PL164516B1 - Biological sewage treatment apparatus - Google Patents

Abstract

Device for biological treatment sewage by circulating and contacting them with gas, consisting of a main chamber cleaning, forming a deep shaft inside which has downward flow pipes, biological contribution for sedentary microorganisms and a system for aeration and introduction of sewage circuit, characterized in that it is equipped with at least one oxygen stabilization chamber (14), which is situated below the outlet (5) of the pipe (4) o sloping sewage flow and near the bottom (15) main purification chamber (1), the diameter being the stabilization chamber (14) is larger from half the diameter of the main purification chamber (1) and an oxygen stabilization chamber (14) it has a sludge pipe (9) whose outlet (17) is located near its lower part and in the upper part, constituting the dome (13), there is an outflow pipe (18) with valve (19) for connection to main cleaning chamber - (1).

Description

The subject of the invention is a device for biological wastewater treatment, which is used, in particular, to neutralize sludge formed in biological wastewater treatment processes in a hydrophobic activated sludge chamber containing biological inserts, constituting a substrate for sedentary microorganisms that produce sludge with properties different than free-flowing zoogleal flocs.

A device for biological treatment of wastewater by introducing it into the circulation and contacting it with gas is known from the Polish patent description No. 151,614. This device has a main cleaning chamber, which is preferably a shaft up to 80 m long sunk into the ground, or a tower situated on the ground. Above the main purification chamber there is a supply tank in which there are inlets of downward flow pipes symmetrically arranged in relation to the vertical axis of the main purification chamber. Downflow pipe outlets are located at the bottom of the main purification chamber. Inside the main cleaning chamber, biological cartridges are placed, which constitute a substrate for sedentary microorganisms. On the perimeter of the main treatment chamber, secondary settling tanks are located vertically concentrically, which are connected to the chamber through inlet ports.

A device for biological treatment of wastewater by circulating it and contacting it with gas, consisting of a main treatment chamber, which is a deep shaft, inside which there are pipes with falling flow, biological inserts for sedentary microorganisms, and a system for aerating and introducing wastewater into circulation, according to the invention characterized by the fact that it is equipped with at least one oxygen stabilization chamber,

164 516, which is located below the outlet of the descending sewage pipe and close to the bottom of the main purification chamber, the diameter of the oxygen stabilization chamber being greater than half the diameter of the main purification chamber, and the stabilization chamber having a sludge supply pipe, the outlet of which is located nearby. in its lower part, and in its upper part, which is the dome, there is a discharge pipe with a valve for connection to the main cleaning chamber.

It is preferred that the oxygen stabilization chamber is divided by partitions arranged along its height, which form a series of consecutive vertical oxygen stabilization chambers, one above the other.

Another advantageous solution is that the oxygen stabilization chamber is divided by coaxial partitions arranged coaxially to form a series of successive oxygen stabilization chambers coaxial to each other, the coaxial partitions connected to the bottom of the main purification chamber. The housing, which is an oxygen stabilization chamber, is provided with a layer of thermal insulation. The device further comprises an oxygen supply line to the inlet of the sediment introduction tube into the oxygen stabilization chamber.

The device according to the invention has significant advantages compared to the conventional system of biological treatment plant and the separate sludge treatment, in particular due to the reduction of the built-up area, shortening of the routes of liquid and sludge transmission, and also due to the recovery of a part of the internal energy of sewage pollutants in the form of heat transferred from the stabilized sludge to the main a purification chamber in which the activated sludge is aerated.

Moreover, placing the oxygen stabilization chamber in a deep well shaft or in a tower provides good conditions for the development of the microflora specific to hot aerobic stabilization, and dramatically improves the degree of oxygen utilization both due to its increased solubility under high pressure and accelerated consumption at high temperature.

The subject of the invention is shown in the embodiment on the drawing, in which fig. 1 shows the first version of the device according to the invention in a schematic view, fig. 2 - a part of the main purification chamber with an oxygen stabilization chamber according to the second version in a schematic view, fig. 3 - main part a treatment chamber with an oxygen stabilization chamber according to the third version in a schematic view.

The main cleaning chamber 1 is a shaft sunk into the ground, and the main cleaning chamber 1 can also be a tower situated on the ground. Above the main purification chamber 1 there is a supply tank 2 to which the sewage is supplied and in which there are inlets 3 of sewage pipes 4 with a descending flow, symmetrically arranged in relation to the vertical axis of the main treatment chamber 1. The outlets 5 of sewage pipes 4 with a descending flow are arranged in bottom 11 of main purification chamber 1.

