CN213680289U - Ultrasonic wave and H2O2And micro-channel advanced oxidation device - Google Patents
Ultrasonic wave and H2O2And micro-channel advanced oxidation device Download PDFInfo
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- CN213680289U CN213680289U CN202022615932.0U CN202022615932U CN213680289U CN 213680289 U CN213680289 U CN 213680289U CN 202022615932 U CN202022615932 U CN 202022615932U CN 213680289 U CN213680289 U CN 213680289U
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- AHEWZZJEDQVLOP-UHFFFAOYSA-N monobromobimane Chemical compound BrCC1=C(C)C(=O)N2N1C(C)=C(C)C2=O AHEWZZJEDQVLOP-UHFFFAOYSA-N 0.000 claims description 7
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- BFCFYVKQTRLZHA-UHFFFAOYSA-N 1-chloro-2-nitrobenzene Chemical group [O-][N+](=O)C1=CC=CC=C1Cl BFCFYVKQTRLZHA-UHFFFAOYSA-N 0.000 description 1
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Abstract
The application discloses supersound, H2O2The micro-channel advanced oxidation device comprises an organic matter temporary storage device, a first conveying device, a hydrogen peroxide temporary storage device, a second conveying device, a micro-channel reactor, an ultrasonic generator and a sewage biochemical treatment unit; the organic matter temporary storage device links to each other and the pending waste water in the organic matter temporary storage device can send into the microchannel reactor through first conveyor in with the microchannel reactor through first conveyor, hydrogen peroxide solution temporary storage device links to each other and hydrogen peroxide solution temporary storage device can add hydrogen peroxide solution so that hydrogen peroxide solution and the pending waste water that gets into in the microchannel reactor mix according to the settlement proportion and obtain the oxidation intermediate liquid in the microchannel reactor through second conveyor and microchannel reactor in to the microchannel reactor links to each other, the microchannel reactor links to each other with sewage biochemical treatment unit. This application realizes hydrogen peroxide's quick decomposition through the ultrasonic wave, effectively promotes the concentration of free radical in the solution, and then promotes the treatment effeciency of organic matter waste water.
Description
Technical Field
The invention relates to the field of pollutant treatment, in particular to the field of pollutant treatment containing organic matters, and specifically relates to ultrasonic and H2O2And a microchannel advanced oxidation device. The efficiency of hydrogen peroxide for generating free radicals is promoted by utilizing ultrasound, and the treatment effect is improved.
Background
High organic matter wastewater is common wastewater which is difficult to treat, generally refers to wastewater with high organic matter content and complex components, and the wastewater usually contains a large amount of refractory organic matters such as aromatic hydrocarbons, heterocyclic rings and the like. High organic matter industrial wastewater is generally difficult to treat by a biological method due to a large amount of refractory organic matters such as aromatic hydrocarbons, heterocyclic rings and the like contained in the wastewater. At present, the existing treatment method for high organic wastewater generally has the problems of large equipment investment, high treatment cost and the like, and limits the application of corresponding technologies.
Chinese patent application CN201911174692.0 discloses a process for treating wastewater from the production process of sulfenamide accelerators, which comprises the following steps: (1) standing and settling the wastewater of the production process of the sulfenamide accelerant, and filtering after settling is finished to obtain a first filtrate; (2) carrying out ion exchange on the first filtrate obtained in the step (1), and obtaining exchanged liquid after the exchange is finished; (3) adjusting the pH value of the exchanged liquid obtained in the step (2), and then performing catalytic oxidation to obtain a treated liquid; (4) adjusting the pH value of the treated liquid obtained in the step (3), cooling, filtering to obtain a second filtrate, and performing secondary oxidation treatment to obtain a secondary oxidation liquid; (5) sequentially carrying out purification operation and concentration operation on the secondary oxidation liquid obtained in the step (4), and then filtering to obtain wet salt and mother liquor; wherein, the condensed water generated in the concentration operation is purified and then mixed with the wet salt for preparing alkali by an ionic membrane; the mother liquor is returned as wastewater for secondary treatment and utilization.
Chinese patent application CN201911174742.5 discloses a treatment method of rubber auxiliary agent production wastewater, which comprises the following steps: (1) removing impurities from rubber auxiliary production wastewater; (2) extracting the wastewater subjected to impurity removal in the step (1); (3) evaporating and concentrating the wastewater extracted in the step (2), and filtering to obtain industrial wet salt and an evaporation mother liquor; (4) and (4) carrying out catalytic oxidation treatment on the evaporation mother liquor obtained in the step (3), and reusing the obtained treatment liquor for evaporation concentration in the step (3).
