LT5386B - Device for treating sewage - Google Patents

Abstract

The invention relates to devices for treating sewage. A device of activating process for treating sewage comprises a container with activating space, which includes unairing anaerobic and anoxic zones and airing oxygen zone, space for sedimentation of silt and retention space, wherein between activating space zones is made reprocess and processed sludge is reprocessed between activating space and a silt precipitate space, characterized in that a container (1) with a bottom (2), an outer hood (3) and a cover (4) is divided in unairing activating space (8), an airing activating space (9), a silt sedimentation space (10) and a retention space (25). An unairing activating space (8) from an airing activating space (9) is separated by dividing wall (5), which extends from bottom (2) of container (1) up to a cover (4) and includes permeable opening (11) in a level of a bottom (2) of a container (1) and of a pipe (12) of a container (1). A silt sedimentation space (10) inside an airing activating space (9)

Description

The invention relates to a device for continuous biological treatment of wastewater from minor sources of pollution. During the modified activation process, one container contains an activation space with spatially distributed anaerobic, anoxic, and oxygen zones, a sedimentation space, and a retention space. Recycling takes place between the activation space zones and between the activation and sediment deposition space.

Overview of the Related Art

Small wastewater treatment plants are used to treat wastewater from sources that cannot be connected to public sewerage networks. The treatment of wastewater from minor sources is a complex problem, as the diversity of the effluent and the diversity of pollution from these minor sources need to be addressed. Because of the relatively short lengths of sewerage collectors, the quantity and quality of the wastewater does not equal, and the individual technological steps of the wastewater treatment process (tank leveling, mechanical, biological and, if necessary, auxiliary treatment) must be adapted so that they are continuous. and that the required retention time is not exceeded and that the surface does not become entangled in the sediment deposition space. Unless conditions are created for equalizing the quantity and quality of wastewater, these steps must be clearly foreseen in advance. Wastewater treatment plants are defined by the average amount of wastewater discharged Q ₂ 4. The irregularity of hourly wastewater is expressed by another defined amount of wastewater - the maximum amount of wastewater discharged per hour Q max ·

DE4307288 describes a device for biological treatment of wastewater, which does not have any specially designated leveling vessel. The effluent discharged is discharged into the collection tank, the activation tank and the sedimentation tank, if necessary, in the dam or in the entire sewage treatment plant. In order to equalize the amount of waste water, the waste water is continuously pumped out of the sedimentation tank until a certain lower water level limit is reached in the sedimentation tank. The suction is then stopped until the discharge reaches a higher level.

Likewise, the wastewater treatment plant described in U.S. Pat. No. 3,886,065 does not have a separate isolation tank. Alignment occurs in the collection, activation, and sedimentation tanks. Sewage from the sedimentation tank is continuously pumped through pipes below their surface to another tank.

DE 199 16 381 A1 discloses a small biological-chemical wastewater treatment plant, in which the quantity and quality are also equalized in the collection and activation space, but without diverting the collected wastewater to another container. The volume of the same tanks is used to accommodate a larger volume of wastewater. After biological treatment, the wastewater is transferred to one of the other pumps by one or two pumps, and new wastewater is constantly introduced. The pump mode is set to exceed the average daily discharge, but remains low enough to minimize pump shutdown intervals.

In all of the above solutions, the amount and quality of the effluent is equalized simply in the activation space or in the activation space and other functional tanks or treatment plant rooms that do not specifically separate the leveling tank, but equalize by suction, resulting in additional costs and increased failure.

An alternative option for wastewater treatment, with a significant change in the incoming wastewater and its composition, is the sequencing batch reactor (SBR). This system uses two or more batch reactors: Filling, Cleaning, Assembly and Disposal. SBR systems undergo all cleaning processes, including equalization of composition and volume in one container. Unlike multi-reactor continuous systems, it is difficult to maintain conditions for completely different processes such as nitrification and denitrification in the same container. It is difficult to determine the duration of a particular process (eg nitrification) with different inputs and different compositions of wastewater, so these reactors have to be set up for the worst case scenario, resulting in the pre-definition of SBR reactors.

Requirements for the quality of treated wastewater discharged from small treatment plants are also constantly increasing. In the case of treated wastewater discharging into eutrophically sensitive areas, or discharged wastewater into groundwater or recycling, high efficiency and stable efficiency of wastewater treatment plants, even for small sources of pollution, must always be ensured.

