DE2926441A1 - Oxygenation of liquids for biological treatments - using fresh oxygen feed with vent gas purge controlled by pressure and oxygen content in space above liquid - Google Patents

Abstract

Oxygen enrichment of liq. in a closed vessel is carried out by injecting pure O2 into the gas space. The gas above the liq. is drawn into the liq. by means of an agitator. Purge gas is vented. The quantity of gas as fresh O2 injected into the system is controlled by the pressure and O2 content of the gas above the liq. The purge gas exhaust stream is also controlled by a combination of these parameters. The gas input can also be linked with the O2 content of the liq. For use on activated sludge treatment of effluent streams. Improves the O2 utilisation and thus reduces overall O2 usage.

Description

Process and device for oxygen

enrichment of a liquid The invention relates to a method for oxygen enrichment in a container closed to the atmosphere located liquid, in which the container gas in the form of pure oxygen or an oxygen-containing gas mixture supplied in the container above the liquid level maintain a gas phase and from the gas phase oxygen-containing gas into the Liquid entered and exhaust gas is discharged, as well as a device for implementation of the traversing # ns.

Such processes for oxygen enrichment are in particular at used in the biological treatment of wastewater using activated sludge but also for other areas of application, such as the ozonization of Suitable for drinking water. A device operating according to such a method for biological purification of waste water is known from DE-OS 24 32 543. At this Device is the oxygen supply in a closed to the atmosphere Aeration basin depending on the pressure in the aeration basin and the Flue gas removal from the aeration tank depending on the gas phase the oxygen concentration present in the activated sludge tank is carried out automatically.

If the pressure drops slightly in the gas phase due to the oxygen release Microorganisms below a specified limit value, more oxygen is fed in.

At the same time, however, arises from the increased activity of the microorganisms more carbon dioxide, as a result of which the oxygen concentration in the gas phase drops. An analysis regulator then opens an exhaust valve further, whereupon the pressure in the activated sludge tank drops again somewhat and accordingly more oxygen is fed. After a resulting increase in the oxygen concentration the gas phase, the exhaust valve is closed again somewhat and after a pressure increase the oxygen supply is reduced in the aeration tank. Pressure and concentration fluctuate in each case by a setpoint. With this device there is thus the possibility of the amount of exhaust gas removed from the oxygen consumption, which depends on the amount supplied and characteristics of the wastewater introduced into the aeration tank changes automatically to adjust. The disadvantage with this, however, is that the measurement of the oxygen concentration in the gas phase, generally using a for comparison purposes required calibration gas is to be carried out, is not only expensive, but in particular can also lead to operational malfunctions due to measurement inaccuracies, whereby on the one hand the oxygen consumption increases unnecessarily and on the other hand compliance the most favorable aerobic conditions in the aeration tank are not ensured can be. In addition, the measurement of the oxygen concentration in the gas phase leads at least insofar as relatively long dead times in the control system and thus unnecessary Oxygen consumption, as the oxygen content in the gas phase only gradually increases on an oxygen consumption of the microorganisms in the wastewater of the activated sludge tank adjusts.

The invention is based on the object of a method of the above mentioned type for the oxygenation of liquids and a device to implement the method in such a way that the setting is easy the amount of exhaust gas improved depending on the oxygen consumption and overall the oxygen consumption can be reduced.

This object is achieved in that the discharged Amount of exhaust gas and / or the amount of gas introduced into the liquid from the gas space each depending on the amount of gas supplied to the container or in Depending on the oxygen content present in the liquid is set.

With this procedure there are dead times in the setting system for the amount of exhaust gas to be discharged largely excluded, since the setting in all cases the amount of exhaust gas to be discharged immediately while recording the oxygen consumption of the microorganisms present in the liquid are made.

Appropriately, the amount of the supplied to the container Gas depending on the pressure in the container or depending on the gas phase the container's existing oxygen content is set.

