KR20030092731A - Method and system for disposing a sewage through controlling an oxygen content of gas being provided and an output of the gas - Google Patents

Abstract

PURPOSE: Provided are a method and a system for controlling amount of oxygen to be supplied to wastewater, considering concentration and amount of organic material in the wastewater. CONSTITUTION: The method comprises the steps of introducing wastewater into an aeration tank with a DO (dissolved oxygen) meter and an ORP (oxidation reduction potential) meter, transmitting data of DO and ORP to a PLC (programmable logic controller), transmitting a signal to a PSA (pressure swing adsorption) to generate and supply a first gas with 90% of oxygen concentration to the aeration tank when the data indicate a figure lower than reference data for a predetermined time, transmitting a signal to the PSA to generate and supply a second gas with 60% of oxygen concentration to the aeration tank when the data indicate a figure greater than the reference data for a predetermined time, and transmitting a signal to the PSA to generate and supply a third gas with 21% of oxygen concentration to the aeration tank when the data indicate a figure greater than the reference data for a predetermined time.

Description

Method and system for wastewater treatment by controlling oxygen concentration and amount of feed gas {Method and system for disposing a sewage through controlling an oxygen content of gas being provided and an output of the gas}

The present invention relates to a method for treating wastewater by controlling the oxygen concentration and the amount of gas to be supplied. More specifically, the present invention relates to wastewater treatment according to DO meter (Dissolved Oxygen Meter) and ORP (Oxidation-Reduction Potential Meter) measurements. The present invention relates to a wastewater treatment method through controlling the oxygen concentration and amount of a supply gas that is controlled by adjusting the amount and oxygen concentration of a gas to be supplied.

In general, wastewater treatment methods containing organic matters include physical and chemical treatment methods and biological treatment methods. The representative treatment methods of the biological treatment methods include active sludge treatment using wastewater sludge. have. In addition, the activated sludge process is divided into standard activated sludge process, pure oxygen sealed type and pure oxygen open type according to the use of the aeration tank.

Among them, the pure oxygen sealed type is a method of decomposing and treating contaminants by aerobic microorganisms by agitating a high concentration of oxygen produced by PSA on top of a closed type aeration tank to dissolve and treat oxygen. Regardless of the concentration and amount of organic matter, it was common to treat wastewater by quantitatively injecting high concentrations of oxygen (more than 99.99%). Therefore, there is a disadvantage in that a high cost is required to produce a high concentration of oxygen to be used for wastewater treatment.

On the other hand, in the method according to the prior art, there was also a method of adjusting and adjusting the amount of oxygen injection based on the experience of the wastewater treatment plant worker, COD, BOD, DO meter and the like. However, this method has the disadvantage that it can always be applied where a certain concentration and amount of wastewater is generated, but it is difficult to apply in other places that do not. In addition, the DO meter method does not accurately know the reactivity of the microorganisms in the actual aeration tank because the DO amount simply represents the dissolved oxygen amount in the water, so even if the DO meter reading is higher than the reference value, the DO meter reading alone requires oxygen and microorganisms. There was a problem that can not determine whether the activity is sufficient.

The present invention has been made in view of the above-described problems, the oxygen concentration and amount of the gas required for wastewater treatment in consideration of the reactivity by the concentration and the amount of organic matter contained in the wastewater is determined, the gas by the determined value It is an object of the present invention to provide a wastewater treatment method by controlling the oxygen concentration and amount of a feed gas for producing and supplying wastewater to treat wastewater.

In addition, another object of the present invention is to provide a wastewater treatment method by controlling the oxygen concentration and amount of the feed gas independent of the environment of the wastewater treatment plant.

1 is a block diagram of an apparatus for implementing the method according to the present invention;

2 is a flow chart showing a method according to the invention,

3 is a flowchart showing a detailed configuration of one step of FIG.

4 is a flowchart illustrating a detailed configuration of another step of FIG. 2;

5 is a flowchart illustrating a detailed configuration of still another step of FIG.