Inside the supply tank 2, there are auxiliary sludge tanks 6, to which it is supplied from the secondary settling tanks by means of the pipeline 7. In the auxiliary sludge tanks 6 there are inlets 8 of the sludge pipes 9 with a falling flow. A conduit 10 is fed to the inlets 8 of the sludge pipes 9, through which oxygen is supplied from an oxygen unit, not shown in the drawing.

In the lower part of the main purification chamber 1, in the first version of the device, a capacity is separated by means of a cylindrical wall 12 and a dome 13, constituting the oxygen stabilization chamber 14. The oxygen stabilization chamber 14 is located below the outlets 5 of the sewage pipes 4 and close to the bottom 15 of the main purification chamber. 1. Below the lower end of the stabilization chamber 14 there is a gap through which the liquid can flow from the main cleaning chamber-1 to the oxygen stabilization chamber 14. Both the wall 12 and the dome 13 are provided with a thermal insulation layer 16. The diameter of the stabilization chamber oxygen 14 is greater than half the diameter of the main purification chamber 1.

Sediment pipes 9 are introduced into the oxygen stabilization chamber 14, the outlets of which 17 are located near the lower part of the chamber. In the dome 13 there is a discharge pipe 18 provided with a valve 19 for connection of the oxygen stabilization chamber 14 to the main cleaning chamber. The opening or closing of the valves 19 can be performed by means of a cable 20 that is led outside the device.

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In the second version, the oxygen stabilization chamber 14 is divided halfway up by a partition 21, by means of which two consecutive oxygen stabilization chambers 22 and 23 are arranged vertically and one above the other. It is possible to use more partitions 21 arranged along the height of the oxygen stabilization chamber 14 and to obtain a series of further oxygen stabilization chambers.

As in the first version, sludge pipes 9 are introduced into successive oxygen stabilization chambers 22 and 23, the outlets 17 of which are located near their lower parts. Subsequent oxygen stabilization chambers 22 and 23 are connected to the main purification chamber 1 by means of discharge pipes 18 provided with valves 19 and are connected to each other by a flow tube 24 provided with a flow valve 25, which is controlled similarly to valves 19.

In the third version, the oxygen stabilization chamber 14 is divided by a coaxial partition 26, by means of which two successive oxygen stabilization chambers 27 and 28 are formed coaxially with respect to each other. A coaxial baffle 26 in the upper part is connected to the dome 13, and in the lower part to the bottom 15. It is possible to use a greater number of coaxial baffles 26 coaxial to each other and to obtain a series of further coaxial oxygen stabilization chambers. As in the first version, sludge pipes 9 are introduced into the subsequent oxygen stabilization chambers 27 and 28, the outlets 17 of which are located near their lower parts. The subsequent oxygen stabilization chambers 27 and 28 are connected to the main cleaning chamber 1 by means of discharge pipes 18 provided with valves 19.

In the process of wastewater treatment, the operation of the device according to each version is similar. In any case, the waste water to be treated is fed to the feed tank 2. From the feed tank 2, the waste water is circulated through the inlets 3 of the down-flow waste pipes 4. The falling waste water entrains air from the atmosphere prevailing above the liquid table in the supply tank 2 and becomes mixed with it. Sewage together with air through outlets 5 are introduced to the lower part of the main cleaning chamber 1, from where the sewage flows slowly upwards. In the central zone of the main purification chamber 1, the up-flow wastewater flows through the zone with settled microorganisms, which are biological inputs, not shown in the figure, and the wastewater is treated as a result of the biological processes taking place. The sludge produced in the biological cartridge has different properties than zoogleal, free-flowing flocs. The sludge from the biological media shows a sedimentation tendency, while the free-flowing activated sludge may have properties favoring flotation of flocs. In the upper zone of the main treatment chamber 1, part of the rising flow is directed through the outlet 29 to secondary settling tanks, where the suspension is separated from the liquid, from where the clarified water is discharged outside the device. The remaining active sludge is recirculated to the main treatment chamber 1, and the excess sludge is neutralized in the oxygen stabilization chamber 14.

Excess sludge is fed to auxiliary sludge tanks 6, from where through the inlet 8 of sludge pipes 9 it is introduced into the circulation together with the sucked atmospheric air. At the same time, at the inlet 8, oxygen is pumped from the conduit 10. A mixture of activated sludge, air and oxygen through the outlet 17 is introduced into the oxygen stabilization chamber 14.