The Chinese patent application CN201911174711.X discloses a treatment method of high-salt high-organic matter industrial wastewater, which comprises the following steps: (1) standing and settling the high-salt high-organic matter industrial wastewater and filtering; (2) carrying out ion exchange on the industrial wastewater filtered in the step (1); (3) adjusting the industrial wastewater subjected to ion exchange in the step (2) to acidity, and then carrying out catalytic oxidation; (4) adjusting the industrial wastewater subjected to catalytic oxidation in the step (3) to be alkaline, cooling and filtering, and performing secondary oxidation; (5) and (4) purifying the industrial wastewater subjected to secondary oxidation in the step (4) by using resin, evaporating and concentrating, and filtering to obtain solid salt.
The method is mainly used for treating the high-salt high-organic matter industrial wastewater, and the substances of the method are as follows: the salt in the industrial wastewater is removed through ion exchange or concentration evaporation, and then the organic matters in the industrial wastewater are removed through oxidation treatment. Therefore, it is essential to achieve high organic matter content wastewater treatment for oxidation treatment of organic matter in organic matter-containing wastewater.
To this end, the present application provides a method and/or apparatus to address the above-mentioned problems.
Disclosure of Invention
The invention aims to provide an ultrasonic wave H2O2And a microchannel advanced oxidation device. This application realizes hydrogen peroxide's quick decomposition through the ultrasonic wave, effectively promotes the concentration of free radical in the solution, and then promotes the treatment effeciency of organic matter waste water. Simultaneously, by ultrasound, H2O2And the micro-channel, and the sewage biochemical treatment are matched to realize the rapid and efficient degradation of the wastewater containing organic matters.
In order to achieve the purpose, the invention adopts the following technical scheme:
ultrasonic wave and H2O2The micro-channel advanced oxidation device comprises an organic matter temporary storage device, a first conveying device, a hydrogen peroxide temporary storage device, a second conveying device, a micro-channel reactor, an ultrasonic generator and a sewage biochemical treatment unit;
the device comprises an organic matter temporary storage device, a first conveying device, a hydrogen peroxide temporary storage device, a micro-channel reactor, a micro-channel biochemical treatment unit and a hydrogen peroxide temporary storage device, wherein the organic matter temporary storage device is connected with the micro-channel reactor through the first conveying device, wastewater to be treated in the organic matter temporary storage device can be conveyed into the micro-channel reactor through the first conveying device, the hydrogen peroxide temporary storage device is connected with the micro-channel reactor through a second conveying device, the hydrogen peroxide temporary storage device can add hydrogen peroxide into the micro-channel reactor through the second conveying device, so that the hydrogen peroxide and the wastewater to be treated entering the micro-channel reactor are mixed according to a set proportion to obtain an oxidized intermediate liquid, the micro-channel reactor is connected with the sewage biochemical treatment unit, the oxidized intermediate liquid can obtain an ultrasonic intermediate liquid after reacting in the micro-channel;
the ultrasonic generator is arranged outside the microchannel of the microchannel reactor, and ultrasonic waves generated by the ultrasonic generator can carry out ultrasonic treatment on the solution in the microchannel reactor.
The temporary storage device for organic matters is a temporary storage device for waste water containing organic matters;
or the waste gas pump is used for absorbing waste gas, the gas outlet of the waste gas pump is connected with the waste water temporary storage device, and the waste gas absorbed by the waste gas pump can be sent into the aqueous solution of the waste water temporary storage device and can absorb pollutants containing organic matters in the waste gas through the aqueous solution.
The first conveying device and the second conveying device are respectively conveying pumps.
The sewage biochemical treatment unit is one or more of a biological film biochemical treatment device and an activated sludge biochemical treatment device.
The sewage biochemical treatment unit is one or more of an MBR system, an MBBR system and an A3/O-MBBR system.