<Explanation of symbols for the main parts of the drawings>

10 ... aeration tank, 12 ... DO meter,

14 ... ORP meter, 30 ... oxygen PSA,

32 compressors, 34 raw material tanks,

36 ... flow control valve, 38 ... adsorption tower,

40 ... product tank, 50 ... PLC.

In order to achieve the above object, the present invention provides a wastewater treatment method comprising: a first step of introducing wastewater into an aeration tank provided with a DO meter and an ORP meter; The measurements of the DO and ORP meters are sent to a PLC connected to the DO and ORP meters, and when the measurements are judged to be below the reference values for a certain period of time, the maximum output gas of 90% oxygen concentration from the PLC 1 gas) a second step in which a production related signal is notified to the oxygen PSA so that the oxygen PSA is controlled, a first gas is produced from the controlled oxygen PSA, supplied to the aeration tank, and reacted with the waste water; The measurements of the DO and ORP meters are sent to the PLC connected to the DO and ORP meters, and when the measurements are judged to be above the reference values for a certain period of time, the maximum output gas of 60% oxygen concentration from the PLC 2-1 gas) a production-related signal is notified to the oxygen PSA to control the oxygen PSA, and a second step of producing a 2-1 gas from the controlled oxygen PSA and supplying it to the aeration tank to react with the wastewater; And the maximum production gas of 21% oxygen concentration from the PLC when the measurements of the DO and ORP meters are transmitted to a PLC connected to the DO and ORP meters, and the measurements are all determined to be above the reference values for a certain period of time (hereinafter, 3-1 gas) production-related signal is notified to the oxygen PSA, the oxygen PSA is controlled, and the 3-1 gas is produced from the controlled oxygen PSA is supplied to the aeration tank and comprises a fourth step of reacting with the waste water It is done.

On the other hand, the present invention is a waste water treatment apparatus, DO meter for measuring the amount of dissolved oxygen in the waste water and ORP meter for measuring the oxidation / reduction potential of the waste water is installed aeration tank aeration waste water; Compressor for compressing the raw air, raw material tank for storing the compressed raw air, flow rate control valve for adjusting the production amount of the oxygen PSA by adjusting the amount of opening and closing of the raw air into the oxygen PSA through the adjustment of the degree of opening and closing, unnecessary of the raw air An oxygen PSA configured to generate a mixed gas containing oxygen and to supply the aeration tank, the product tank including an adsorption tower for adsorbing the component to be discharged to the waste gas and storing the produced mixed gas including oxygen; And a program related to the oxygen PSA control, which is connected to the DO meter and the ORP meter to determine the oxygen concentration and amount of the mixed gas to be produced by receiving respective measurement values, and notify the oxygen PSA of the related signals. It is characterized by consisting of a controlling PLC.

EMBODIMENT OF THE INVENTION Hereinafter, the Example by this invention is described in detail with reference to an accompanying drawing.

1 is a block diagram of an apparatus for implementing the method according to the present invention.

As shown in Fig. 1, the apparatus implementing the method according to the present invention is provided with a DO meter 12 for measuring the amount of dissolved oxygen in the wastewater and an ORP meter 14 for measuring the oxidation / reduction potential of the wastewater. An aeration tank 10 in which waste water is aerated, an oxygen pressure swing adsorption 30 for producing a mixed gas which is connected to the aeration tank 10, and supplies the aeration tank 10 to the aeration tank 10, and the oxygen PSA ( 30) A program related to the control is installed and is connected with the DO meter 12 and the ORP meter 14 to determine the oxygen concentration and amount of the mixed gas to be produced by receiving each measurement value and to send the related signal to the oxygen signal. It consists of the PLC 50 which informs and controls the PSA 30. FIG.