In such cases, small treatment plants must ensure that nitrogen and phosphorus are removed from the effluent. Large wastewater treatment plants use modified activation processes, such as UCT PROCES, developed at the University of Cape Town for the biological removal of nitrogen and phosphorus from wastewater, with the appropriate sequencing of processes in the anaerobic, anoxic and oxygen zones. This process has been modified to MUCT PROCES (modified UCT). These processes create more anoxic zones and recycle activated sludge into one of the anoxic zones rather than the anaerobic one. The activated mixture is recycled to the anaerobic zone, where nitrogen compounds have been removed by internal processing in the anoxic zone. The obvious disadvantage of these processes is the high cost of the mechanical suction unit - the pumps used to recycle the sludge, to recycle the activated mixture between oxygen and anoxic space and to recycle the activated mixture between anoxic and anaerobic space. Another disadvantage is the cost of mixing non-ventilated anaerobic and anoxic spaces using mechanical equipment - submerged mixers. Until now, these processes have not been carried out in small wastewater treatment plants, since tanks need to be distributed internally to a large number of unventilated and ventilated areas, and mixing techniques to mechanically mix the contents of non-ventilated spaces are expensive.

Designing and implementing small wastewater treatment plants requires that small wastewater treatment plants be easily transported or installed at the right location and that construction work is simple, that external shapes can be easily adapted to the circumstances or location, and that the plant can be modeled and expand with increasing wastewater volumes. Small wastewater treatment plants with integrated retention space in the current state of the art do not meet all of these requirements.

The object of the present invention is to design a wastewater treatment plant designed for small wastewater sources so that it can be made into a single compact system whose shape and models can be modified using simple concrete movable structures and lightweight thermoplastic wall or structural elements, so that one functional system balances the varying amount of wastewater discharged, while achieving the highest possible efficiency in biological wastewater treatment with nitrogen and phosphorus removal at low cost for suction and mixing techniques.

The essence of the invention

A modified activation process unit for continuous wastewater treatment, with a single space containing an anaerobic and anoxic zone and a ventilated oxygen zone, a sedimentation space and a retention space for recycled sludge, meet the stated objectives and largely address the shortcomings of known devices. between the activation and sediment deposition space installed in accordance with the present invention. Its essence is that the container, consisting of the bottom, the outer enclosure and the roof, is divided into a non-ventilated activation space, a ventilated activation space, a sedimentation sedimentation space and a retention space - such that the non-ventilated activation space from the ventilated activation space is a dividing wall of the roof having a penetrating opening at the bottom of the tank or at the level of the outlet pipe. The sedimentation space inside the ventilated activation space is separated by a hood extending from the bottom to the roof of the container and having a permeable opening located at the bottom level of the container. The retention space is separated in the container between the level of the tank outlet pipe and the tank inlet pipe across the entire tank area above the non-ventilated activation space, ventilated activation space, and sediment settling space. The non-ventilated space is divided by at least five dividing walls arranged in a continuous flow direction from the bottom to the roof of the container. They have permeable openings arranged in alternating order: at the bottom of the tank and at the level of the outlet. In the sediment deposition space, a flow regulator is installed on the tank outlet pipe.

In order to create anaerobic and anoxic conditions in the non-ventilated activation space, it is essential that there are at least five internal walls, which distinguish one anaerobic zone and two anoxic zones within the non-ventilated activation space between the activation zone and the processing sludge recycling path between activation and sedimentation. of space.

The intermittent arrangement of permeable openings on the inner partition walls in a consistent flow direction through the non-ventilated activation space is essential for mixing the contents of the unventilated activation space, creating conditions for ideal mixing of the non-ventilated activation space content without the use of mechanical agitators.

To effectively equalize fluctuations in the amount of untreated wastewater entering the wastewater treatment plant, it is essential that the throttle effect of the wastewater regulator on the outflow of the unit increase the amount of wastewater discharged above the average defined amount of wastewater Q24 in the whole tank, from the water level corresponding to the discharge pipe to the water level corresponding to the discharge pipe or the safety level. Meanwhile, the inner partition walls in the non-ventilated activation space, the wall between the ventilated activation space and the non-ventilated activation space and the sedimentation deposit enclosure will prevent unrestricted mixing of the contents of individual spaces and zones as it reaches the highest possible water level in the tank cleaning processes can also run smoothly in the retention space.