The sewage biochemical treatment unit is an MBBR system, and comprises a biological filler component, an aerobic tank, an oxygen input device, a biological membrane reaction tank and a drainage device, wherein the biological filler component is composed of at least one biological filler tank, the microchannel reactor is connected with the biological filler component, the biological filler component is connected with the aerobic tank, and materials processed in the biological filler component can be fed into the aerobic tank for treatment, the oxygen input device is connected with the aerobic tank, and the oxygen input device can feed air into the aerobic tank to promote the aerobic reaction in the aerobic tank, the aerobic tank is connected with the biological membrane reaction tank, and the materials processed in the aerobic tank can be fed into the biological membrane reaction tank for treatment, and the biological membrane reaction tank is connected with the drainage device, and clean water solution processed in the biological membrane reaction tank can be discharged through the drainage device.
The device also comprises a sludge treatment device, wherein the sludge treatment device is connected with the biomembrane reaction tank, and the sludge generated by the biomembrane reaction tank can be sent into the sludge treatment device for treatment.
The biological filler component is formed by sequentially connecting at least two biological filler tanks in series, and the ultrasonic intermediate liquid treated by the microchannel reactor can be sent into the biological filler component and treated one by the biological filler tanks.
The aeration pipe is arranged at the bottom of the aerobic tank, the aeration pipe is connected with the air inlet pump, and air sucked by the air inlet pump can enter the aerobic tank through air holes in the aeration pipe.
The microchannel reactor comprises a water inlet tank, a microchannel and an intermediate water tank, wherein two ends of the microchannel are respectively connected with the water inlet tank and the intermediate water tank, a solution entering the microchannel through the water inlet tank can enter the intermediate water tank after reacting in the microchannel, the water inlet tank is connected with a second conveying device, a gas-liquid mixture mixed in the second conveying device can enter the microchannel through the water inlet tank, the intermediate water tank is connected with a biological filler component, and a material in the intermediate water tank can enter the biological filler component for treatment.
The present application seeks to provide a green treatment system that reduces capital and operating costs and does not produce secondary pollution, and meets the user's treatment needs for such wastewater.
In the application, hydrogen peroxide is mixed with a wastewater solution to be treated, or after the waste gas to be treated is dissolved by water, the solution dissolving the waste gas is mixed with the hydrogen peroxide to obtain an oxidation intermediate solution. Then feeding the oxidized intermediate liquid into a microchannel of the microchannel reactor to enable the oxidized intermediate liquid to react in the microchannel; carrying out ultrasonic treatment on the oxidized intermediate liquid in the micro-channel by an ultrasonic generator while conveying the oxidized intermediate liquid in the micro-channel; obtaining an ultrasonic intermediate liquid after the ultrasonic treatment of the oxidation intermediate liquid in the microchannel is completed; in the process, part of small molecular organic matters are decomposed, and benzene rings, miscellaneous chains and the like contained in high-concentration refractory organic matters are broken or decomposed, so that the ultrasonic intermediate liquid is obtained. And finally, carrying out sewage biochemical treatment on the ultrasonic intermediate liquid.
In the present application, hydrogen peroxide itself can decompose to produce hydroxyl radicals. Simultaneously, under the radiation catalysis of external ultrasonic wave, H2O2Accelerating the formation of various free radicals including hydroxyl radical. Based on the double generation function of free radicals in hydrogen peroxide, the decomposition product can be fully mixed with liquid and quickly react, so that the mineralization and oxidation efficiency and the application range of organic matters are further improved. In the application, when ultrasonic waves with the frequency of more than 30kHz are input into liquid in a microchannel, the attractive force among liquid phase molecules is broken, cavitation bubbles with the temperature of 5500 ℃ and 50-100 MPa are formed, and the cavitation bubbles are compressed in a very short time to generate transient cavitation and steady cavitation phenomena. Gas bubbles or violent non-linear vibrations in microchannelsOscillating or generating microjet at bubble interface due to high-speed gradient when oscillation is strong, so that H is2O molecules (O-H bond energy in water molecules is 500kJ/mol) are decomposed into H and OH free radicals; meanwhile, micrometer-level liquid circulation (namely, micro sound flow) induced by cavitation bubble radiation torsion enables the bubble surface to form high speed gradient and viscous stress, and therefore carbon bonds on the main chain of the macromolecule are broken. The method is based on external field strengthening, achieves the channel internal cavitation effect of the microchannel by adding ultrasonic waves, generates hydroxyl free radicals, adopts a gas-liquid double-phase bubble flow pattern design, is matched with the microchannel reaction of the microchannel reactor, achieves micron-scale cutting of flowing liquid, improves mass transfer, heat transfer and energy transfer efficiency, and ensures that free radicals generated by hydrogen peroxide and ultrasonic waves are fully mixed with the liquid. In the application, under the ultrasonic wave cooperation, the decomposition product of the hydrogen peroxide is fully mixed with the liquid and quickly reacts, so that the mineralization and oxidation efficiency and the application range of the organic matters are further improved. Based on the cooperative treatment of the ultrasound, the hydrogen peroxide and the micro-channel, the high-concentration degradation-resistant organic wastewater can be treated and utilized more economically, efficiently and safely.
