KR20230151841A - Electrodialysis system for the management of wastewater and circulation water of wet scrubber - Google Patents

Abstract

The present invention purifies air pollutants generated from incineration processes, etc. through a wet scrubbing tower, and provides wastewater generated from a wet exhaust gas purification facility configured to maintain a constant ion concentration of the washing water and reduce the amount of concentrated water generated. and an electrodialysis system for managing circulating cleaning water. More specifically, a purification space through which exhaust gas containing contaminants passes is provided, cleaning water flows in, and the introduced cleaning water is sprayed from the purifying space. A wet washing tower equipped with a plurality of spray nozzles; And an ED treatment unit that recovers the washing wastewater used in the wet washing tower and separates and discharges ionic contaminants from the washing wastewater recovered through electro dialysis.

Description

Electrodialysis system for the management of wastewater and circulation water of wet scrubber}

The present invention purifies air pollutants generated from incineration processes, etc. through a wet scrubbing tower, and provides wastewater generated from a wet exhaust gas purification facility configured to maintain a constant ion concentration of the washing water and reduce the amount of concentrated water generated. and an electrodialysis system for managing circulating washing water.

With rapid industrial development, a large amount of various wastes, such as industrial waste and household waste, are being produced, which is acting as a major cause of environmental pollution.

Accordingly, incinerated waste, especially waste that takes a long time to decompose, is generally disposed of by incineration instead of landfill. however. In this way, the process of incinerating waste inevitably involves the generation of exhaust gases due to combustion, and these exhaust gases are known to contain various harmful substances.

For example, the exhaust gas from an incinerator where waste is incinerated due to nitrogen, sulfur, chlorine and other organic substances contained in the waste contains various harmful substances such as nitrogen oxides, sulfur dioxide, hydrogen chloride and dioxin, as well as a large amount of dust. , these harmful substances not only have a direct negative impact on the human body, but also cause smog and acid rain, causing serious environmental problems.

Accordingly, in order to protect public health and the environment, the above hazardous substances must be removed from the exhaust gases of incinerators and then discharged into the atmosphere. To this end, the concentration of hazardous substances in the exhaust gases emitted from incinerators is regulated by law. Therefore, waste incineration facilities are equipped with hazardous substance prevention facilities that collect exhaust gases emitted from the incineration process, purify them, remove hazardous substances, and then discharge them. A representative example of such prevention facilities is the wet scrubber tower, which shows excellent purification efficiency. is using.

These wet washing towers are generally equipment that removes pollutants contained in the exhaust gas by spraying washing water into the exhaust gas containing ionic pollutants. Although the treatment efficiency is high, a large amount of waste water containing secondary pollutants is generated.

In addition, the washing water used in the wet washing tower is repeatedly used by circulating the washing water within the wet washing tower as a way to reduce the amount of wastewater generated, so the inorganic ion concentration of the circulating washing water is maintained at a high level. .

Accordingly, in the case of conventional wet washing towers, scale is generated inside the piping or the washing tower due to the high concentration of inorganic ions, and the consumption of chemicals such as NaOH, which is added to prevent corrosion problems due to pH reduction, increases excessively, which causes maintenance problems. There is a problem in that not only is the maintenance period short, but the operating costs increase accordingly.

In addition, in the case of high-concentration inorganic ion concentrated wastewater, it must be treated through separate consignment treatment, causing an increase in treatment costs. Therefore, there is a need for a method to absolutely reduce the amount of high-concentration concentrated wastewater generated from wet scrubbing towers.

Republic of Korea Patent No. 10-1943914 (announced on January 30, 2019)

Therefore, the object of the present invention is to provide a wet exhaust gas purification facility that can maintain a constant ion concentration of the washing water and reduce the amount of concentrated water generated in purifying air pollutants generated from the incineration process through a wet washing tower. The purpose is to provide an electrodialysis system for managing generated wastewater and circulating cleaning water.

As a means to solve the above-mentioned problems, an electrodialysis system for managing wastewater and circulating cleaning water of a wet exhaust gas purification facility of the present invention (hereinafter referred to as "system of the present invention") is an electrodialysis system that removes exhaust gas containing pollutants. A wet washing tower is provided with a purification space through which water flows, and is equipped with a plurality of spray nozzles for spraying the inflow washing water into the purification space; And an ED treatment unit that recovers the washing wastewater used in the wet washing tower and separates and discharges ionic contaminants from the washing wastewater recovered through electro dialysis.