In order to be able to model and adapt the treatment plant to the ever increasing amount of wastewater, it is useful that the modified activation process unit for continuous wastewater treatment according to the invention comprises: a rectangular bottom container, an outer enclosure and a roof. The non-ventilated activation space is provided with internal partition walls extending from the bottom of the container to the roof of the container and having passageways arranged alternately at the bottom of the container and at the outlet level in a sequential direction - one row or two or more rows separated by a water wall.

The device for continuous treatment of wastewater by a modified activation process can be purposefully realized in a round perimeter container with a bottom, an outer hood and a roof. According to the invention, the container of the device may also be polygonal, e.g. rectangular or hexagonal, where the container is divided by one concentric wall of a circular or polygonal perimeter into a non-ventilated activation space and a ventilated activation space at the level or bottom of the container outlet. . In the non-ventilated space, the inner partition walls extending from the bottom of the tank to the roof in the form of a ring are provided with permeable openings arranged alternately at the bottom of the tank and at the outlet pipe in a consistent flow direction.

According to the invention, monolithic or poured concrete containers made of water-suitable concrete having a perimeter round or having four or more angles with a bottom, an outer enclosure, a wall between a non-ventilated activation space and a ventilated activation space and a baffle made of water suitable for construction concrete, and the inner wall and the sediment cover are made of thermoplastic structural elements based on polyethylene, polypropylene or polycarbonate.

The device according to the invention can also be manufactured using a container having a circumferential circumference or having four or more edges with a bottom, an outer enclosure, a wall between a non-ventilated activation space and a ventilated activation space and baffles made of thermoplastic structural members based on polyethylene, polypropylene or polycarbonate. .

It is important that the throttle orifice and passage pipes inside the regulator are protected from deposits of dirt and activated sludge, so that the controller is easy to operate and maintain. For this purpose, a protective grid, which is periodically rinsed with purified sewage water, is suitable. The flushing mechanism operates by periodically inflating pressurized air or pressurized water through the opening in the hollow chamber of the wastewater regulator chamber, and then pressurized air or pressurized water displaces the purified water in the wastewater regulator into the space between the inlet wastewater regulator inside the pipe flow regulator, primarily through a safety grid, and only when the level of the inlet pipe inlet is reached will the pressurized water or air begin to leak through the throttle. The short-term return pressure of the pressurized water or compressed air / pressurized water mixture thus created is sufficient for the safety net to be cleaned perfectly.

Addressing the present state of the art of small wastewater treatment plants, the present invention provides a device structure for treating wastewater from low-emission sources that can be prepared as a single compact system and can be shaped and modeled using simple concrete movable structures and lightweight thermoplastic wall or structural elements. One functional unit is also sufficient to equalize the varying amount of wastewater and to achieve the highest possible biological purification efficiency by removing nitrogen and phosphorus at low cost for the mixing technique.

Drawing overview

The invention will now be further illustrated by the following exemplary embodiments thereof, which are illustrated in the accompanying drawings, in which:

- FIG. 1 a, b is a device for treating wastewater according to the present invention

- FIG. 2 a, b, c - rectangular perimeter device for wastewater treatment;

- FIG. 3 a, b, c - Round, square or polygonal perimeter for wastewater treatment;

- FIG. 4 - regulator of incoming wastewater.

