CZ280354B6 - Reactor vessel for waste water bio-aeration - 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

Reactor for biological waste water treatment

Technical field

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a biological wastewater reactor combining an activation space in a tank and an upwardly extending fluid filtration separation space with an internal circulation circuit between the separation space and the activation space.

BACKGROUND OF THE INVENTION

The known reactors are adapted to the biological wastewater treatment process, a significant part of which is nitrification, which requires the presence of nitrifying bacteria in the activated sludge. This requires sufficient sludge age, with virtually complete nitrification being achieved with a sludge load of 0.12 kg of biological oxygen demand in five days (BOD ₅ ) per kilogram of activated sludge biological recovery. In addition, nitrification processes require a sufficient concentration of dissolved oxygen. 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.

One of the known solutions 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 sludge is poorly effective and causes a low operating concentration in the activation portion. The need for a low load of activated sludge results in large volumes of activation space.

A significant drawback of the circulation systems is also the high sludge index of activated sludge due to insufficient release of bubbles of nitrogen gas adhering to the activated sludge particles during denitrification, which results in a significant reduction in plant capacity.

Another disadvantage of combining the three functions, ie, aeration, source of activation mixture activation, and mixing of the waste water mixture with the activation mixture, is that this combination brings a reduction in denitrification efficiency for wastewater with higher nitrogen contamination content, namely

Due to the lack of carbon source required for the denitrification processes in the denitrification section.

The aforementioned known denitrification solution has shortcomings both for the construction of new wastewater treatment plant buildings and for the reconstruction of already existing classic-type wastewater treatment plants which no longer meet the increased requirements for the quality of treated water in terms of removal of eutrophication elements.

These drawbacks have been largely eliminated by a solution that creates a progressive flow circulation circuit in the activation space, while the thickened activation mixture descending from the separation spaces is fed to the beginning of the circulation circuit. Raw water is also fed to the same location. The activation mixture entering from the activation space into the separation space is provided in the upper part of the activation space wall. This arrangement has increased the efficiency of the biological cleaning process, but the separator walls are still relatively complicated and expensive to manufacture.

It is an object of the present invention to overcome the disadvantages of the known solutions to the greatest extent possible and to provide a device enabling a substantial intensification of biological activation wastewater treatment using a progressive circulation circuit that improves the hydraulic conditions in the separators while simplifying the construction of reactor wastewater treatment installations.

SUMMARY OF THE INVENTION

The disadvantages of the known solutions are largely eliminated by the biological wastewater treatment reactor, which is based on the separation space being connected to the activation space by a passage in the partition wall of the separation space at the bottom of the tank. with inlets for thickened activation mixture, which is connected to a pump set whose outlet is connected to the activation space.

In order to create a circulation circuit, it is essential that a flow circuit channel and a distribution channel are formed in the activation space and are connected passageously to the separation space.

In order to prevent the effect of the flow in the distribution channel of the activation space on the flow in the separation space, it is important that in the passage area at least one current rectifier is assigned to the partition on the side of the activation space.

For a higher intensity of the denitrification process, it is beneficial that a mixer is provided at the beginning of the activation space into which the outlet of the pump set is connected, the raw wastewater inlet is connected to the mixer and the outlet from the mixer is connected to the adjacent part of the activation space.

For the possibility of cleaning the manifold, it is essential that the pump set consists of a pump equipped with a submersible reverse electric motor.

For the possibility of removing the electric motor and part of the pump set it is beneficial that the reverse electric motor and the pump impeller

-2GB 280354 B6 are slidably mounted on the guide bars.

In order to maintain the optimum manifold length, it is advantageous that the pump set is connected to at least two manifold branches.

For the possibility of intermittent or regulated air supply, it is important that aeration hoses are provided in the activation space, which are connected to a source of compressed air by means of a closure or regulator.

In order to increase the utilization of air oxygen by the activation mixture, it is important that the aeration hoses are arranged in two branches which are arranged on opposite sides of the cross section of the peripheral channel.

Limiting the connection of the activation space to the separation space to a single passage at the bottom of the tank significantly simplifies the implementation of the separation space inserted into the activation space. This makes it possible to use a self-supporting shell structure which consists of only two elements, i.e. two partition walls, to create a separation space. These walls are attached directly to the bottom of the tank and with the other upper end to a supporting structure (not shown).

The small cross-sectional area of the peripheral channel and distribution channel, together with the intense gradual flow due to the circulation of the activation mixture in the inner circulation circuit, creates favorable conditions for suspending the activated sludge. At the same time, intense turbulence in the pump set removes nitrogen gas bubbles adhering to the activated sludge particles in the denitrification process.

The ability to inspect the equipment, repair the submersible motor and clean the manifold while the equipment is in operation increases the reliability of the entire equipment.