As an example, the ED processing unit has positive and negative electrodes disposed on one side and the other spaced apart from each other, and anion exchange membranes and cation exchange membranes are alternately disposed at regular intervals in the space between the positive electrode and the negative electrode to form a plurality of dilution chambers and ED module where an enrichment room is provided; It is connected to the wet washing tower through a first circulation line to selectively introduce the washing wastewater used in the wet washing tower, and is connected to the ED module through a second circulation line to supply the received washing wastewater to the ED module. A dilution tank into which treated water flows from the dilution chamber of the ED module; and a concentration tank into which the concentrated water treated in the concentration chamber of the ED module flows.

As an example, the wet washing tower includes a storage tank for receiving washing water; And a third circulation line connecting the storage tank and the spray nozzle to circulate the washing water contained in the storage tank.

As an example, the storage tank is provided in the purification space of the wet washing tower, and the dilution tank of the ED treatment unit utilizes the storage tank.

As an example, the storage tank used as the dilution tank of the ED processing unit is equipped with one or more sensor modules that measure ion concentration in real time and transmit the measured value, receive the measured value measured from the sensor module, and receive the measured value. It is characterized by further comprising a control unit that determines load fluctuations by comparing and analyzing the measured value with a preset reference value, and controls the voltage and current values supplied to the ED processing unit to be adjusted based on the determined load fluctuations.

As an example, the enrichment tank is connected to the enrichment chamber of the ED module through a fourth circulation line, receives concentrated water from the enrichment chamber of the ED module, and flows the received concentrated water into the enrichment chamber of the ED module. It is characterized by cumulative concentration by performing the supply circulation process at least twice.

The system of the present invention maintains the concentration of the washing water circulating inside the wet washing tower constant through the electrodialysis process, thereby dramatically reducing the consumption of chemicals for preventing corrosion of the purification system inside the washing tower and adjusting pH, thus maintaining the system. This has the effect of reducing management and drug usage, thereby reducing operating costs.

In addition, by concentrating and discharging the existing concentrated wastewater concentration of about 2% up to 10 to 15% through the electrodialysis process, the amount of replenishment water for washing water and the discharge of concentrated wastewater are reduced, reducing the cost of consignment wastewater treatment and connection with the downstream zero discharge system. It has the effect of dramatically reducing the capacity and operating costs of city evaporation and concentration facilities.

In particular, the washing water storage tank provided inside the wet washing tower is used concurrently as a dilution tank in the ED treatment unit, so that the dilution tank required in the general electrodialysis process and the circulation pump provided to operate the dilution tank as well as additional equipment to drive it are used. etc. can be excluded, and as a result, not only can the overall system and process configuration be simplified, but it has the effect of further improving the ease of facility investment and securing space.

1 is a diagram showing a system according to an embodiment of the present invention.
Figure 2 is a diagram showing the configuration of an ED processing unit according to an embodiment of the present invention.
Figure 3 is a diagram showing a system according to another embodiment of the present invention.
Figure 4 is a graph showing the power supply control method of the ED processing unit according to load fluctuations.

In describing the present invention, the terms and words used in the specification and claims are based on the principle that the inventor can appropriately define the concept of the term in order to explain the invention in the best way. It must be interpreted with meaning and concepts consistent with the technical ideas of.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

Referring to FIG. 1, the present invention includes a wet scrubbing tower (10) that collects exhaust gas generated from an incineration process, etc. and purifies air pollutants contained in the exhaust gas using washing water, and the wet scrubbing tower ( It includes an ED treatment unit 20 that not only reduces ionic contaminants in the washing wastewater generated during the purification treatment process of 10) so that it can be reused as washing water, but also maintains a constant concentration of inorganic ions in the washing water.

The wet scrubbing tower 10 is provided with a purification space 100 through which exhaust gas containing contaminants passes.

As an example, the wet scrubbing tower 10 has a purification space 100 inside, as shown in FIG. 1, an inlet 110 on the side through which exhaust gas flows into the purification space 100, and an upper may be provided with an outlet 120 through which exhaust gas in the purification space 100 is discharged to the outside.