Examples of application of the invention

Example No. 1

A continuous wastewater treatment device during a modified activation process according to the invention. 1 a, b consisting of container 1 with bottom 2, outer hood 3 and roof 4. The container 1 is divided by a dividing wall 5 into a non-ventilated activation space 8 and a ventilated activation space 9. The ratio of non-ventilated space 8 to the ventilated space is approximately 1: 1, as is apparent from the state of the art in systems for the removal of nitrogen and phosphorus from waste waters containing high levels of unfermented organic carbon. The sediment deposition space 10 is enclosed within the sediment deposition space enclosure 6 within the ventilated activation space 9. In accordance with the principles of the sediment deposition space 10 for activated sludge used in practice, the structures have a enclosure 6 in the form of a fully inverted and slit ball or roll (Fig. La) or a partially inverted and slit ball or roll (Fig. Lb). and the angle of the enclosure 6 of the sediment deposition space 10 with the bottom 2 of the container 1 is at least 60 °. The partition wall 5 and the enclosure 6 of the sedimentation space 10 extend from the bottom 2 all the way to the roof 4 of the container 1. The dividing wall 5 has a permeable opening 11 at the level of the outlet pipe 12 or the bottom 2 of the container 1. The enclosure 6 of the sediment settling space 10 has a permeable opening 7 located at the level 2 of the bottom of the container 1. The non-ventilated activation space 8 is divided by a plurality of internal partition walls 13 extending from bottom 2 to roof 1 of container 1. Separate, successive inner partition walls 13 have permeable openings 14 arranged successively at bottom 2 of container 1, at the outlet of container at pipe 12 level. In the sediment deposition space 10, an inlet wastewater regulator 15 is provided below the level of the treated water. 4. Flow controller 15 is a hollow chamber consisting of a hood 16, an inlet 17 and an outlet shroud 18. The inlet 17 is protected by a safety net 19. The outlet shroud 18 has a throttle orifice 20 having a permeability to the outgoing waste water for the average defined amount of waste water entering the wastewater treatment plant Q ₂₄ . Inside the inlet regulator 15 is a flow pipe 21 whose inlet 22 is immediately behind the inlet 17 of the inlet regulator 15 and the outlet 23 is connected to the throttle outlet 20. The space between the outlet pipe 21 and the enclosure 16 of the inlet regulator 15 is water. An outlet 24 is provided in the enclosure 16 of the inlet wastewater regulator 15 after the outflow cover 18, through which a fluid-pressurized substance, such as pressurized air or pressurized water, enters. Sediment deposition space 10 is equipped with the safety threshold of 30, to stop leakage when their number increased up to the maximum amount of sewage Q _m ax · on the safety threshold of 30 purified water flows into the outlet, or drag container not shown in the figures.

The retention space 25 in the container 1 is marked between the level 12 of the outlet pipe 12 of the container 1 and the level 26 of the inlet pipe 1 of the container 1 over the entire area of the container 1, i.e., above the un ventilated activation space 8, ventilated activation space 9 and sedimentation space 10. The enclosure 6 of retention space 13 and sediment deposition space 10 retains anaerobic, anoxic, oxygen, and separation conditions in the retained space 25 for activated sludge. How the contents of the ventilated activation space 9 interact with the air is known from the prior art. The source of compressed air is not shown in the figures, but the same source also generates compressed air for the air pumps 27, 28, 29 which move recycled sludge from the sedimentation deposit space 10 to the unventilated activation space 8, maintaining circulation between the ventilated activation space 9 and the unventilated activation space 8. and internal circulation inside the un ventilated activation space 8.

The flow of untreated effluent is reduced by flowing inlet pipe 26 into the non-ventilated activation space 8. The activation mixture formed by mixing the untreated sediment water and the recycled activated sludge flows through a row of inner partition walls 13 with alternately arranged permeable openings 14: at level 12 of the outlet pipe. The permeable orifices 14 of varying heights arranged in the flow direction of the sediment entering the dividing walls 13 allow the contents of the non-ventilated space 8, which creates anaerobic and anoxic conditions for activated sludge, to mix ideally and cheaply without the use of mechanical agitators. From the non-ventilated space 8, the activation mixture flows through the permeable opening 11 through the partition wall 5 to the ventilated activation space 9. The activated sludge in the ventilated space 9 maintains oxygen conditions under ventilation. From the ventilated space 9, the activation mixture flows through the permeable opening 7 of the sedimentation sedimentation space 10 into the sedimentation area 10. In the sedimentation space 10, the activated sludge is separated from the purified water by gravity. Activated sludge as recycled sludge is pumped from the sludge settling space 10 into a non-ventilated activation space 8, and the treated water is discharged through the inlet wastewater regulator 15 and the outflow pipes 12 from the wastewater treatment tank 1. Purified water enters the inlet wastewater regulator 15 a network 19 located on the inlet port 17 of the inlet sediment regulator 15, behind the safety net 19 the inlet port 22 of the inlet pipe 21, the pipe tapering at the other end to the throttle opening 20 of the outlet flap 18 via the outlet 1 of the tank 1 the pipe 12 is freely drained of purified sewage water. The function of the inlet wastewater regulator 15 can only flow through the calibrated throttle opening 20 at a flow equal to or less than the average flow Q ₂ 4 for which the area and volume of the sedimentation space 10 is calculated. If the inflow flow is higher, the throttle effect of the inflow regulator 15 raises the water level throughout the tank 1 - from water level A to level B. The inner partition walls 13, the partition wall 5 and the enclosure 6 of the sedimentation area 10 prevent unlimited mixing. the contents of individual spaces. As a result, all wastewater treatment processes can run undisturbed and in the retention space 25.