The independence of the flow in the circulation system from the aeration system permits time-varying aeration of the activation mixture in the circulation circuit, resulting in an intensification of the denitrification processes.

The possibility of regulating the aeration intensity and the use of a pump set for the recirculation of the activation mixture increases the efficiency of the waste water treatment and also brings energy savings.

BRIEF DESCRIPTION OF THE DRAWINGS

An example of the invention is shown in the accompanying drawings, in which Fig. 1 is a rectangular view of a partial cut-off reactor and Fig. 2 is a schematic cross-section of the reactor.

DETAILED DESCRIPTION OF THE INVENTION

In the rectangular tank with the jacket 1, two longitudinal separation spaces 2 are formed by the interposed dividing walls 3 and the faces 6 and 6 ', which widen upwards. The partition walls 3 are preferably fixed in their lower part to the bottom of the tank and with their upper part to the support structure (not shown). The separation spaces 2 form in the tank between the dividing walls 3 and the fronts 6, 6 (distribution channel 4 ´)

-3GB 280354 B6 which is part of the activation area. The face 6 of the separation space 2 extends as far as the housing 1, thus forming a partition 5 which separates the peripheral channel 4. The second face 6 'closes not only the separation spaces 2 but also separates the distribution channel 4' from the peripheral channel 4. does not communicate with any other space except distribution channel 4. ' that follows it.

In the opposite face 6, an inlet 24 to the distribution channel 4 'is formed. The separation space 2 is connected to the distribution channel 4 over its entire length. , and thus with the activation space, a single passage 19 at the bottom of the tank. The passage 19 may either be uninterrupted over its entire length or may be provided as a set of openings in the partition 3 of the separation space 2.

The dividing walls 3 preferably have an arcuate shape in section. The partition walls 3 move upwardly from each other, thus forming a prismatic separation space 2 for the fluid filter. The separating walls 2 are spaced apart from each other at the bottom of the tank, and in the space between them there is a perforated manifold 12 located at the bottom, which is connected to the pump unit 25. The separating wall 3 can be made of smooth material or profiled material. It is advantageous to perform profiling in the top-down direction, whereby low ribs are formed on the surface of the partition walls 2.

in the area of the passage 19 to the partition 2 from the side of the activation space, i. at least one current rectifier 20 is provided on the side of the distribution channel 14 '. It is intended to shield the flow of the activation mixture in the distribution channel 4 'from the flow inside the separation space 2. The rectifier 20 is preferably fixed to the partition 2, is oriented vertically and extends substantially along the entire length of the partition 2. The rectifier 20 is located at the lower part of the partition wall 3, its lower edge is situated somewhat above the lower edge of the partition wall 2 / but at most reaches the level of the lower edge of the partition wall 2 · ^J ® but also possible omit this rectifier 20 completely. When applied, the rectifier 20 limits the transfer of vortices from the activation area to the separation area. Its efficiency may be somewhat higher for profiled partition walls 2 or even for smooth partition walls, where profiling is performed only in the region of attachment of the baffle 20, where it is attached to the projections of the partition wall 2 ^and thus does not lie close to the entire contact area. This brings a small portion of the activation mixture between the rectifier 20 and the partition wall 2 into the passage area 19 and promotes the reduction of vortex transmission from the distribution channel 4 'of the activation space.

The pump assembly 25 consists of a pump housing, into which the manifold 12 is connected and which is fixed to the bottom of the tank, and a pump impeller connected by a shaft to a submersible electric motor, which is preferably reverse. The rotating parts of the pump assembly 25 are supported with the possibility of being pulled above the level of the reactor during its operation. For example, the pump impeller, which is rotatably mounted in its carrier (not shown), is slidably supported by this carrier on guide rods (not shown) positioned perpendicular to the bottom of the tank. A lifting device on which the support is suspended is mounted on a structure above the reactor, also not shown.

-4GB 280354 B6

The collecting pipe 25 from the other separation space 2 also opens into the pump set 25, so the pump set 25 is common.

In the case of a large length of the separation spaces 2, the pump set can advantageously be placed in the middle of the length of the distribution channel 4 '.

In this case, four manifolds 12 from the two adjacent separation spaces 2 are connected to the pump set, two and two from each side. With a long reactor length, it is possible to arrange a plurality of pumping units one after the other so as to achieve a collecting pipe length of 12 meters or less, which is the optimum length for the collecting system.

The drive train of the pump assembly 25 is a submersible electric motor 26. A lifting device (not shown) is mounted on a support structure (not shown). The reversible electric motor 26 and the impeller of the pump assembly 25 are slidably mounted on guide rods arranged perpendicular to the bottom of the tank. By means of this lifting device it is possible to pull the submersible reverse electric motor 26 and the pump assembly 25 on the guide rods (not shown) even without draining the tank. The pump set 25 and its drive are adapted to reverse rotation to reverse the activation mixture in the 12 sběr manifold.