With one made depending on the amount of gas supplied Adjusting the amount of exhaust gas ensures a largely constant oxygen content in the Gas phase reached. When the liquid is exposed to high loads, i.e. in the case of strong Wastewater pollution is also the consumption of oxygen by the microorganisms relatively high in the liquid, which reduces the pressure due to the consumption of oxygen drops rapidly in the container. The oxygen supply takes place in the container for example, depending on the pressure present in the container, can then be Falling below a predetermined minimum pressure gas in the form of oxygen or an oxygen-containing gas mixture are introduced into the container. Since the Adjustment of the amount of exhaust gas can be made depending on the gas supplied should, at the same time as the increased gas supply from the container, more exhaust gas discharged, and until the higher in relation to the amount of exhaust gas Gas supply caused pressure increase to exceed a predetermined maximum pressure leads in the container and the gas supply and the exhaust gas discharge is reduced again. With low exposure to the liquid and correspondingly low oxygen consumption of the microorganisms in the liquid, the pressure drops only gradually below the predetermined minimum pressure in the container, with the gas supply and the exhaust gas discharge is also reduced.

With the depending on the oxygen content in the liquid made adjustment of the amount of exhaust gas is achieved, however, that the oxygen concentration in the gas phase directly to the load conditions in the container Liquid is adapted and thus the amount of oxygen actually supplied corresponds to the amount of oxygen required. As with a low load of the liquid the oxygen consumption of the microorganisms is low and thus the oxygen content is correspondingly high in the liquid, the exhaust gas discharge from the gas space remains small amount. If, on the other hand, the oxygen consumption increases when the liquid is exposed to high levels, the oxygen content in the liquid and the proportion of exhaust gas in the Gas phase increases. Accordingly, there is more exhaust gas from the gas space above the liquid deducted. Due to the increased oxygen consumption of the microorganisms and the larger Exhaust gas volume then the pressure in the container falls below the specified chose Minimum value at which an increased oxygen supply begins and continues for as long until the pressure in the container and the oxygen concentration are brought to the specified value is increased again in the gas space.

This allows more oxygen to enter the liquid, whereupon the exhaust valve opens when the oxygen concentration in the liquid is sufficient is closed again. The consequence is that at low loads the liquid in the gas phase of the container has a low oxygen concentration and vice versa, if the liquid is exposed to high loads, there is also a high oxygen concentration adjusts in the gas phase, so that an adjustment of the oxygen content in the gas phase to the load conditions is reached and thus the oxygen consumption is low is held.

With the two procedures described above, it is possible to in addition to the amount of exhaust gas discharged, the amount entered into the liquid from the gas space Amount of gas depending on the amount of gas supplied to the container or in Depending on the oxygen content in the liquid. In addition to a reduction in oxygen consumption, this also results in a reduction in energy consumption to achieve the entry systems, since then the compressors or surface aerators of the entry systems not continuously, but depending on the actual one Running oxygen consumption.

An advantageous procedure consists in that from the gas space Amount of gas introduced into the liquid as a function of the amount of gas in the liquid existing oxygen content and the amount of exhaust gas discharged depending on the to adjust the gas supplied to the container. In this way it is reduced Energy consumption or reduced Oxygen consumption in the gas phase a largely constant oxygen content is achieved.

In addition, it is used for process management with surface aerators possible, an additional drain weir in the container for the liquid to adjust the height depending on the oxygen content of the liquid, so that an oxygen input control can take place.

A device for performing the method has a counter the atmosphere closed container for the liquid to be treated, one am Gas supply line connected to the container with a feed valve, one connected to the container Exhaust pipe with exhaust valve as well as a gas inlet system arranged in the container for the entry of oxygen into the liquid. According to the invention, these are Feed valve, the exhaust valve and optionally the gas inlet system individually or together as a function of at least one measuring device in connection with a controller switchable and the measuring device is used as a measuring device for influencing the amount of gas supplied or as an oxygen concentration measuring device for determination of the dissolved oxygen content in the liquid. With this structure of the device becomes instantaneous, depending on the oxygen consumption Switching of the feed valve, the exhaust valve and, if necessary, the gas inlet system achieved.

The measuring device is advantageously used to influence the supplied Amount of gas as a gas pressure measuring device or as an oxygen concentration measuring device designed to determine the oxygen content present in the gas phase.