In addition, the wet washing tower 10 is equipped with a plurality of spray nozzles 130 that spray the washing water flowing into the washing water and on the movement path of the purification space 100 through which the exhaust gas passes. In the process of gas being discharged to the outlet 120, air pollutants are removed by the washing water.

Since such a wet washing tower 10 can have various structures, it is natural that the wet washing tower 10 of the present invention is not limited to the structure shown in FIG. 1.

The ED treatment unit 20 recovers washing water (hereinafter referred to as “washing wastewater”) whose inorganic ion concentration has increased due to use for a long time in the wet washing tower 10, and washes the recovered water through electro dialysis. In addition to separating and discharging ionic contaminants from wastewater, the treated water from which ionic contaminants are separated can be reused as washing water for the wet scrubbing tower (10).

Specifically, as shown in FIG. 2, the ED treatment unit 20 receives the cleaning wastewater and dilutes the cleaning wastewater as treated water or concentrates ionic contaminants through an ion separation process using electrodialysis. ED module 200, a dilution tank 210 for receiving the treated water diluted in the ED module 200, a concentrating tank 220 for receiving the concentrated water concentrated in the ED module 200, and the ED module It includes an electrolyzer 230 for supplying electrolyzed water to 200.

The ED module 200 has a positive electrode 201 and a negative electrode 202 disposed on one side and the other spaced apart from each other, and an anion exchange membrane 203 and a cation exchange membrane (202) in the space between the positive electrode 201 and the negative electrode 202. 204) are arranged alternately at regular intervals to provide a plurality of dilution chambers 205 and concentration chambers 205.

At this time, the number of the dilution chamber 205 and the concentration chamber 205 may be determined depending on the processing capacity, and the dilution tank 210 and the concentration tank 220 are diluted through the second circulation line and the fourth circulation line described below. It is interconnected to enable circulation of the treated water and concentrated water.

The positive electrode 201 and the negative electrode 202 of the ED module 200 are each composed of an electrolytic chamber containing electrodes, and Na ₂ SO ₄ , H ₂ SO ₄ , KCl, etc. are used to prevent side reactions of the electrodes contained in the electrolytic chamber. The same electrolyte solution is supplied from the electrolytic cell 230.

The electrolyte cell 230 accommodates the aforementioned electrolyte solution, and can circulate the electrolyte solution to continuously supply and recover the electrolyte solution to each electrolyte chamber of the ED module 200.

To briefly explain the operation and mechanism of the ED module 200, first, a direct current voltage applied from the outside is supplied to the positive electrode 201 and the negative electrode 202 to carry out the electrodialysis reaction of the ED module 200. Afterwards, the cleaning wastewater contained in the dilution tank 210 is supplied to the ED module 200.

The cleaning wastewater flows from the ED module 200 into each dilution chamber 205. Among the ions present in the cleaning wastewater flowing into each dilution chamber 205, positive ions tend to move toward the negative electrode 202, and negative ions In the case of , it moves in the direction of the positive electrode 201.

That is, in the cleaning wastewater flowing into the Heesik room 205, positive ions pass through the cation exchange membrane 204 and move toward the negative electrode 201, and negative ions pass through the anion exchange membrane 203 toward the positive electrode 201. As it moves, the ionic contaminants in the dilution chamber 205 move to the concentration chambers 206 on both adjacent sides.

Conversely, cations and anions moved to the concentration chamber 206 do not pass through the anion exchange membrane 203 and the cation exchange membrane 204, respectively, and remain in the concentration chamber 206. As a result, in each concentration chamber 206, adjacent As cations and anions moved from both dilution chambers 205 continue to accumulate, concentration occurs, and cations and anions continue to escape from the adjacent dilution chambers 205, thereby desalting the washing wastewater.

Thereafter, the treated water from which ionic contaminants have been separated in the dilution chamber 205 may be discharged during circulation through the second circulation line and received into the dilution tank 210.

In addition, the enrichment tank 220 is also connected to the ED module 200 through a fourth circulation line so that a circulation process can be performed, and the concentrated water concentrated and discharged from the enrichment chamber 206 of the ED module 200 Can be accommodated in the enrichment tank 220.