This sludge mixture in the oxygen stabilization chamber 14 is subject to aerobic stabilization, whereby, under the conditions of increased pressure and abundance of oxygen, and as a result of starting with the participation of cultivated microflora, an aerobic fermentation system of activated sludge is produced without the participation of methane microflora. The mixing of the contents in the oxygen stabilization chamber 14 is ensured by its own recirculation system created in it, regardless of the recirculation existing in the main treatment chamber 1. Maintaining the temperature of the sediment stabilization process resulting from the vital activity of specialized bacteria and fungi is ensured by the thermal insulation layer 16 of the oxygen stabilization chamber 14.

The collection of the stabilized sludge from the oxygen stabilization chamber 14 may be performed continuously or periodically in time periods shorter than the cycle of full sludge stabilization. The flow of stabilized sludge from the stabilization chamber 14 to the main treatment chamber 1 is regulated by means of valves 19 by opening or closing them.

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In the case of continuous collection of the stabilized sludge, in principle, the sludge is passed through a shortened circulation inside the oxygen stabilization chamber 14, whereby a limited supply of the gas circuit with an increased oxygen content is necessary, and thus the control and regulation of the oxygen content in the sludge and its utilization rate. The stabilized sludge in the stabilization chamber 14 can also be discharged outside the device via the pipeline 30.

The operation of the device according to the second version with vertically arranged oxygen stabilization chambers 22 and 23 is similar to that of the first version. Each of the aerobic stabilization chambers 22 and 23 is fed through the outlet 17 of the sludge pipe 9 with excess adequately peroxygenated sludge at the inlet 8, and the chamber 23 is fed via the flow pipe 24 with the pre-stabilized sludge in the chamber 22. The collection of the stabilized sludge to the main treatment chamber 1 is performed individually from each oxygen stabilization chamber 22 and 23. It is also possible to discharge the stabilized sludge outside the device via the pipeline 30.

The operation of the device according to the third version is similar for each successive oxygen stabilization chamber 27 and 28 as in the first version of the device.

All the versions according to the invention achieve a high quality of selective treatment of excess sludge and a certainty of destroying harmful substances. The oxygen-stabilized sludge discharged periodically outside the plant undergoes anaerobic digestion and can be used for agricultural purposes.

On the other hand, the placement of the oxygen stabilization chamber, according to all device versions, in a deep shaft or in a tower provides good conditions for the development of specific microflora for hot aerobic stabilization and dramatically improves the degree of oxygen utilization both due to its increased solubility under high pressure and accelerated consumption at high temperature .

Fig. 3

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Publishing Department of the UP RP. Circulation of 90 copies. Price: PLN 10,000

Claims (6)

Patent claims 1. A device for biological treatment of wastewater by circulating it and contacting it with gas, consisting of a main treatment chamber, which is a deep shaft, inside which there are pipes with a falling flow, a biological contribution for settled microorganisms, and a system for aerating and introducing wastewater into the circulation , characterized in that it is provided with at least one oxygen stabilization chamber (14) which is situated below the outlet (5) of the pipe (4) with the downward flow of sewage and close to the bottom (15) of the main treatment chamber (1), the diameter of which is the oxygen stabilization chamber (14) is larger than half the diameter of the main cleaning chamber (1), and moreover, the oxygen stabilization chamber (14) has a sludge pipe (9), the outlet (17) of which is located near its lower part, and in its upper part constituting a dome (13), there is a discharge pipe (18) with a valve (19) for connection to the main purification chamber (1). 2. The device according to claim The stabilization chamber according to claim 1, characterized in that the oxygen stabilization chamber (14) is divided by partitions (21) arranged along its height, which form a series of successive oxygen stabilization chambers arranged vertically, one above the other. 3. The device according to claim The stabilization chamber according to claim 1, characterized in that the oxygen stabilization chamber (14) is divided coaxially by partitions (26) arranged coaxially, which form a series of successive oxygen stabilization chambers coaxial to each other. 4. The device according to claim 3. The method of claim 1, 2 or 3, characterized in that the wall (12) and the dome (13) of the oxygen stabilization chamber (14) are provided with a thermal insulation layer (16). 5. The device according to claim 1 The device of claim 3, characterized in that the coaxial partition (26) is attached to the bottom (15) and the dome (13). 6. The device according to claim 1 A conduit (10) to which oxygen is supplied is provided at the inlet (8) of the sludge pipe (9).