The oxygen PSA 30, as shown, the compressor 32 for compressing the raw air, the raw material tank 34 for storing the compressed raw air, the amount of introduction of the raw material air into the oxygen PSA through the adjustment of the degree of opening and closing That is, the flow rate control valve 36 for adjusting the production amount of oxygen PSA, the adsorption tower 38 for adsorbing the unnecessary components of the raw air to be discharged to the waste gas, and the product tank 40 for storing the mixed gas produced by the oxygen, etc. It is composed.

2 is a flow chart illustrating a method according to the present invention.

First, when the waste water flows into the aeration tank in which the DO meter and the ORP meter are installed (S1), the oxygen PSA is measured when the measured DO meter and the ORP meter of the introduced waste water are 2 mg / L and 0 mV (hereinafter referred to as reference values), respectively. A mixed gas of 90% oxygen concentration is supplied to the aeration tank and reacts with the waste water (S2). Subsequently, a mixed gas of 60% oxygen concentration is supplied from the oxygen PSA to the aeration tank when the DO and ORP meter readings are above the reference values. And reacted with the waste water (S3), and when the DO meter and the ORP meter are still above the reference value, a mixed gas of 21% oxygen concentration from the oxygen PSA is supplied to the aeration tank and reacted with the waste water (S4).

The progress of each step is performed only when the measured values of the DO meter and the ORP meter satisfy the conditions for a predetermined time, for example, for 1 hour.

The reference value is not a fixed value and is set differently according to the incoming wastewater. In addition, it is possible to set and process not only a single value form of the reference value as described above but also a reference range including an upper limit value and a lower limit value.

3 is a flowchart showing a detailed configuration of step S2 of FIG.

The DO meter and ORP meter values of the introduced wastewater are measured and notified to the PLC (S200), and the PLC determines whether the measured values of the DO meter and the ORP meter are below the reference values (S210).

As a result of the determination of the measured value compared to the reference value, if the reference value is greater than or equal to the step (S200), and if it is less than the reference value, a signal related to the production of the gas (hereinafter referred to as the first gas) of the maximum production amount of 90% oxygen concentration is notified to the oxygen PSA. The PSA is controlled and a corresponding mixed gas is produced from the controlled oxygen PSA and supplied to the aeration tank to react with the waste water (S220). For example, if the maximum yield of mixed gas at 90% oxygen concentration is 2Nm ³ / hr, oxygen PSA produces 2Nm ³ / hr mixed gas containing 90% oxygen. That is, the oxygen PSA will be to produce a mixed gas of ^{1.8Nm 3 / hr (2Nm 3 /hr*.9=1.8Nm} 3 / hr) of 2Nm ³ / hr of oxygen contained in the.

Subsequently, values of each of the DO meter and the ORP meter of the wastewater supplied with the first gas are measured and notified to the PLC (S230), and the PLC determines whether the measured values of the DO meter and the ORP meter are equal to or greater than the reference value (S240). As a result of the above determination, when the reference value is greater than or equal to the reference value, step S3 of FIG. 2 is performed, and when the reference value is less than the reference value, step S220 is performed.

4 is a flowchart showing the detailed configuration of step S3 of FIG.

Signal related to production of gas of maximum production (hereinafter referred to as 2-1 gas) of 60% oxygen concentration from PLC is notified to oxygen PSA to control oxygen PSA, and corresponding mixed gas is produced and supplied to aeration tank from controlled oxygen PSA React with the waste water (S300). For example, if the maximum yield of mixed gas with 60% oxygen concentration is 6Nm ³ / hr, the oxygen PSA produces 6Nm ³ / hr mixed gas containing 60% oxygen. That is, the oxygen PSA produces 6 Nm ³ / hr of mixed gas containing 3.6 Nm ³ / hr (6 Nm ³ /hr*.6=3.6 Nm ³ / hr) of oxygen.

Subsequently, the values of the DO meter and the ORP meter of the wastewater supplied with the gas 2-1 are measured and notified to the PLC (S310), and the PLC determines whether the measured values of the DO meter and the ORP meter are higher than the reference value (S320). .