The electrodialysis process using the ED module 200 can be operated in batches until the ion concentration of the washing wastewater reaches a preset specific concentration, and the dilution tank 210 is formed over time through each cycle. The concentration gradually decreases, and conversely, the concentration in the enrichment tank 220 increases.

Meanwhile, the dilution tank 210 is connected to the wet washing tower 10 through a first circulation line, so that the washing wastewater used in the wet washing tower 10 can be selectively introduced.

As shown in FIG. 1, the first circulation line is a recovery pipe 211 that recovers the cleaning wastewater of the wet scrubbing tower 10 and supplies the treated water diluted in the dilution tank 210 to the wet scrubbing tower as washing water. It may include a resupply pipe 212 for supply, and may include a pump 213 and a valve 214 for controlling the circulation of fluid by the return pipe 211 and the resupply pipe 212.

And the dilution tank 210 is connected to the dilution chamber 205 of the ED module 200 through a second circulation line to supply the received cleaning wastewater to the ED module 200 or to the dilution chamber 205 of the ED module 200. The treated water from the dilution chamber 205 flows in and receives it.

The second circulation line is connected to the first inlet pipe 215, which is connected to the inlet side of the dilution chamber 205 of the ED module 200, and the discharge side of the dilution chamber 205 of the ED module 200. It may include a first discharge pipe 216, and may include a pump 217 for controlling the circulation of the cleaning wastewater contained in the dilution tank 210.

The concentrated water treated in the enrichment chamber 206 of the ED module 200 flows into the enrichment tank 220.

As described above, this enrichment tank 220 can be connected to the enrichment chamber 206 of the ED module 200 through the fourth circulation line, and the concentrated water concentrated in the enrichment chamber 206 of the ED module 200 The circulation process of flowing in, receiving, and supplying the received concentrated water to the concentration chamber 206 of the ED module 200 can be carried out at least twice for cumulative concentration.

Like the second circulation line, the fourth circulation line includes a second inlet pipe 221 connected to the inlet side of the enrichment chamber 206 of the ED module 200, and a enrichment chamber of the ED module 200 ( It may include a second discharge pipe 222 connected to the discharge side of the concentrator 206) and may include a pump 223 for controlling circulation of the concentrated water contained in the enrichment tank 220.

In addition, the concentrated water accumulated in the enrichment tank 220 is not shown in the drawing, but when the preset target concentration is reached through measurement by a sensor mounted on the enrichment tank 220, the operation and circulation process of the ED module 200 After temporarily stopping the waste, it can be discharged to the outside and processed separately through consignment processing.

In this way, in the present invention, the washing wastewater from the wet washing tower 10 is collected in the ED treatment unit 20, and ionic contaminants are separated and removed by electrodialysis, and the ionic contaminants are removed in the dilution tank. The treated water of 210 is supplied and circulated back to the wet washing tower 10 through the first circulation line as washing water, so that the inorganic ion concentration of the washing water used in the wet washing tower 10 is kept constant. Not only can it be maintained, but it is also possible to minimize the amount of washing water used and replenishment.

In particular, it is possible to prevent the formation of scale inside the pipes and the washing tower due to the high concentration of inorganic ions in the washing water used in the wet washing tower (10), and exclude chemicals such as NaOH, which are added to prevent corrosion due to pH reduction. This makes maintenance easier and reduces operating costs.

Meanwhile, the wet washing tower 10 has a storage tank 140 that accommodates washing water, and a third circulation line that connects the storage tank 140 and the spray nozzle 130 to circulate the washing water contained in the storage tank 140. It may further include.

The washing water contained in the storage tank 140 may be washing water replenished from the outside or treated water in which ionic contaminants are separated and treated in the ED treatment unit 20.

The third circulation line includes a first circulation pipe 151 connected to the storage tank 140 and a second circulation pipe 152 connected to the injection nozzle 130, and the first circulation pipe 151 and a pump 153 mounted between the second circulation pipe 152 and supplying the washing water contained in the storage tank 140 to the spray nozzle 130.

At this time, the storage tank 140 is provided in the purification space 100 of the wet washing tower 10 to be advantageous in terms of structure simplification and space utilization, and the dilution tank 210 of the ED processing unit 20 is the storage tank ( It is desirable to use 140).