To sum up, this application provides an supersound, hydrogen peroxide solution and microchannel advanced oxidation device, and this method integrates supersound, hydrogen peroxide solution and microchannel waste water treatment technology advantage in an organic whole, with the organic pollutant in the high concentration difficult degradation waste water quick, high-efficient oxidative decomposition, cooperate sewage biochemical treatment again, realize the effective degradation of small molecule organic matter. Through determination, the wastewater containing over ten thousand levels of COD can reach the standard discharge standard after being treated by adopting the method. The application combines the ultrasonic method, the hydrogen peroxide method and the micro-channel method for the first time, utilizes the ultrasonic to generate transient cavitation and stable cavitation, is matched with the hydrogen peroxide and the micro-channel treatment, and utilizes the ultrasonic wave to catalyze and decompose the hydrogen peroxide, and can realize more economic, efficient and safe treatment and utilization of the high-concentration refractory organic wastewater.
Drawings
The invention will now be described, by way of example, with reference to the accompanying drawings, in which:
fig. 1 is a schematic structural view of embodiment 1.
The labels in the figure are: 1. the device comprises an organic matter temporary storage device, a first conveying device, a hydrogen peroxide temporary storage device, a second conveying device, a water inlet tank, a micro-channel, a middle water tank, an ultrasonic generator, a sewage biochemical treatment unit and a sewage biochemical treatment unit, wherein the organic matter temporary storage device is 2, the first conveying device is 3, the hydrogen peroxide temporary storage device is 4, the second conveying device is 5, the water inlet tank is 6.
Detailed Description
All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations of features and/or steps that are mutually exclusive.
Any feature disclosed in this specification may be replaced by alternative features serving equivalent or similar purposes, unless expressly stated otherwise. That is, unless expressly stated otherwise, each feature is only an example of a generic series of equivalent or similar features.
The device adopted in the embodiment of the application is shown in figure 1 and comprises an organic matter temporary storage device, a first conveying device, a hydrogen peroxide temporary storage device, a second conveying device, a micro-channel reactor, an ultrasonic generator and a sewage biochemical treatment unit. In this embodiment, the microchannel reactor includes a water inlet tank, a microchannel, and an intermediate water tank, and both ends of the microchannel are connected to the water inlet tank and the intermediate water tank, respectively. Wherein the number of the micro-channels is selected according to the throughput, and the number of the micro-channels in the micro-channel reactor is 10 in the embodiment4-106And (4) respectively.
In this embodiment, the organic matter temporary storage device is connected with the microchannel reactor through the first conveying device, the hydrogen peroxide temporary storage device is connected with the microchannel reactor through the second conveying device, the microchannel reactor is connected with the sewage biochemical treatment unit, and the ultrasonic generator is arranged outside the microchannel of the microchannel reactor.
By adopting the structure, the wastewater to be treated in the organic matter temporary storage device is conveyed into the microchannel reactor through the first conveying device, and the hydrogen peroxide temporary storage device adds hydrogen peroxide into the microchannel reactor through the second conveying device. By controlling the flow rates of the first conveying device and the second conveying device, the hydrogen peroxide and the wastewater to be treated entering the microchannel reactor can be mixed according to a set proportion, and then the oxidized intermediate liquid is obtained. The oxidized intermediate liquid reacts in the microchannel reactor, and the ultrasonic intermediate liquid can be obtained after the reaction is finished. While the liquid reacts in the microchannel reactor, the ultrasonic generator ultrasonically treats the solution in the microchannel reactor. And finally, sending the ultrasonic intermediate liquid into a sewage biochemical treatment unit for sewage biochemical treatment, thus realizing the treatment of the wastewater containing organic matters.