As a result, when the reference value is less than the reference value (S220) of FIG. 3 is performed, when the reference value is higher than the reference value 70% of gas (hereinafter referred to as the 2-2 gas) production-related signal of the 60% oxygen concentration from the PLC signal The PSA is notified to control the oxygen PSA, and a corresponding mixed gas is produced from the controlled oxygen PSA, supplied to the aeration tank, and reacts with the waste water (S330).

For example, if the maximum yield of mixed gas having a 60% oxygen concentration is 6 Nm ³ / hr, the oxygen PSA received a reduced amount of air from the raw material tank by adjusting the flow control valve is 4.196 Nm containing 60% oxygen. Produces ³ / hr (6 Nm ³ /hr*.7=4.196 Nm ³ / hr) of mixed gas. That is, the oxygen PSA will be to produce a mixed gas of 4.196Nm ³ / hr with the oxygen of ^{2.514Nm 3 /hr(4.196Nm 3 /hr*.6=2.514Nm 3 / hr} ).

As described above, reducing the amount of mixed gas produced at the same oxygen concentration by 30% is related to the recovery rate of oxygen PSA according to the oxygen concentration of the mixed gas to be produced. That is, as the production rate of the oxygen PSA increases as the mixed gas having a lower oxygen concentration is produced, when producing the gas through the oxygen PSA while lowering the oxygen concentration as in the present invention, the gas production is increased to cause a safety problem. It is possible to reduce the amount of gas produced under certain conditions while maintaining the same concentration.

Subsequently, the values of DO and ORP meters of the waste water supplied with the second gas are measured and notified to the PLC (S340), and the PLC determines whether the measured values of the DO and ORP meters are greater than or equal to the reference value (S350). .

As a result of determination, if it is higher than the reference value, a signal related to the production of 40% of the gas (hereinafter referred to as 2-3 gas) of the maximum production at 60% oxygen concentration is notified to the oxygen PSA so that the oxygen PSA is controlled, and from the controlled oxygen PSA, The corresponding mixed gas is produced and supplied to the aeration tank to react with the waste water (S360), and if it is below the reference value, step S300 is performed. The value of each of the DO meter and the ORP meter of the wastewater supplied with the gas is measured and notified to the PLC (S370), and the PLC determines whether the measured values of the DO meter and the ORP meter are higher than the reference value (S380).

As a result of determination, step S4 of FIG. 2 is performed when the reference value is higher than the reference value, and step S330 is performed when the reference value is lower than the reference value.

FIG. 5 is a flowchart showing the detailed configuration of step S4 of FIG.

Signal related to production of gas (hereinafter referred to as 3-1 gas) of 21% oxygen concentration maximum production from PLC is notified to oxygen PSA to control oxygen PSA, and corresponding mixed gas is produced from controlled oxygen PSA and supplied to aeration tank And reacts with the waste water (S400), and the values of the DO meter and ORP meter of the 3-1 oxygen-supplied waste water are measured and notified to the PLC (S410), and the PLC measures the DO and ORP meters above the reference value. Determine whether (S420).

As a result of determination, if it is above the reference value, 70% of gas (hereinafter referred to as 3-2 gas) production related signal of the maximum production amount of 21% oxygen concentration is informed to the oxygen PSA from the PLC, and the oxygen PSA is controlled, and from the controlled oxygen PSA, The corresponding mixed gas is produced and supplied to the aeration tank to react with the waste water (S430), and if the reference value is less than or equal to the reference value, step S360 of FIG. 3 is performed. The value of each of the DO meter and the ORP meter of the waste water supplied with the second gas is measured and notified to the PLC (S440), and the PLC determines whether the measured values of the DO meter and the ORP meter are higher than the reference value (S450).

As a result of determination, if it is above the reference value, a signal related to the production of 40% of gas (hereinafter referred to as 3-3 gas) of the maximum production of 21% oxygen concentration is notified from the PLC to the oxygen PSA so that the oxygen PSA is controlled and the oxygen PSA is controlled. The corresponding mixed gas is produced and supplied to the aeration tank to react with the waste water (S460), and if it is below the reference value, step S400 is performed. The value of each of the DO meter and the ORP meter of the wastewater supplied with the gas is measured and notified to the PLC (S470), and the PLC determines whether the measured values of the DO meter and the ORP meter are lower than the reference value (S480).

