LT5075B - Method for the biosorption treatment of the waste and biosorber - Google Patents

Abstract

The invention relates to a biotechnology field, in particular to a method and device for biologically treatment of waste containing oil products. According to the invention, the treatment of waste is caring out in a biosorber by loading and ejectingthe waste periodically and stopping and actuating aeration. In the biosorber there are placed an activated carbon, an aerator and systems of waste feeding and ejecting of treated water. After loading waste into the biosorber, there is added an activated sludge to form a biofilm on the plastic carriers. The biochemical oxidation of waste is carrying out by agitation with aeration the activated carbon and the plastic carriers with biofilm.

Description

The invention relates to the field of ecological biotechnology, more precisely to the treatment of waste water contaminated with petroleum products and can be used for environmental protection. The unit can be used for wastewater treatment before being discharged from chemical, food and other industrial sites.

The combination of the process of sorbing organic pollutants with activated carbon and their biodegradation by immobilized microorganisms that carry out the regeneration of activated carbon (restoration of sorbing properties) is called biosorption and the facilities where it occurs are called biosorbers. Biosorbers are used to treat wastewater contaminated with synthetic surfactants, petroleum products, dyes and other substances that are not readily biodegradable. The process itself consists of two compound processes - the sorption of pollutants on activated carbon and the decomposition of biochemical adsorbent pollutants (recovery of activated carbon sorption properties - biological regeneration).

The analogue of the present invention is a two-layer biosorber, in which the sorbent is used as an activated carbon, which is highly adsorbent to phenols, polycyclic aromatic hydrocarbons, most petroleum products and other organic pollutants. Granular carbon can be used in filters that are not only for sorption but also for clarification. In the book, C.B. Hkobjicb, Ή. A. KapejiHH, “ΒΟΛΟΟΤΒΟΛΗΙΠΗβ CHCTeMBI npOMBIUUieHBIX npejjnpHilTHfi”, H3A “CTpoŪ3B, aT”, MocKBa, 1990,338 - 340 p. a two-layer biosorber, which is operated at the Szczekinskiy plant, is presented. The effluent is fed to the central chamber where it is aerated, which then passes through the circulation chamber to the distribution chamber. The effluent from the distribution chamber is fed to the bottom semi-"boiling" layer of activated carbon. Contact between the effluent and the activated carbon creates micro-zones with an increased concentration of organic matter and oxygen on the surface of the activated carbon layer. This provides good conditions for the growth of microorganisms that carry out the biochemical oxidation of sorbed contaminants and the biological regeneration of activated carbon. The resulting excess mass of microorganisms is removed and retained from the lower activated carbon layer to the upper dense activated carbon layer, and the purified water is collected in the gutter and removed from the unit. The circulating water velocity in the lower activated carbon layer is 30 - 40 m / h. The flow rate in the upper filtration layer is 3 - 5 m / h. The upper activated carbon layer is washed periodically, during which the floating material accumulated between the activated carbon grains is removed.

Disadvantages of this unit are: (1) complicated construction; (2) difficulty in changing performance; (3) the aeration mode cannot be changed; (4) operate within very narrow ranges of concentrations and flow rates; (5) not protected from activated carbon leaching; (6) It is difficult to change the duration of the regeneration process.

The object of the invention is to improve the final treatment of poorly decomposable organic matter (e.g. detergents, various petroleum products, etc.) in waste water.

The goal is achieved by carrying out the final treatment of wastewater through sorption, biochemical oxidation and filtration processes. These processes are carried out using biochemical oxidation and sorption, a granular activated carbon on which a film of microorganisms is grown. And for filtering using sedimented granular coal and gravel. Contact of pollutants with organic pollutants is effected by saturation of wastewater with air supplied through diffusers.

More specifically, the objective is achieved by performing a biosorbent treatment of wastewater in a single vessel, by periodically adding and discharging wastewater and stopping and activating aeration. The bottom of the tank is provided with a purged water drainage system and a filtration layer is laid over it, then filled with activated carbon, preferably with activated carbon, and a plastic charge. After filling the tank with sewage, activated sludge is added to form a biofilm on the plastic charge and activated carbon. Biochemical oxidation of sorbed contaminants is accomplished by mixing activated carbon and a plastic charge with biofilm aeration, then stops aeration. The treated wastewater is filtered through the deposited activated carbon and a pre-laid bed of filtration, preferably gravel.