In this embodiment, the organic matter temporary storage device is a waste water temporary storage device containing organic matters, and the first conveying device and the second conveying device are respectively conveying pumps. Further, when handling the waste gas that contains the organic matter, this application still includes the exhaust pump that is used for absorbing waste gas, and the gas outlet and the waste water temporary storage device of exhaust pump link to each other. In the structure, waste gas absorbed by the waste gas pump can be sent into the aqueous solution of the temporary waste water storage device, and the absorption of pollutants containing organic matters in the waste gas is realized through the aqueous solution.
In this application, sewage biochemical treatment unit mainly used handles the micromolecular organic pollutant after the front end degradation. It can be one or more of a biological membrane biochemical treatment device and an activated sludge biochemical treatment device. As shown in the figure, the sewage biochemical treatment unit of the embodiment preferably adopts an A3/O-MBBR system; of course, MBR systems or MBBR systems may also be employed.
This example provides a specific embodiment. In this embodiment, the sewage biochemical treatment unit is an MBBR system, and includes a biological filler component, an aerobic tank, an oxygen input device, a biofilm reaction tank, and a drainage device, where the biological filler component is formed by sequentially connecting three biological filler tanks in series, the microchannel reactor is connected to the biological filler component, the biological filler component is connected to the aerobic tank, the oxygen input device is connected to the aerobic tank, the aerobic tank is connected to the biofilm reaction tank, and the biofilm reaction tank is connected to the drainage device. The MBBR system of this embodiment still includes the aeration pipe, admits air the pump, and the aeration pipe setting is in the bottom of good oxygen pond, and the aeration pipe links to each other with the pump that admits air, and the inspiratory air of pump that admits air gets into in the good oxygen pond through the gas pocket on the aeration pipe. By adopting the structure, the material in the middle water tank firstly enters the biological filler component and is sequentially treated by the three biological filler tanks; the material treated in the biological filler component is sent into an aerobic tank for treatment, and an oxygen input device is used for inputting air into the aerobic tank so as to promote the aerobic reaction in the aerobic tank; and the material treated by the aerobic tank is sent into the biomembrane reaction tank for treatment, and the clean water solution treated by the biomembrane reaction tank is discharged by a drainage device. Preferably, the embodiment further comprises a sludge treatment device, the sludge treatment device is connected with the biological membrane reaction tank, and sludge generated by the biological membrane reaction tank can be sent to the sludge treatment device for treatment.
Example 1
The waste water to be treated in the embodiment is chloronitrobenzene waste water with the initial CODCr value of 11500 mg/L.
The wastewater to be treated is treated by adopting the device, and the operation is as follows.
1) The first conveying device conveys the wastewater to be treated in the organic matter temporary storage device into a water inlet tank of the micro-channel reactor, the second conveying device conveys the hydrogen peroxide in the hydrogen peroxide temporary storage device into the water inlet tank of the micro-channel reactor, and the hydrogen peroxide and the wastewater to be treated in the micro-channel reactor are mixed according to a set proportion by controlling the flow rates of the first conveying device and the second conveying device to obtain oxidized intermediate liquid. In the oxidation intermediate solution, the addition amount of hydrogen peroxide is 50% H of 15ml/L (wastewater)2O2。
2) And feeding the oxidized intermediate liquid into a microchannel of the microchannel reactor to enable the oxidized intermediate liquid to react in the microchannel. And carrying out ultrasonic treatment on the oxidized intermediate liquid in the micro channel by an ultrasonic generator while conveying the oxidized intermediate liquid in the micro channel. And obtaining the ultrasonic intermediate liquid after the ultrasonic treatment of the oxidized intermediate liquid in the micro-channel is finished.
In the process, the gas-liquid mixture mixed in the dissolved air pump can enter the micro-channel through the water inlet groove, and the solution entering the micro-channel through the water inlet groove enters the intermediate water tank after reacting in the micro-channel. Wherein the inner diameter of the micro-channel is 150 micrometers, and the specific surface area of the fluid is 104m2/m3The number of micro-channels is 10 according to the processing requirement and the processing capacity4And (4) respectively. The flow rate of the liquid in the micro-channel is 20ml/min, and the power of the ultrasonic generator is tightThe degree is 0.5w/cm2The frequency of the applied ultrasonic wave was 30 kHz.