As a result of the determination, when the reference value is less than the reference value, step S430 is performed, and when the reference value is higher than the reference value, step S460 is performed to treat the wastewater.

In the following, embodiments of the method according to the present invention are described.

The aeration tank used in this embodiment has a treatment capacity of 10 m ³ / day and is a closed type with a total volume of 1 m ³ and a three-stage type. In addition, oxygen PSA is a two tower unit capable of producing 2 Nm ³ / hr of a mixed gas having a 90% oxygen concentration, and ZMS 5A was used as the adsorbent. The DO meters used in this example range from 0 to 15 mg / L and the ORP meters range from -100 to 1000 mV. The wastewater used for the treatment is a comprehensive wastewater in pharmaceutical complexes, and was treated through continuous operation.

The COD _Mn value of the wastewater first introduced into the aeration tank was about 500-2500 mg / L, and the DO and ORP meters were inserted one third from the bottom of the second stage of the three-stage aeration tank. Used. The revolution per minute (RPM) of the surface aerator was designed to keep the first stage 250, the second stage 250, and the third stage 150. In this state, when 2Nm ³ / hr of mixed gas with 90% oxygen concentration was continuously supplied to the aeration tank, DO value was 10-15 mg / L, ORP value was 50mV or more, throughput was 85-90%, COD _Mn Levels ranged from 60 to 80 mg / L.

On the other hand, by measuring the values while changing the concentration and amount of oxygen produced by the oxygen PSA supplied to the aeration tank, the values shown in the table below were obtained.

Oxygen concentration (%) Production gas (Nm ³ / hr) DO (mg / L) ORP (mV) efficiency(%) COD _Mn (mg / L) 90 2 One -350-250 60 200-500 60 6 10 50 85 80 60 4.19 (70% of 6) 8 30 85 80 60 2.4 (40% of 6) One -250 60 300-500

As shown in the table above, 70% of the maximum gas yield (6Nm ³ / hr in this example) at 60% oxygen concentration is 60% oxygen concentration when the used pharmaceutical wastewater is treated with oxygen PSA. that is, it was confirmed to be the most appropriate for the oxygen ^{2.51Nm 3 /hr(4.19Nm 3 /hr*.6=2.51Nm 3 / hr} ) is fed to the aeration tank.

According to the present invention, in the wastewater treatment method by controlling the oxygen concentration and amount of the feed gas, in consideration of the reactivity by the concentration and the amount of organic matter contained in the wastewater by producing the optimum amount of gas under the optimum oxygen concentration The oxygen recovery rate of oxygen PSA can be increased, the operation time can be shortened, and the cost of oxygen production can be reduced.

In addition, since it is independent of the environment of the wastewater treatment plant, the concentration and amount of the wastewater discharged are easily applicable to the wastewater treatment plant.

Claims (4)

