass allows you to purify wastewater, completely utilize carbon dioxide and oxygen in a closed cycle with an increase in the time of illumination of photosynthetic organisms through the use of round-the-clock lighting in the form of mirrors, optical lenses and / or artificial lighting and adjusting the supply of wastewater, as well as adjustments for the removal of treated water and biomass derived from photosynthetic organisms, i.e. preventing greenhouse gas emissions from biological wastewater treatment and increasing the efficiency of biological wastewater treatment with photosynthetic oxygen.

Claims (3)

1. A method of wastewater treatment with biomass production, which includes pumping carbon dioxide through a suspension of photosynthetic organisms in a liquid medium located in a separate tank under light rays to activate photosynthesis with the production of exhaust oxygen and biomass production, characterized in that the necessary the volume of wastewater supplied to a separate tank for the production of carbon dioxide and complete absorption of the released oxygen, and the required number of photosynthetic organisms placed in the tank for oxygen production after pumping all the carbon dioxide received in the tank, and the levels of photosynthetic organisms in the liquid nutrient medium and wastewater , respectively, in the tank and the tank are supported by automation, the biomass obtained by photosynthetic organisms is taken from the tank, and the purified water is taken from a separate section of the tank, communicated below the upper edge of the water at a distance from the acid injection chlorine, sufficient to settle the waste water after reaction with oxygen when water flows into a separate section, oxygen is pumped from the tank above the level of the liquid medium to be supplied to the tank by a dosing pump with oxygen concentration control, when the optimum concentration decreases, air is added to oxygen, when the oxygen concentration decreases the number of photosynthetic organisms removed from the tank is reduced to obtain the optimal oxygen concentration, and carbon dioxide is supplied through the purification system from biologically aggressive for photosynthetic organisms and / or substances by a dosing pump with control of carbon dioxide concentration, to increase or decrease the supply of wastewater to the tank for, respectively , increasing or decreasing the concentration of carbon dioxide to maintain it at an optimal concentration. 2. The method of wastewater treatment with the production of biomass according to claim 1, characterized in that the purification system from biologically aggressive for photosynthetic organisms and / or substances is produced mechanically by pumping gases with carbon dioxide from a tank through at least one filter with pores no more than 0, 2 μm, or chemically by pumping through a liquid reagent that completely neutralizes biologically aggressive organisms and / or substances, or by a combination of mechanical and chemical cleaning. 3. The method of wastewater treatment to obtain biomass according to one of paragraphs. 1 or 2, characterized in that the tank is equipped with a round-the-clock lighting system in the form of mirrors, optical lenses and/or artificial lighting, switched on at night.

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