CZ279589B6 - Method of waste water biological treatment by using activated sludge and equipment for making the same - Google Patents

Abstract

Purification of waste water by biological activation includes a nitrification stage. The activation mixt. is brought into the circulation circuit as a plug flow and the purified water is passed through a fluidised bed filter. The activation mixture is then mixed with raw waste water to bring about denitrification processes. The final mixt. is aerated to keep the activated sludge in suspension and gradual oxygen saturation lead to purificn of the added waste water. The basic process module takes the form of a rectangular tank with concrete walls (1) and the base (8) divided by a series of partitions (2) into spaces for biological activation waste water purification processes and for flocculant suspension separation by a fluidised bed filter.

Description

A solution in which wastewater is biologically purified by the nitrification activation process. The activation mixture is circulated with a flow characteristic, from which purified water is removed by fluid filtration, and after this removal of the purified water, the activation mixture is mixed with raw waste water, causing an oxygen deficiency on the surface of activated sludge particles causing denitrification processes. The resulting mixture is subjected to aeration which keeps the activated sludge suspended and during gradual flow leads to gradual oxygen saturation. The device always comprises two separation spaces (4) arranged adjacent to each other by longitudinal sides in which communication connections are made with the activation space and a longitudinal distribution channel (5) formed between these longitudinal walls. It is completely closed at one end by the front wall (6). at the opposite end it has a passageway (26) through which it is connected to the flow channel system (7).

BACKGROUND OF THE INVENTION Method of biological activation wastewater treatment and apparatus for its implementation

Technical field

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for the biological activation of wastewater, wherein the wastewater is biologically treated by an nitrification activation process. The invention also relates to an apparatus for carrying out the method, which comprises, in a common tank, an activation space and upwardly extending longitudinal separation spaces from which the purified water drains are led, and each separation space being delimited by partition walls and faces and communicating on one longitudinal side with an activation space, wherein separate longitudinal channels are formed between the separation walls of the separation spaces and between the separation walls and the tank walls, in which the aeration elements are located.

BACKGROUND OF THE INVENTION

Effective protection of surface waters, including the seas, from eutrophication requires the most efficient removal of macrobiogenic elements of nitrogen and phosphorus, the content of which in wastewater is a major cause of the phenomenon of eutrophication. Therefore, all wastewater treatment systems must take this nitrogen and phosphorus removal requirement into account.

Known and used wastewater treatment systems with a simultaneous reduction of nitrogen content are oriented towards the biological processes that appear to be the most economical. All of these processes require first to convert the oxidizable form of nitrogen, i.e., ammonia and organic nitrogen, into the nitrate form by nitrification processes. This is followed by reduction of nitrates to nitrogen gas by denitrification processes.

Nitrification requires the presence of nitrifying bacteria in activated sludge, requiring sufficient aging of the sludge to achieve virtually complete nitrification at a sludge age of 30 days, equivalent to a sludge load of 0.12 kg of biological oxygen consumption in five days per kg of activated sludge biological recovery multiplied number of days, hereinafter referred to as BOD ₅ / kg ZNNL. day. In addition, nitrification processes require a sufficient concentration of dissolved oxygen, typically above two milligrams of oxygen per liter of activation mixture - hereinafter referred to as 2 mg 0 ₂ / l activation mixture. Subsequent denitrification takes place in the absence of dissolved oxygen in the activation mixture, where the biocenosis microorganisms obtain the necessary oxygen by reducing nitrates.

Three basic variants of the technical solution of the system for complex biological water purification with simultaneous nitrification and denitrification are known.

The first variant is discontinuous denitrification. In this solution, the nitrification and denitrification phases of the activation purification periodically alternate with intermittent aeration. The disadvantage of this solution is the reduced efficiency of the discontinuous process compared to the continuous, complex process control

Activation of activated sludge at the time of interruption of aeration.

Another variant is upstream denitrification. In this solution, a separate denitrification in the form of a perfectly mixed tank with an intensive mixing source to ensure sludge suspension is upstream of the aerated activation. The pre-denitrification is fed with waste water along with the recirculated activation mixture from the aerated activation. The disadvantage of upstream denitrification is the need to create a separate denitrification zone of activation with an autonomous source of movement of the activation mixture to ensure suspension of the activated sludge. Another disadvantage is the unused area of the denitrification area for the separation of activated sludge, which in municipal wastewater represents up to 25 percent of the reactor volume and area.

The third known variant of denitrification in biological water purification is denitrification in the circulation circuit of the type of oxidation ditches or carousels. In this case, the aeration, mixing of wastewater with the activation mixture and the source of movement of the activation mixture in the purification system are combined into a single organ in the form of a mechanical aerator. As the activation mixture flows through the circulation circuit in the zone downstream of the mechanical aerator, the activation mixture is saturated with dissolved oxygen, thereby nitrifying and gradually consuming oxygen through the oxidation processes of biodegradation and nitrification decreasing the oxygen content of the activation mixture. denitrification process.

This technical solution of denitrification has many drawbacks. Mechanical aeration requires flat, deep tanks that occupy many construction sites. The surface of the tank at the surface is not used to separate the activated sludge, which requires adding a separate separation device to the activation device, which further increases the built-up area requirements and thus the investment costs. The associated separate separation with forced recirculation by sedimentation of the separated channel is poorly effective and causes a low operating concentration in the activation portion. The need for a low load of activated sludge with a sludge age of thirty days then results in large volumes of activation space.