The throttle orifice 20 and the passage pipe 21 are protected against accumulation of dirt and activated sludge pieces by a safety net 19 which is periodically rinsed with purified sewage water. The flushing mechanism operates by periodically pushing compressed air or pressurized water through the orifice 24 into the hollow tank 18 of the inlet regulator 15 after the outlet. Compressed air or pressurized water displaces the purified water contained in the inlet wastewater regulator 15 primarily through a safety net 19, and upon reaching the inlet 22 of the outlet pipe 21, the pressurized water begins to drain through the throttle orifice 20. The resultant short-term the impact of the air mixture is sufficient for the safety net 19 to be completely cleaned, thus eliminating the need for manual cleaning.

The material of the outer enclosure 3, the bottom 2 of the receptacle 1, the dividing wall 5 and the inner divider walls 13 of the receptacle 1 and the enclosure 6 of the sedimentation space 10 may be made of thermoplastic wall or structural members of polyethylene, polypropylene, polycarbonate or a combination. To facilitate transport, the container 1 may have the same dimensions as the standard outer dimensions of the container. At the destination, the tanks 1 can be joined into larger units immediately or gradually with increasing waste water.

The material of the retaining walls - the outer enclosure 3, the bottom 2 of the container 1 and the dividing wall 5 - can be made of water suitable for water construction, and the inner divider walls 13 and the sedimentation space enclosure 6 can be made of thermoplastic wall or structural elements of polyethylene, polypropylene, polycarbonate, or combinations thereof.

Example No. 2

A modified activation process device for the continuous treatment of wastewater according to the invention in FIG. 2 a, b, c consists of a rectangular perimeter receptacle 1 with a bottom 2, an outer hood 3 and a roof 4. The receptacle 1 is divided by one partition wall 5 into a non-ventilated 8 and ventilated 9 spaces, and the receptacle 1 at outlet 12 or the bottom of the receptacle 1. At the level 2, it has a permeable opening 11. The non-ventilated space 8 has a series of internal partition walls 13 extending from the bottom of the container 2 to the roof 4 of the container having permeable openings 13 alternately arranged at the bottom 2 of the container 1 direction. The walls are arranged in one row (Fig. 2a) or in two or more rows (Fig. 2b). In the case where the inner partition walls 13 are arranged in several rows, they are separated by a water wall 31 so that the principle that the waste water gradually passes through all the inner partition walls 13 and finally passes through the permeable opening 14 into the ventilated activation space 9. More receptacles 1 according to the invention can be connected in parallel to larger units (Fig. 2c). In this way, the capacity of the wastewater treatment plant can be gradually increased as the untreated wastewater flow increases.

Example No. 3

A modified activation process device for the continuous purification of wastewater according to the invention (Fig. 3 a, b, c) consists of a round perimeter container 1 with a bottom 2, an outer hood 3 and a roof 4. The container 1 may also be of regular polygonal shape, e.g. ., square or hexagon. The container 1 is divided by one concentric partition wall 5 having a circumference of circular or regular polygon into a non-ventilated activation space 8 and a ventilated activation space 9 with a permeable opening 11 at the level 12 of the outlet pipe 1 of the container 1 or 2. In the non-ventilated activation space 8, the inner partition walls 13 extend from the bottom 2 to the roof 4 of the container 1 and have openings arranged alternately: at the bottom 2 of the container 1 and at the level 12 of the outlet pipe in a continuous flow.