In each case, the measured values of the measuring devices are transferred to a Controller passed on, the measured value supplied by the measuring device with adjustable compares upper and lower limit values and different actuators Emits signals, depending on whether the measured value is the upper limit value or the lower Falls below the limit value.

Further details of the invention are based on two in the figures schematically illustrated embodiments explained in more detail.

It shows; Fig. 1 shows an oxidation tank in which the automatic setting the amount of exhaust gas and, if applicable, that entered into the liquid from the gas space Amount of gas carried out depending on the amount of oxygen supplied and Fig. 2 shows an oxidation tank in which the automatic adjustment of the Amount of exhaust gas and, if applicable, that entered into the liquid from the gas space Amount of gas carried out depending on the oxygen content present in the liquid will.

In the figures, 1 is an oxidation basin that is closed to the atmosphere denotes that an inlet 2 for the liquid to be treated and an outlet 3 has in connection with an overflow weir 4 for the treated liquid.

In addition, there is a gas supply line 5 with a feed valve on the oxidation tank 1 6 and an exhaust line 8 with an exhaust valve coupled to an actuating device lo 9 connected. The feed valve 6 is connected to a pressure measuring and control device 7 in connection, which the feed valve 6 automatically in the Way controls that the gas pressure in the Oxidationsbecker 1 irrimer over a predetermined, mostly above atmospheric pressure is maintained.

In each of the oxidation basins 1 there is a device 11 for mixing the liquid and the gas arranged, for example one of an electric motor 12 driven surface aeration stirrer 13 (Fig. 1) or one in the liquid submerged, also driven by an electric motor 12 stirrer 14 with underneath arranged gas distributor 15, which has a compressor or a fan 16 and Via corresponding lines with the gas space of the oxidation basin 1 in connection is (Fig. 2), may have.

In addition to the mixing devices shown and described, of course also other common mixing devices, such as mixers with gas supply through a hollow shaft of the mixer. In the same There is also the possibility, instead of the gas supply, depending on the gas pressure the gas supply in the oxidation tank 1 as a function of a gas analysis of the gas atmosphere of the oxidation basin 1.

For the automatic adjustment of the discharged from the oxidation tank 1 The amount of exhaust gas as a function of the oxygen consumption is shown in FIG Ausfüh.ungsbeispiel the adjusting device lo of the exhaust valve 9 to the pressure measuring and control device 7, which controls the feed valve 6 for the gas supply, in the Connected way that when the feed valve 6 opens, the exhaust valve 9 also opened and when the feed valve 6 closes, the exhaust valve 9 is closed. In this case, the pressure measuring and control device 7 is for example a controller (not shown for the sake of clarity) connected, the the compares the measured pressure value with an adjustable upper and lower limit value and accordingly influences the control device.

This results in the following workflow: Via the feed valve 6 gas is introduced into the oxidation tank 1 until it is in its gas atmosphere A pressure (setpoint) set in the controller has been reached above the liquid.

Subsequently, via the pressure control and measuring device 7, the feed valve 6 and at the same time the exhaust valve 9 is closed again somewhat. Meanwhile, will with the aid of the mixing device 11, further gas is introduced into the liquid.

When consumed by the microorganisms present in the liquid The amount of oxygen is greater than that which gets into the gas space above the liquid Fresh gas, the pressure in the gas phase of the oxidation basin drops again.

Is a certain, set in the controller via the setpoint If the minimum pressure is reached, the feed valve is controlled via the pressure control and measuring device 7 6 and the exhaust valve 9 further open, so that more exhaust gas is blown out at the same time and significantly more fresh gas is introduced. Through the exhaust valve, which is in the Relation to the feed valve opens, only a fraction of the 'fresh gas quantity blown off as the amount of exhaust gas, so that the pressure control process by the fresh gas exhaust gas superimposition is not affected. These control processes cause both the gas space pressure and the gas concentration can be kept largely constant.