Claims (22)

A method of biological activation wastewater treatment, wherein the wastewater is biologically treated by an nitrification activation process, characterized in that the activation mixture containing at least partially activated wastewater including biomass with microorganisms is circulated with a sequential flow characteristic from which purified water is removed by fluid filtration and the activated sludge mixture is mixed with raw waste water after this treatment, causing an oxygen deficiency on the surface of activated sludge particles causing denitrification processes, and the activated sludge kept suspended and during In a sequential flow, the activation mixture is saturated with oxygen, gradually moving from denitrification to nitrification while purifying the effluent, while the nitrates formed by the nitrification are returned to the denitrification process with the activation mixture, thereby b All processes of complex wastewater treatment will take place in one cycle. Method according to claim 1, characterized in that in the same period of time the amount of purified water withdrawn from the circulation by fluid filtration is less than the amount of activating mixture circulating in the circulation. 3. The process of claim 1, wherein the activation mixture mixed with the raw effluent is successively oxygenated by aeration while suspending the activated sludge until a concentration of dissolved oxygen in the activation mixture of at least two milligrams of oxygen per liter of activation mixture is reached. Method according to claim 1, characterized in that the aeration is carried out by means of pneumatic aeration of varying intensity in terms of time and / or location in the circulation circuit. Method according to claim 1, characterized in that the circulation flow of the activation mixture is at least twice the consumption of purified water. 6. The method of claim 1, wherein the activating mixture is recirculated to the circulation by supplying raw waste water, draining the purified water, and forcing the separations of the thickened activating mixture to be circulated beyond the separation zone. 7. The process of claim 1 wherein the purified water is removed by fluid filtration from a portion of the circulating activation mixture. An apparatus for carrying out the method according to claim 1, comprising in the common tank an activation space and an upwardly extending longitudinal separation space from which the purified water outlets are led, and each separation space being delimited by partition walls and faces and communicating on one longitudinal side with activator Separate longitudinal ducts are formed between the separation walls of the separation spaces and between the separation walls and the walls of the tank, in which the aeration elements are located, characterized in that two separation spaces (4) are arranged adjacent to each other. the longitudinal sides in which communication connections with the activation space are made and the longitudinal guide channel (5) formed between these longitudinal walls is completely closed at one end by the end wall, while at the opposite end it has a passage connecting it to the flow channel system (9) 7), laterally separated from the separation space (4), and the flow channel system (9, 7) and the at least one distribution channel (5) form part of the circulation circuit, the other part of the circulation circuit forming a collecting device connected to the activation mixture outlet separační prosto (4), and at least one pumped aggregate is connected to this collecting device, the outlet of which forms the beginning of the circulation circuit, the raw water inlet being connected either to the inflow or outflow region of the pumping aggregate and having at least one circulation circuit by a baffle (28). Apparatus according to claim 8, characterized in that the collecting device is located at the bottom of the fluid filtration separating space (4), the communication connection with the activation space being formed by the upper passage (10) and the lower passage (11), both of which are located on the same side of the separation space (4), the upper passage (10) follows the extension of the separation space (4) and the lower passage (11) is at its bottom, the upper passage (10) being smaller than the lower passage (11), it creates an upstream resistor for the activation mixture flow. Apparatus according to claim 8, characterized in that the circulation circuit is formed by at least one basic module, in which a distribution channel (5) is formed by two inner dividing walls (2) and the outer dividing walls (2) each form together with the inner by means of a dividing wall (2) a separation space (4), on the one hand with the peripheral wall (1) of the tank or the outer wall of another module, a circumferential flow channel (7), the distribution channel (5) being frontally connected to the circumferential flow channel (7) and laterally with separation space (4). Apparatus according to claim 8, characterized in that in the circulation circuit there is a collecting well (35) provided with a pump (36) into which the outlets (27) of the collecting device supplying the activation mixture and the outlet (27 ') from the pump ( 36) is connected to the partition (28) at the beginning of the flow channel (7) · Device according to claim 11, characterized in that a raw waste water inlet (22) is connected to the collecting well (35). Device according to claim 10, characterized in that additional modules of the same design are perpendicularly assigned to the base module. -18GB 279589 B6 Apparatus according to claim 10, characterized in that the base module is arranged with an axis passing through the center of the tank and the additional modules are arranged symmetrically to and perpendicular to the base module. Device according to claim 14, characterized in that at least one additional module parallel to it is associated with the base module, the system of parallel modules thus formed being symmetrical about an axis passing through the center of the tank. Apparatus according to claim 8, characterized in that the aeration elements (3) are arranged at a greater distance in the area of the raw waste water supply than in the following parts of the circulation circuit. Apparatus according to any one of claims 8 to 16, characterized in that the cross-sectional area of the inlet passage (14) into the fluid filter is greater than 10% of the surface area in the separation space (4). Device according to claim 8, characterized in that the collecting device is provided with at least one pump. Apparatus according to claim 18, characterized in that the pump is designed as a centrifugal pump (36) and is optionally located in a collecting sump (35). Device according to any one of claims 8 to 19, characterized in that the fluid filtration separation space (4) is arranged along the entire length of the circulation circuit channels (5, 9), the inlet of the activation mixture into the fluid separation space (4). the filtration and collecting means for draining the thickened activation mixture from the separation space (4) are provided along its entire length. Apparatus according to claim 8, characterized in that a float sludge trap (29) is formed in the upper part of the separation space (4), which is formed by an inclined roof, to whose lower side a compressed air supply (38) and a higher side are connected. is provided with a flotation sludge outlet in the form of a mammoth pump (39), which opens into the activation area, the entire roof being below the level of the tank. Apparatus according to claim 21, characterized in that the canopy comprises a horizontal base part and an inclined extension (40) connected thereto.