SK6337Y1 - Domestic waste water treatment plant - Google Patents

Abstract

Domestic waste water treatment plant consists of an inflow chamber (2) pipelined with an activation chamber (4). A circulation pump (18) for pumping waste waters into the inflow chamber (2) and a pump (31) of excess mud flowing into a sludge box (8) are set in the activation chamber (4). The supply of waste waters from the inflow chamber (2) into the activation chamber (4) is directed into the lower part of the activation chamber (4). The substance of the solution rests in a transport device (12) for withdrawing of purified water from the activation chamber (4) that is connected with a separate tank (10) of a pump (11) of cleaned water, where the pump (11) is connected through its delivery with a reservoir (13) of cleaned water. In the reservoir (13) of cleaned water, there is set a feeding pump (14) the delivery (20) of which is connected with the separate tank (10) of the pump (11) of cleaned water.

Description

The technical solution relates to small domestic wastewater treatment plants, where wastewater is activated by activated sludge in the floating mode in the mode of discontinuous wastewater flow.

BACKGROUND OF THE INVENTION

Various types of treatment plants are used to treat wastewater from small sources of pollution, such as single-family houses, groups of houses, pensions, restaurants and the like. The most widespread are systems where wastewater is treated with activated sludge, a mixture of microorganisms that need organic pollution from wastewater for their lives and oxygen supplied to the water by aeration equipment. An activation tank is used for cleaning, where the waste water is usually supplied after removal of coarse impurities. In it, the waste water is held for a technologically necessary time and mixed with the activated sludge while aerating. The weight of the activated sludge is greater than the weight of the water and therefore, after the mixing of the contents of the activation tank is complete, the purified water is separated from the sludge and the sludge settles at the bottom of the tank.

In practice, two basic types of treatment plants are used, according to the method of separating the sludge from the purified water. With continuously flowing activation tank and with activation tank with discontinuous flow. In the method of continuous flow of the activation tank, a separate non-aerated settling tank is placed downstream of the activation tank, into which a mixture of purified water and sludge is fed from the activation tank without interruption. The sludge settles at the bottom of the settling tank and the purified water flows without sludge to the effluent from the treatment plant.

The plants with a discontinuous flow of the activation tank do not contain a settling tank. The biological cleaning process takes place during filling of the activation tank from the minimum level to the maximum level, possibly even after the activation tank is filled. Then there is a sedimentation phase where the tank is neither aerated nor stirred, and subsequently the purged water is pumped into the drain. There are known systems with a buffer tank at the inflow where wastewater accumulates during sedimentation of the sludge at the bottom of the activation tank and during pumping of purified water when it is not advisable to supply wastewater to the activation tank. Further, there are known technical solutions without a buffer tank, in which the wastewater inflow is led to the bottom of the activation tank even during sedimentation, possibly even during pumping of purified water, whereby pumping of purified water is solved so as not to mix raw water with purified water. There are also known technical solutions where the waste water from the buffer tank is pumped to the bottom into the activation tank after the sedimentation phase and thus pushes the surface layer of purified water from the bottom into the drain channel.

There are various technical solutions for pumping the purified water layer into the drain, the smaller the treatment plant, the harder it is to construct a simple, cheap and reliable recovery device. A rapid pumping of the purified water layer without swirling of the settled sludge is required. Usually, the sludge layer after settling reaches a depth of 30% to 60% of the activation tank fill. It is advantageous to drain the purified water from the subsurface layer so that the floating impurities remain at the surface. For example, submersible electric pumps placed on the float are used where the float with the pump sinks and rises with the water level in the activation tank or flexible hoses terminated by the float. At other times, the pumps or pump inlets are fixedly fixed at a constant height above the layer of settled sludge. Generally, exhaust systems, where the inlet of purified water moves with the surface, have the advantage of significantly reducing the sedimentation time while at the same time providing greater safety before the settled sludge is sucked into the outlet. Their disadvantage is usually low reliability of operation, because waste water contains waste that penetrates also into the activation tank but does not biodegrade, accumulates and clog parts of technology used in the activation tank during aeration. Fixed inlet installations are much more reliable, but require considerably longer sedimentation times, and if the activation tank is not regularly drained, the sludge level after sedimentation reaches the inlet of the pumps and then the sludge is pumped off with purified water.

Another major disadvantage of the known solutions for small wastewater treatment plants is the difficulty in regulating the output according to the actual amount of wastewater, since the actual load of the treatment plant corresponds only to the design capacity of the treatment plant rarely, either in terms of wastewater or organic pollution. The regulation used in large wastewater treatment plants is not feasible for small wastewater treatment plants mainly for economic reasons. Only manually set timers are used to regulate the blower function time, for example based on the number of persons using the object. In practice, this leads to a waste of electrical energy and, in the case of insufficient organic load of the treatment plant and an excess of supplied oxygen, the biological function of the wastewater treatment plant can also collapse, especially during long periods of low or no load.