Industrial use

According to the present invention, this device can be used to treat wastewater from a variety of extremely small sources - both municipal and industrial - which can be biologically eliminated. Due to its applicability, the unit is particularly suitable for decentralized wastewater treatment solutions in small communities, schools, restaurants, hotels, boarding houses, green lawn production parks and the like. The unit can be modeled and gradually integrated into larger units as the wastewater flow increases. Its advantage is its low construction costs, while its technical solutions allow for the provision of ready-to-pack sewage treatment plants that require minimal installation and construction at the destination. And the quality of the treated water meets the increased requirements in terms of the quality of the effluent. These treatment plants can also be used when discharged wastewater is discharged to surface water bodies located in sensitive areas where there is a risk of surface water eutrophication, or when discharged to groundwater or for the treatment of treated wastewater.

Claims (6)

DEFINITION OF INVENTION 1. A modified activation process unit for continuous treatment of waste water, comprising in one container an activation space with non-ventilated anaerobic and anoxic zones and a ventilated oxygen zone, sediment deposition space and a retention space for in-process recycling and recycling of sludge activation space and sediment deposition space, characterized in that the container (1) with bottom (2), outer hood (3) and roof (4) is divided into a non-ventilated activation space (8), a ventilated activation space (9), a sedimentation space (10) and a retention space (25), the non-ventilated activation space (8) is separated from the ventilated activation space (9) by a dividing wall (5) extending from the bottom (2) of the container (1) to the roof (4) (11) at the bottom (2) level of the container (1) or at the level of the outlet (12) of the container (1), the sedimentation space (10) is separated by a ventilated asset inside the driving space (9), the retention space (25) separated from the bottom (2) of the container (1) to the roof (4) and having a perforated opening (7) at the level of the bottom (2) of the container (1) in the container (1) between the level of the outlet (12) of the container (1) and the level of the inlet (26) of the container (1) over the entire area of the container (1) above the non-ventilated activation space (8), ventilated activation space (9) and sedimentation. spaces (10), the non-ventilated activation space (7) divided by at least five dividing walls (13) disposed in a continuous flow direction extending from the bottom (2) of the container (1) to the roof (4) having permeable openings (14) arranged at the bottom (2) level of the container (1) and at the level of the container (1) outlet pipe (12), furthermore, the sediment settling space (10) is provided with a flow regulator (15) on the outlet pipe (12) of the container (1). 2. A device for treating wastewater according to claim 1, characterized in that the container (1) has an outer enclosure (3) with a circumferential or circular polygon having at least four corners, a dividing wall (5) between the non-ventilated activation space (2). 8) and ventilated activation spaces (9) concentrically arranged on a circular or polygonal perimeter having at least four corners; the non-ventilated activation space (7) is divided by at least six annular inner dividing walls (13) in the direction of continuous flow. 3. A device for treating wastewater according to claim 1, characterized in that the container (1) has an outer enclosure (3) having a rectangular perimeter and at least two rows of internal partition walls (13) in the non-ventilated activation space (8). ) separated by a water wall (31) extending from the bottom of the container (2) to the roof (4) of the container and having permeable openings (13) alternately arranged at the bottom (2) of the container (1) and at the level of the outlet pipe (12) in the direction of a continuous flow, with a water wall (31) extending from the bottom of the container (2) to the roof of the container (4). A device for treating wastewater according to claims 1 to 3, characterized in that the bottom (2), the outer enclosure (3) and the partition wall (5) located between the non-ventilated activation space (8) and the ventilated activation space (9) ) and the material of the water wall (31) is a concrete and / or thermoplastic suitable for water construction, such as polyethylene, polypropylene or polycarbonate, while the material of the inner partition walls (13) and the enclosure (6) is a thermoplastic material such as polyethylene, polypropylene or polycarbonate. 5. A device for treating wastewater according to claims 1 to 4, characterized in that the throttle opening (20) of the inlet wastewater regulator (15) in the inlet sleeve (17) is protected by a net (19) which prevents coarse dirt particles. , the network (19) is subsequently rinsed with purified water accumulated in the inlet wastewater regulator (15) between the inlet wastewater regulator (15) cover (16) and the outlet pipe (21) by periodically pushing a pressurized fluid into the inlet wastewater regulator (15). 6. A device for treating waste water according to claim 5, characterized in that the pressurized fluid is pressurized air or pressurized water.