Wherein, the hydrogen peroxide can be decomposed to generate hydroxyl free radicals. Simultaneously, under the radiation catalysis of external ultrasonic wave, H2O2Accelerating the formation of various free radicals including hydroxyl radical. Carrying out ultrasonic treatment on the oxidized intermediate liquid in the microchannel by an ultrasonic generator to break the attractive force between liquid phase molecules to form cavitation bubbles, compressing the cavitation bubbles to realize the cavitation action of the microchannel, generating a gas-liquid two-phase bubble structure, initiating microjet at a bubble interface to decompose water molecules into free radicals, and forming a speed gradient and viscous stress for breaking carbon chains on a macromolecular main chain of the organic matter by a micrometer-level liquid circulation flow initiated by radiation torsion of the cavitation bubbles to break the macromolecular main chain of the organic matter; in the process that an ultrasonic generator carries out ultrasonic treatment on the oxidized intermediate liquid in the micro-channel, cavitation bubbles are generated to cut the liquid flowing through the micro-channel, so that the effects of improving heat transfer, mass transfer and energy transfer are achieved, and the reaction efficiency of free radicals and organic matters flowing through the liquid is promoted; by combining the functions of the hydrogen peroxide, the ultrasound and the micro-channel, the advanced oxidation of organic matters is realized, and then micromolecule and/or short-chain organic matters are formed.
3) And carrying out sewage biochemical treatment on the ultrasonic intermediate solution. In the embodiment, the ultrasonic intermediate liquid obtained in the step 2 is sent to an A3/O-MBBR system for sewage biochemical treatment, and qualified water can be directly discharged and/or recycled.
In the embodiment, the pretreated high-concentration degradation-resistant wastewater and hydrogen peroxide are mixed in a water inlet tank in proportion, and then ultrasonic waves are applied; the wastewater mixed with hydrogen peroxide and applied with ultrasonic waves enters a micro-channel reactor; in the microchannel reactor, a strong oxidation reaction is generated, so that most organic matters in the water are decomposed or degraded; the wastewater treated by the micro-channel reactor is sent to an A3/O-MBBR system for advanced treatment.
The ultrasonic intermediate liquid is tested, and the test results are as follows: CODCrThe concentration was 136 mg/L.
Example 2
The wastewater to be treated in the embodiment is molasses alcohol wastewater, and the COD value is 36000 mg/l.
Wherein the concentration of hydrogen peroxide in the intermediate oxidation solution is 50% H of 45ml/L (wastewater)2O2(ii) a In the step 2), the inner diameter of the micro-channel is 200 microns, the flow rate of liquid in the micro-channel is 20ml/min, and the power density of the ultrasonic generator is 0.5w/cm2The frequency of the applied ultrasonic wave was 30 kHz. The other operations were the same as in example 1.
The ultrasonic intermediate liquid is tested, and the test results are as follows: CODcr was 423 mg/L.
Example 3
The wastewater to be treated in the embodiment is printing and dyeing wastewater, the chroma is 4096 times, and the COD is 10240 mg/L.
Wherein the concentration of hydrogen peroxide in the intermediate oxidation solution is 50% H of 30ml/L (wastewater)2O2(ii) a In the step 2), the inner diameter of the micro-channel is 150 microns, the flow rate of liquid in the micro-channel is 25ml/min, and the power density of the ultrasonic generator is 0.5w/cm2The frequency of the applied ultrasonic wave was 40 kHz. The other operations were the same as in example 1.
The ultrasonic intermediate liquid is tested, and the test results are as follows: the chroma is 48 times, and the COD is 120 mg/L.
Example 4
The wastewater to be treated in this example was coking wastewater, and the phenol content was 1760 mg/L.
Wherein the concentration of hydrogen peroxide in the intermediate oxidation solution is 50% H of 15ml/L (wastewater)2O2(ii) a In the step 2), the inner diameter of the micro-channel is 200 microns, the flow rate of liquid in the micro-channel is 25ml/min, and the power density of the ultrasonic generator is 0.5w/cm2The frequency of the applied ultrasonic wave was 25 kHz. The other operations were the same as in example 1.
The ultrasonic intermediate liquid is tested, and the test results are as follows: the phenol concentration was 55 mg/L.
The invention is not limited to the foregoing embodiments. The invention extends to any novel feature or any novel combination of features disclosed in this specification and any novel method or process steps or any novel combination of features disclosed.