SK 6337 Υ1

The essence of the technical solution

These drawbacks are overcome by a domestic sewage treatment plant comprising an inflow chamber connected to an activation tank in which a circulation pump for pumping waste water into the inflow chamber, a pump of excess sludge entering the sludge tank and a device for purging the purified water into the outlet are located. According to the invention, the waste water supply from the inflow chamber to the activation tank is led to the bottom, preferably to the bottom of the activation tank. A transport device for pumping the purified water from the activation tank to the drain is connected to a separate tank of the purified water pump, which is connected by discharge to the purified water tank. The purified water tank houses a filling pump, the discharge of which is connected to the tank of the purified water pump.

The waste water supply to the activation tank is formed by an opening in the common wall of the inflow chamber and the activation tank. The wall opening is formed below the wastewater level in the inflow chamber or at the level of the wastewater level in the inflow chamber, and then forms an overflow into the activation tank. The opening in the wall opens into a tube located in the activation tank. The pipe outlet is then at the bottom of the activation tank. An opening in the common wall can also be formed at the bottom of both tanks.

Constructed in this way, domestic wastewater treatment plants are structurally simple and safe in economical operation with minimal operator requirements, where the consumption of electricity corresponds to the real load of the wastewater treatment plant. Their further advantage is the speed of pumping the purified water while maintaining the desired quality of the purified water.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings show the individual phases of operation and variants of the design of the domestic treatment plant according to the utility model. In FIG. 1 shows the filling phase of the treatment plant reactor, FIG. 2 shows a sedimentation phase with a separate sludge cup and FIG. 3 phase of pumping the purified water from the domestic treatment plant. In FIG. 1, 4 and 5, various variants of the connection of the inflow chamber and the activation tank are shown.

EXAMPLES

The waste water flows through the inlet 1 into the inlet chamber 2, where coarse dirt is collected, and further to the bottom 6 of the activation tank 4. At the same time aeration of the activation tank 4 is carried out by the first aeration device 24 connected to the blower 25 through the manifold 27 through the first air 32. The water level in the inlet chamber 2 and the activation tank 4 gradually rises from the minimum level 21 to the maximum level 23. Initially, or all the time during the filling of the activation tank 4, the transport device 12 is also aerated through the first air inlet 32. aeration of activation tank 4.

The water level in both tanks 2, 4 is sensed, for example, by a pressure sensor 26, which is usually located in the activation tank 4 in the pipe 5, but can also be placed in the inflow chamber 2 if the opening 3 lies below the minimum level 21. A circulating pump 18 with a discharge 17 led into the inlet chamber 2 is activated. By mixing the sewage with activated sludge in the activation tank 4 in the presence of dissolved O ₂ , the wastewater is treated biologically. During aeration of the activation tank 4, a part of the activation mixture is pumped from the activation tank 4 to the inflow chamber 2, where it is mixed with raw water and partially denitrified and then returned to the activation tank 4. This mixture is returned to the activation tank 4. an opening 3 in the common wall 9 of the inflow chamber 2 and the activation tank 4 formed below the surface, as shown in FIG. 1, 2 and 3, or at the level of the waste water level of FIG. 5. In FIG. 4, an opening 3 is formed at the bottom 6 of the activation tank 4. FIG. 1, 2, 3 and 5 the orifice 3 opens into a pipe 5 located in the activation tank 4 and opens at the bottom of the activation tank 4 to prevent mixing of raw and purified water at the time of sedimentation and at the time of purging of purified water from the activation tank 4. In order to ensure correct operation of the treatment plant, it is necessary that the outlet of the wastewater inlet into the activation tank 4 is always below the level 29 of the sludge after it settles at the bottom 6 of the activation tank 4. In FIG. 5 shows a variant where the waste water inlet 1 is led to the inlet chamber 2, which at the same time functions as a primary sedimentation tank and usually also a sludge tank. In this case, the interconnection of the inlet chamber 2 and the activation tank 4 is at or near the maximum level 23.

Upon reaching the maximum water level 23 in the activation tank 4, the aeration is terminated immediately or after a set pause, and the aeration is diverted to the inflow chamber 2, in which intensive mixing begins with the second aeration device 30 connected to the manifold 27 by the second air supply 33. This also breaks down coarse organic impurities. Thus, the power of the compressor 25 is efficiently utilized even when the activation tank 4 is not aerated.

At that time, the sludge sedimentation phase at the bottom 6 takes place. The maximum water level 23 is stabilized or continues to rise due to the further inflow of waste water into the inlet chamber 2. The activated sludge settles gradually at the bottom 6 to the sludge level 29.