At the beginning of the distribution channel 4 ', i.e. at the beginning of the activation space, a mixer 31 is provided for mixing the activation mixture with the raw waste water. The outlet 28 of the pump assembly 25 is led beyond the partition 5 to the beginning of the perimeter channel 4 into the mixer 31 into which the raw waste water inlet 13 is also connected.

The interconnection of the peripheral duct 4, the distribution duct 4 ', the separation space 2 and the collecting system formed by the collecting pipe 12 and the pump set 25 forms an internal circulation circuit. It follows from the described arrangement that the manifold 12 could also be referred to as recirculating because it activates the activation mixture back into the circulation circuit.

The peripheral duct 4 and the distribution duct 4 'are provided with an aeration system consisting of a series of perforated elastic aeration hoses 32 connected to a common compressed air manifold 29. The apertures (not shown) in the perforated aeration hoses 32 are preferably small to produce fine aeration bubbles. Each of the aeration hoses 32 is provided with a separate cap 30 or a regulator (not shown) to control the aeration rate. By placing a different number of aeration hoses 32 at different locations in the peripheral duct 4 and the distribution duct 4 ', the aeration intensity can also be influenced according to the cleaning process. Further regulation of the aeration intensity versus time can be achieved by the use of a variable speed blower (not shown), possibly by using a plurality of blowers and actuating them according to the need for aeration. In a preferred arrangement of the aeration hoses 32 in the peripheral channel 4 of the activation space, the aeration hoses 32 are disposed in two branches, each branch of which may comprise several aeration hoses 32. These branches are disposed on opposite sides of the cross section of the peripheral channel 4, usually near the bottom of the tank .

The upper part of the separation space 2 is provided with overflow troughs 33 for draining the purified water after filtration in the fluidized bed.

-5GB 280354 B6

The described apparatus operates as follows:

It is a function of an integrated reactor for biological water purification, where separation spaces 2 for separating the activated sludge suspension by fluid filtration are inserted into the activation space. By incorporating the separation spaces 2, a system of channels is provided which are connected in series-in a row-as described above.

The peripheral duct 4 and the distribution duct 4 'have a preferred shape, which creates favorable conditions for suspending the activated sludge.

The raw waste water is fed via a feed line to the mixer 31 at the beginning of the perimeter channel 4 downstream of the baffle 5, where the recirculated activation mixture is also fed from the separation spaces 2 through the pumping unit 25. In the mixer 31 . The introduction of the organic substances contained in the raw waste water into the stream of the activation mixture causes a sudden decrease in the dissolved oxygen content, thereby creating anoxid conditions for denitrification processes at the beginning of the peripheral channel 4.

Activated sludge suspension in this anoxide portion of activation is maintained by aeration at a very low intensity, which is sufficient to maintain the suspension in buoyancy, but does not disrupt the anoxide conditions for the course of denitrification. Therefore, the number of aeration hoses 32 in this part of the circumferential channel 4 is reduced. In order to improve the suspension, it is possible to equip this part of the peripheral channel 4 with a mechanical mixing source (not shown), which makes it possible to completely omit the aeration of this part of the activation.

The course of the denitrification process is controlled by measuring the parameters of the activation mixture by means of probes (not shown) that transmit impulses to the blower drive train. This changes the rotation speed and the amount of air supplied. With reduced aeration intensity, the denitrification zone in the peripheral channel 4 widens, thereby increasing the intensity of denitrification. This process can be fully automated.

As the activation mixture gradually flows through the peripheral channel 4, the dissolved oxygen content in the activation mixture gradually increases due to increasing aeration intensity and a decrease in biodegradable substances. This creates an oxidizing environment for aerobic activation processes of biodegradation of organic substances and for nitrification of ammonia and organic nitrogen. If the aeration hoses 32 are arranged in two branches located on opposite sides of the cross-section of the circumferential channel 4, it is possible by means of the closures 30 or regulators (not shown) to supply air alternately to one branch and then to the other branch. When the air is supplied, for example, to the left branch, a transverse circulation movement of the activation mixture occurs. When the air supply to the left branch is interrupted and the air is supplied to the right branch, a countercurrent of the air and the activation mixture is created, which continues its inertial lateral circulation by inertia until it stops moving under the flow of air and starts to rotate again. These cycles can be repeated periodically by means of regulation. This increases the residence time of the air in the activation mixture, which increases the oxygen transfer to the activation mixture. Another effect of the air and oxygen countercurrent is a more efficient suspension of activated sludge.