Claims (9)
1. Ultrasonic wave and H2O2The micro-channel advanced oxidation device is characterized by comprising an organic matter temporary storage device, a first conveying device, a hydrogen peroxide temporary storage device, a second conveying device, a micro-channel reactor, an ultrasonic generator and a sewage biochemical treatment unit;
the device comprises an organic matter temporary storage device, a first conveying device, a hydrogen peroxide temporary storage device, a micro-channel reactor, a micro-channel biochemical treatment unit and a hydrogen peroxide temporary storage device, wherein the organic matter temporary storage device is connected with the micro-channel reactor through the first conveying device, wastewater to be treated in the organic matter temporary storage device can be conveyed into the micro-channel reactor through the first conveying device, the hydrogen peroxide temporary storage device is connected with the micro-channel reactor through a second conveying device, the hydrogen peroxide temporary storage device can add hydrogen peroxide into the micro-channel reactor through the second conveying device, so that the hydrogen peroxide and the wastewater to be treated entering the micro-channel reactor are mixed according to a set proportion to obtain an oxidized intermediate liquid, the micro-channel reactor is connected with the sewage biochemical treatment unit, the oxidized intermediate liquid can obtain an ultrasonic intermediate liquid after reacting in the micro-channel;
the ultrasonic generator is arranged outside the microchannel of the microchannel reactor, and ultrasonic waves generated by the ultrasonic generator can carry out ultrasonic treatment on the solution in the microchannel reactor.
2. The apparatus of claim 1, wherein the first and second delivery devices are each a delivery pump.
3. The apparatus of claim 1, wherein the sewage biochemical treatment unit is one or more of a biofilm biochemical treatment apparatus and an activated sludge biochemical treatment apparatus.
4. The apparatus of claim 3, wherein the wastewater biochemical treatment unit is one or more of an MBR system, an MBBR system, and an A3/O-MBBR system.
5. The apparatus of claim 4, wherein the wastewater biochemical treatment unit is an MBBR system, which comprises a biological filler component, an aerobic tank, an oxygen input device, a biological film reaction tank and a drainage device, the biological filler component is composed of at least one biological filler pool, the microchannel reactor is connected with the biological filler component, the biological filler component is connected with the aerobic tank, and the materials treated in the biological filler component can be sent into the aerobic tank for treatment, the oxygen input device is connected with the aerobic tank and can input air into the aerobic tank to promote the aerobic reaction in the aerobic tank, the aerobic tank is connected with the biomembrane reaction tank, and the materials treated in the aerobic tank can be sent into the biomembrane reaction tank for treatment, the biomembrane reaction tank is connected with the drainage device, and the clean aqueous solution treated by the biomembrane reaction tank can be discharged through the drainage device.
6. The device as claimed in claim 5, further comprising a sludge treatment device, wherein the sludge treatment device is connected with the biomembrane reaction tank, and sludge generated by the biomembrane reaction tank can be sent to the sludge treatment device for treatment.
7. The device according to claim 5, wherein the biological filler component is formed by sequentially connecting at least two biological filler tanks in series, and the ultrasonic intermediate liquid treated by the microchannel reactor can be sent into the biological filler component and treated one by the biological filler tanks.
8. The apparatus of claim 5, further comprising an aeration pipe and an air intake pump, wherein the aeration pipe is arranged at the bottom of the aerobic tank, the aeration pipe is connected with the air intake pump, and air sucked by the air intake pump can enter the aerobic tank through air holes on the aeration pipe.
9. The device according to any one of claims 1 to 8, wherein the microchannel reactor comprises a water inlet tank, a microchannel and an intermediate water tank, two ends of the microchannel are respectively connected with the water inlet tank and the intermediate water tank, a solution entering the microchannel through the water inlet tank can enter the intermediate water tank after reacting in the microchannel, the water inlet tank is connected with the second conveying device, a gas-liquid mixture mixed in the second conveying device can enter the microchannel through the water inlet tank, the intermediate water tank is connected with the biological filler component, and a material in the intermediate water tank can enter the biological filler component for treatment.
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Cited By (1)
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| CN113003852A (en) * | 2020-11-13 | 2021-06-22 | 四川全息生态环境技术产业有限公司 | Ultrasonic wave and H2O2And micro-channel advanced oxidation method and device |
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
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| CN113003852A (en) * | 2020-11-13 | 2021-06-22 | 四川全息生态环境技术产业有限公司 | Ultrasonic wave and H2O2And micro-channel advanced oxidation method and device |
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