Biosorbent wastewater treatment is performed by a biosorber consisting of a tank containing activated carbon, an aerator, wastewater feed and purified water discharge systems. The biosorber provided is characterized by a single container with a purified drainage system in the form of a drainage pipe on the bottom and a filtration layer, preferably a gravel layer, on top of which is additionally filled with activated carbon, preferably granular, and plastic. , while the aerator diffusers are located above the filtration layer and the wastewater is installed at the top of the tank.

Typically, the capacity of the biosorber is filled with 10% gravel, 20% activated carbon and 10% charge (by volume of biosorber).

BRIEF DESCRIPTION OF THE DRAWINGS The drawing shows a general view of the biosorber.

The biosorber consists of a main reservoir - bioreactor 1, aeration tank, air distribution pipeline 2 and diffusers 3, drainage manifold 4, bore drainage pipes 5, support gravel layer 6, activated carbon and plastic charge 8.

Principle of Biosorber operation

The biosorber is a unit of volume (capacity 1) with a bottom drainage system 4 of perforated pipes 5 and a filtering gravel layer 6 with a grain diameter of 1.2 - 3 mm. Air distribution equipment with diffusers 3 distributed evenly above the gravel layer 6.

The remainder of the volume (usually 8 m high) is filled with a plastic mobile charge and granulated activated carbon 8. The mobile charge is 10 mm high, 15 mm diameter, made of a polymer having a density of 0.94 - 0.98 g / cm. This density of material allows it to move freely in the reactor. The charge is a small cylinder with internal partitions dividing the cylinder into six compartments, two of which are larger and four smaller, with 0.5 to 2 mm ribs on the outside of the charge.

Biosorber is a biochemical complex purification plant in which activated carbon acts as a sorbent and as a backbone for microorganism film growth.

The capacity of the biosorber is filled with 10% mobile charge, 20% activated carbon and 10% gravel (based on the volume of the biosorber). Contaminated wastewater is fed to the bioreactor, where the charge provides good conditions for the growth of microorganisms. The charge is designed to form a protective surface for the biofilm. Activated carbon and mobile charge circulation in the unit result in efficient decomposition of organic pollutants.

Removal of contaminants in the biosorption process can reach 3.5 kg ChDS / kg activated carbon. This is 7 times more than using simple sorbent additional treatment of biochemically treated wastewater. With the introduction of biosorbers, capital inputs are reduced by up to 2 times and operating costs up to 3 times compared to the traditional bioremediation scheme with auxiliary treatment.

Not only does this process of water treatment lead to the aggregate operation of these processes, but an oxidation-sorption catalyst is formed which greatly increases the depth and speed of this process, on the other hand, most of the partial oxidation products are better sorbed by activated carbon. In addition, the use of two methods is always more reliable and significantly extends the range of organic compounds that can be removed from the water.

Claims (8)

Definition of the Invention 1. A biosorbed wastewater treatment method, in which the effluent is fed to the activated carbon layer and aerated, characterized in that the biosorbed wastewater treatment is carried out in a single tank, periodically filling and discharging the wastewater and stopping and activating aeration, the filtration layer is filled with activated carbon and a plastic charge, then, after the tank is filled with wastewater, the activated sludge is added to form a biofilm on a plastic charge; filtration through a precipitated activated carbon and a pre-laid filtration layer. 2. The biosorption process for wastewater treatment according to claim 1, characterized in that it utilizes granular activated carbon. 3. A biosorbent wastewater treatment method according to claim 1, characterized in that the pre-laid filtration layer is a gravel layer. 4. A biosorber containing a tank containing activated carbon, aerators, wastewater and purified water drainage systems, characterized in that it consists of a single tank with a purified water drainage system on top and a filtration layer over it. filled with activated carbon and plastic charge, aerator diffusers are located above the filtration layer, and wastewater is installed at the top of the tank. 5. Biosorber according to claim 4, characterized in that the bed filtration layer is a gravel layer. 6. The biosorber of claim 4, wherein the container is filled with granular activated carbon. 7. A biosorber according to claim 4, characterized in that the purged water discharge system consists of drainage manifolds. 8. Biosorber according to claims 4-6, characterized in that the container is filled with 10% gravel, 20% activated carbon and 10% by volume (based on the volume of the biosorber).