-6GB 280354 B6

In the distribution channel 4 'prior to collection into the separation chamber 2, the aeration rate can be adjusted so that the dissolved oxygen content entering the fluid filter layer in the separation space 2 completely ensures oxidation conditions throughout the separation process.

The short residence time of the activation mixture in the separation space during fluid filtration also contributes to achieving optimal oxidation conditions by fluid filtration separation due to the small volume in which the separation takes place. This results from the prismatic shape of the separation space 2 and the high filtration rate in the fluid filter.

The described process of activating biological treatment with alternating oxide and anoxide conditions in the circulation circuit causes accumulation of phosphorus from the waste water into the activated sludge. Subsequent separation of excess activated sludge in the separation space prevents strict adherence to oxidic conditions to prevent the accumulated phosphorus from being released back into the purified water. This achieves a high efficiency of the biological purification process also in the removal of phosphorus from the waste water. Purified water is removed by troughs 33 after passing through the fluid filter.

As already described, the separation space 2 is connected to the distribution channel 4. ' only one passage 19 in which a baffle 20 or a plurality of baffles 20 are provided. This simple solution of the activation mixture entry into the separation space 2 is enabled by the intensive recirculation of the activation mixture in the circulation circuit with its collection at the bottom of the separation space 2. through the collecting line 12. The circulation intensity of the activation mixture in the circulation circuit also affects the efficiency of denitrification processes according to (100 - Γ [%]) = ------- X 100, n + 1 n

or otherwise expressed 7 * [%] = ------ ^x 100, η + 1 where denotes the denitrification efficiency in percent and the flow rate ratio in the circulation circuit, for example, in the distribution channel 4 'to the amount of raw water supplied over the same period of time.

-7EN 280354 B6

From the bottom of the separation space 2, the activated sludge trapped in the separation space 2 is sucked off by fluidized-bed filtration together with the circulating activation mixture from the distribution channel 4. ' activation, ie from the activation process. The flow intensity at the bottom of the separation space 2 due to the recirculation of the activation mixture prevents perturbation from the aerated distribution channel 4 'to the separation space 2. This ensures the stability of the filter bed in the separation space 2 and high separation efficiency.

Limiting the connection of the activation space to the separation space to a single passage 19 at the bottom of the tank greatly simplifies the implementation of the separation space 2 inserted into the activation space. This makes it possible to use a self-supporting shell structure which consists of only two elements, i.e. two partition walls 2, to form a separation space 2. These walls are fastened directly to the bottom of the tank and the other upper end to a support structure (not shown).

The system of connecting a plurality of manifolds 12 to one pump assembly 25, or the use of a plurality of pump assemblies 25, allows the optimal length of the manifold 12 to be maintained even for large wastewater treatment plant capacities where the separation space 2 can reach several hundred meters.

The reverse operation of the pump set is used to clean the manifold 12 with a backflow of water.

Industrial applicability

The reactor according to the invention is suitable for the treatment of waste water, in particular for the treatment of municipal waste water in large capacity installations.

Claims (9)

A biological wastewater treatment reactor comprising an activation space in a tank and an upwardly extending fluid filtration separation space with an internal circulation circuit between the separation space and the activation space, characterized in that the separation space (2) is connected to the passage activation space ( 19) in the separating wall (3) of the separation space (2) at the bottom of the tank, wherein in the separation space (2) at the bottom of the tank there is a manifold (12) with inlets for the thickened activation mixture connected to the pump set (25) ), whose outlet (28) opens into the activation space. Reactor according to claim 1, characterized in that a flow perimeter channel (4) and a distribution channel (4 ') are formed in the activation space and connected to the separation space (2) by a passage (19). -8EN 280354 B6 Reactor according to claim 1, characterized in that in the region of the passage (19), at least one current rectifier (20) is associated with the partition (3) on the side of the activation space. Reactor according to claim 1, characterized in that at the beginning of the activation space there is a mixer (31) into which the outlet (28) of the pump set (25) is connected, the raw inlet (13) of the raw material (13). the effluent and the outlet of the mixer (31) is connected to the adjacent part of the activation space. Reactor according to claim 1, characterized in that the pump set (25) is a pump provided with a submersible reverse electric motor (26). Reactor according to claim 5, characterized in that the reverse electric motor (26) and the pump set (25) are slidably mounted on the guide rods. Reactor according to claim 1, characterized in that the pump set (25) is connected to at least two branches of the manifold (12). Reactor according to claim 1, characterized in that aeration hoses (32) are arranged in the activation space, which are connected to a source of compressed air by means of a closure (30) or a regulator. Reactor according to claim 8, characterized in that the aeration hoses (32) are arranged in two branches which are arranged on opposite sides of the cross-section of the peripheral channel (4).