For part or all of the sedimentation time, the tank 10 of the purified water pump 11 is filled by the filling pump 14 by its discharge 20 from the clean water tank 13. This achieves an increase in the purified water level in the tank 10 above the maximum level 23 in the activation tank 4, which is necessary for the subsequent phase of pumping purified water from the activation tank 4 by the purified water pump 11, and the treatment plant is ready to withdraw the purified water. If the treatment plant is equipped with a separate sludge tank 8, the excess sludge pump 31 is also in operation at this stage. The excess sludge pump 31 has an inlet located above the bottom 6 of the activation tank 14 at 15-50% of the depth 22 of the activation tank 4 at maximum level 23 water.

After sedimentation is finished, the purging phase of purified water occurs. During continuous aeration of the inflow chamber 2, the purified water pump 11 is actuated, which purges the purified water from the subsurface layer from the activation tank 4 by the transport device 12 into the tank 10 and subsequently from it through the discharge 19 into the purified water tank 13. After filling the reservoir to the level of the second overflow 15, the purified water flows into the outlet 16 from the treatment plant and / or into a tertiary treatment tank (not shown), which is usually formed by sand or membrane filtration. Since the hydraulic power of the feed pump 14 is substantially less than that of the purified water pump 11, both pumps can operate simultaneously. If necessary, the excess sludge pump 31 continues to operate. However, it is preferable from the point of view of the hydraulic load of the treatment plant if the feed pump 14 and the excess sludge pump 31 are already switched off during the purged water pumping phase. Since the capacity of the purified water pump 11 allows the pumped water to be pumped faster than a possible new wastewater inflow to the treatment plant, the activation tank 4 causes the water to drop from a maximum level of 23 to a minimum level of 21. and the control unit 28 redirects the aeration from the inlet chamber 2 back to the activation tank 4 and the filling phase of the activation tank 4 begins again.

In domestic sewage treatment plants, small amounts of water are moved, and therefore air pumps connected to the central air distribution from the blower 25, as shown in FIG. 5. The air pumps are operated by electrical valves (not shown) from the control unit 28. In FIG. 1 to 4, electric pumps are used.

PROTECTION REQUIREMENTS

Claims (10)

1. Domestic wastewater treatment plant, consisting of an inlet chamber connected to an activation tank, in which a circulation pump for pumping waste water into the inlet chamber, a pump of excess sludge entering the sludge pit, a water level measuring device and a device for pumping purified water into the outlet are characterized in that the waste water supply from the inlet chamber (2) to the activation tank (4) is led to the lower part of the activation tank (4), the transport device (12) for pumping purified water from the activation tank (4) to the outlet (16) is connected to a separate tank (10) of the purified water pump (11), which is connected by its discharge (19) to the purified water tank (13) in which the filling pump (14), whose discharge (20) is connected to the tank (10) of the purified water pump (11). A domestic wastewater treatment plant according to claim 1, characterized in that the wastewater supply to the activation tank (4) is formed by an opening (3) in the common wall (9) of the inflow chamber (2) and the activation tank (4) formed below. the waste water level in the inlet chamber (2). A domestic wastewater treatment plant according to claim 1 and 2, characterized in that the opening (3) opens into a pipe (5) located in the activation tank (4), the outlet of the pipe (5) being situated at the bottom of the activation tank (4). ). A domestic wastewater treatment plant according to claim 1 and 2, characterized in that the opening (3) is formed in the lower part of the activation tank (4). 5 are electric pumps. A domestic wastewater treatment plant according to claim 1, characterized in that the opening (3) in the common wall (9) of the inflow chamber (2) and the activation tank (4) is formed at the maximum level (23) and above. A domestic wastewater treatment plant according to claims 1 to 5, characterized in that the excess sludge pump (31) has an inlet located above the bottom (6) of the activation tank (4) at a height of 15-50% of the depth (22) of the activation tank (4). ) at maximum level (23). A domestic sewage treatment plant according to claims 1 to 6, characterized in that a second aeration device (30) is located in the inlet chamber (2), which is connected to the blower (25) via a distributor (27) by a second air inlet (33). ), wherein a first aeration device (24) is provided in the activation tank (4), which is connected to the blower (25) via a distributor (27) by a first air inlet (32), while the air inlet (32) is routed to the transport device (12). SK 6337 Υ1 A domestic wastewater treatment plant according to claim 7, characterized in that the blower (25) is connected to the control unit (28) as well as the water level meter (26). A domestic wastewater treatment plant according to claims 1 to 8, characterized in that the purified water pump (11), the filling pump (14), the circulation pump (18) and the excess sludge pump (31) The domestic wastewater treatment plant according to claims 1 to 8, characterized in that the purified water pump (11), the filling pump (14), the circulation pump (18) and the excess sludge pump (31) are air pumps.