In the embodiment shown in Figure 2, the adjusting device lo of the exhaust valve 9 is connected to a control device 18, which is equipped with an in the liquid arranged measuring probe 17 for measuring the dissolved in the liquid Oxygen content is in connection. The control device 18 compares that of the measured value delivered by the measuring probe with the set target value and accordingly gives different signals to the actuating device lo, each depending on whether the oxygen content in the water has exceeded or fallen below the setpoint Has.

The mode of operation of this oxidation basin is thus as follows: About the feed valve 6 gas is introduced into the oxidation tank until in whose gas atmosphere above the liquid has reached a predetermined pressure. Afterward the feed valve 6 is throttled so much via the pressure control and measuring device 7, that the pressure in the gas space remains constant except for the control deviations. Meanwhile 11 gas is introduced into the liquid with the aid of the mixing device. Through this the oxygen concentration in the liquid has a certain value, what of the measuring probe 17 is registered. If the oxygen content registered by the measuring probe 17 lies of the liquid above the setpoint value set in the control device 18 remains the exhaust valve 9 is largely closed. If the oxygen concentration in the Liquid as a result of increased oxygen consumption of the microorganisms below the specified Setpoint value, a corresponding one is obtained via the measuring probe 17 and the control device 18 The signal to open the exhaust valve 9 is passed on to the actuating device lo. By the increased consumption and the larger amount of exhaust gas lower the pressure in the gas phase the liquid, whereby the feed valve via the pressure control and measuring device 7 6 further opens in the gas supply line 5 and the oxygen concentration in the gas space is increased. More oxygen can now be introduced into the liquid via the mixing device 11 are entered so that with a correspondingly increased oxygen content in the liquid Via the measuring probe 17 and the control device 18, the setting device lo for the slightest Closing the exhaust valve 9 is influenced. Then the pressure is in the gas phase above of the liquid has risen above the setpoint again, the pressure measurement and Control device 7, the feed valve 6 is somewhat closed and the process can of start over.

As in both Figure 1 and Figure 2 by dash-dotted lines between the pressure regulating measuring device 7 and the mixing device 11 or between the regulating device 18 and the motor 12 of the stirrer 14 and the fan 16 of the mixing device 11 are indicated there is also the possibility of either depending on the gas inlet systems on the amount of gas supplied to the container or depending on the Set liquid oxygen content present, so in addition to the oxygen consumption also reduce energy consumption.

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Claims (5)

Claims i 1.7 A method for oxygenation of a in a liquid that is closed to the atmosphere the gas in the container in the form of pure oxygen or an oxygen-containing gas mixture supplied, a gas phase is maintained in the container above the liquid level and oxygen-containing gas is introduced into the liquid from the gas phase and Exhaust gas is discharged, characterized in that the amount of exhaust gas discharged and / or the amount of gas introduced into the liquid from the gas space in each case as a function on the amount of gas supplied to the container or depending on the Liquid oxygen content is set. 2. The method according to claim 1, characterized in that the amount of the gas supplied to the container depending on the pressure in the container or in Set depending on the oxygen content present in the gas phase of the container will. 3. The method according to claim 1 or 2, characterized in that the Amount of gas introduced into the liquid from the gas space depending on the in the oxygen content of the liquid and the amount of exhaust gas discharged in Dependence of the gas supplied to the container is set. 4. Device for performing the method according to one of the claims 1 to 3 with a container closed to the atmosphere for the to be treated Liquid, a gas supply line connected to the container with a feed valve, an exhaust pipe connected to the container with an exhaust valve and one in the container arranged gas entry system for the entry of oxygen into the liquid, thereby characterized in that the feed valve (6), the exhaust valve (9) and optionally the Gas inlet system (11) individually or jointly as a function of at least one Measuring device can be switched in connection with a controller and the measuring device as a measuring device (7) for influencing the amount of gas supplied or as an oxygen concentration measuring device (17) designed to determine the oxygen content dissolved in the liquid is. 5. Apparatus according to claim 4, characterized in that the measuring device (7) to influence the amount of gas supplied as a gas pressure measuring device or as an oxygen concentration measuring device for determining what is present in the gas phase Oxygen content is formed.