In the wastewater treatment method, A first step in which wastewater flows into an aeration tank in which a DO meter and an ORP meter are installed; The measurements of the DO and ORP meters are sent to a PLC connected to the DO and ORP meters, and when the measurements are judged to be below the reference values for a certain period of time, the maximum output gas of 90% oxygen concentration from the PLC 1 gas) a second step in which a production related signal is notified to the oxygen PSA so that the oxygen PSA is controlled, a first gas is produced from the controlled oxygen PSA, supplied to the aeration tank, and reacted with the waste water; The measurements of the DO and ORP meters are sent to a PLC connected to the DO and ORP meters, and if the measurements are all determined to be above the reference values for a period of time, then the maximum yield gas of 60% oxygen concentration from the PLC 2-1 gas) a production-related signal is notified to the oxygen PSA to control the oxygen PSA, and a second step of producing a 2-1 gas from the controlled oxygen PSA and supplying it to the aeration tank to react with the wastewater; And The measurements of the DO and ORP meters are sent to a PLC connected to the DO and ORP meters, and if the measurements are all determined to be above the reference values for a period of time, then the maximum production gas of 21% oxygen concentration from the PLC 3-1 gas) The production-related signal is notified to the oxygen PSA so that the oxygen PSA is controlled, and the 3-1 gas is produced from the controlled oxygen PSA and supplied to the aeration tank to react with the wastewater. Wastewater treatment method by controlling the oxygen concentration and amount of the supply gas, characterized in that consisting of. The method of claim 1, The third step, When the values of each of the DO meter and the ORP meter of the waste water supplied with the 2-1 gas are measured and both are less than or equal to a predetermined reference value for a predetermined time, the second step is performed, and both are greater than or equal to the predetermined reference value for a predetermined time. The oxygen production change-related signal is notified to the oxygen PSA to control the oxygen PSA, and from the controlled oxygen PSA, 70% of gas (hereinafter referred to as 2-2 gas) of the maximum yield of 60% oxygen concentration is produced and supplied to the aeration tank. Step 3-1 reacting with the wastewater; And When the values of each of the DO meter and the ORP meter of the waste water supplied with the second gas are measured and both are less than or equal to a predetermined reference value for a predetermined time, the third step is performed, and both are greater than or equal to the predetermined reference value for a predetermined time. Oxygen PSA-related signals are notified to the oxygen PSA to control the oxygen PSA, and from the controlled oxygen PSA, 40% of the gas at the maximum yield of 60% oxygen is produced and supplied to the aeration tank to react with the wastewater. Wastewater treatment method by controlling the oxygen concentration and amount of the supply gas further comprising. The method of claim 2, The fourth step, When the values of the DO meter and the ORP meter of the waste water supplied with the 3-1 gas are respectively measured and are less than or equal to a predetermined reference value for a predetermined time, the step 3-2 is performed, and both are equal to or greater than the predetermined reference value for a predetermined time. In this case, the oxygen production change-related signal is notified to the oxygen PSA to control the oxygen PSA, and from the controlled oxygen PSA, 70% of gas (hereinafter referred to as "3-2 gas") of the maximum yield of 21% oxygen concentration is produced and supplied to the aeration tank. A 4-1 step of supplying and reacting with the waste water; And When the value of each of the DO meter and the ORP meter of the waste water supplied with the second gas is measured and both are less than or equal to a predetermined reference value for a predetermined time, the fourth step is performed, and if both are greater than or equal to the predetermined reference value for a predetermined time. Oxygen production change-related signal is notified to the oxygen PSA to control the oxygen PSA, step 4-2 in which 40% of the maximum production amount of 21% oxygen concentration is produced from the controlled oxygen PSA and supplied to the aeration tank to react with the wastewater. Wastewater treatment method by controlling the oxygen concentration and amount of the supply gas further comprising. In the wastewater treatment apparatus, A DO meter for measuring the amount of dissolved oxygen in the waste water and an ORP meter for measuring the oxidation / reduction potential of the waste water, the aeration tank in which the waste water is aerated; Compressor for compressing the raw air, raw material tank for storing the compressed raw air, flow rate control valve for adjusting the production amount of the oxygen PSA by adjusting the amount of opening and closing of the raw air into the oxygen PSA through the adjustment of the degree of opening and closing, unnecessary of the raw air An oxygen PSA configured to generate a mixed gas containing oxygen and to supply the aeration tank, the product tank including an adsorption tower for adsorbing components to be discharged to waste gas and storing a mixed gas produced including oxygen; And It is equipped with a program related to the oxygen PSA control, which is connected to the DO meter and ORP meter to determine the oxygen concentration and amount of the mixed gas to be produced by receiving each measurement value, and control the oxygen PSA by notifying the related signal. PLC Wastewater treatment apparatus by controlling the oxygen concentration and amount of the supply gas, characterized in that consisting of.