That is, in the system of the present invention, as shown in FIG. 3, the storage tank 140 is provided in the lower part of the purification space 100 of the wet scrubbing tower 10, and this storage tank 140 is installed in the ED processing unit 20. It is configured to double as a dilution tank (210).

In this case, the first circulation means provided for circulation between the wet washing tower 10 and the dilution tank 210 is excluded.

In this way, the storage tank 140 of the wet washing tower 10 and the dilution tank 210 of the ED treatment unit 20 are provided in one space, so that the dilution tank and the dilution tank operation required in the general electrodialysis process are provided. It is possible to exclude the circulation pump as well as additional equipment to drive it, and as a result, not only can the overall system and process configuration be simplified, but the ease of investing in equipment and securing space can be further improved.

In addition, in this embodiment, in using the storage tank 140 of the wet washing tower 10 as the dilution tank 210 of the ED treatment unit 20, the ED treatment unit based on sensor measurement is used to maintain a constant concentration of the circulating washing water. It is characterized by being configured to control the amount of power supply (20).

In general, in the ED treatment unit 20 applying the electrodialysis method, the concentration of the dilution tank 210 is adjusted below a certain concentration and returned to the wet scrubbing tower 10, so that it is sensitive to load changes of ionic contaminants introduced from the atmosphere. Response is possible.

However, when circulation is performed directly through the dilution chamber 205 of the ED treatment unit 20 inside the wet scrubbing tower 10 as in the present embodiment, the ED treatment unit 20 carries a constant load equal to the applied voltage and current. Since it can only be treated, as the load introduced from the atmosphere increases, the concentration in the storage tank 140 of the wet scrubbing tower 10 gradually increases, thereby canceling out the effect of reducing chemical usage according to this embodiment. .

Also, on the contrary, when the inflow load decreases due to various causes, the concentration in the storage tank 140 also gradually decreases in proportion, and the ED processing unit 20 reaches the limit current density, which has negative effects on the performance and lifespan of the module due to side reactions. A problem arises that has an impact.

Accordingly, in this embodiment, when the storage tank 140 of the wet washing tower 10 is used as the dilution tank 210 of the ED treatment unit 20, the concentration of the storage tank 140 is adjusted to prevent the effects of the above-mentioned problems. It is characterized by monitoring load changes through real-time measurement, and controlling the voltage and current applied to the ED processing unit 20 to selectively adjust according to the monitoring results, that is, concentration changes.

As an example, the storage tank 140 is equipped with one or more sensor modules 141 for concentration measurement as shown in FIG. 3, and in the system of the present invention, the operating range of the dilution tank 210 of the ED processing unit 20 That is, it may further include a control unit 30 that sets a normal concentration range, compares and analyzes the set operating range and the measurement results of the sensor module 141, and adjusts the voltage and current applied to the ED processing unit 20. .

Here, the sensor module 141 can select a suitable one among various known sensors for measuring ion concentration, but it is preferable to use an electrical conductivity sensor.

The sensor module 141 is installed in the storage tank 140 used as the dilution tank 210 of the ED processing unit 20, measures the ion concentration in real time and sends the measured value to the control unit ( 30).

The control unit 30 may receive the measured value measured from the sensor module 141, compare and analyze the received measured value with a preset reference value, and determine the load change.

As mentioned above, the reference value is the operating range, that is, the normal concentration range, for the dilution tank 210, and load fluctuations can be determined through the ion concentration measured from the sensor module 141.

Additionally, the control unit 30 can control the voltage and current values supplied to the ED processing unit 20 to be adjusted based on the determined load change.

That is, as shown in FIG. 4, in the present invention, the operating range and ion concentration value for the storage tank 140 used as the dilution tank 210 of the ED processing unit 20 are preset, and the ion concentration value for the storage tank 140 is preset. As the concentration increases and the load gradually increases, the voltage value and current value increase when the increase limit range is reached. Conversely, as the ion concentration in the storage tank 140 decreases and the load gradually decreases, when the decrease limit range is reached, the ED processing unit By controlling to reduce the voltage value and current value applied to (20), stable operation can be performed.

In this way, in the present invention, the advantage of using the storage tank 140 of the wet washing tower 10 as the dilution tank 210 of the ED processing unit 20 is maintained through controlling the amount of power through the control unit 30, while maintaining the storage tank 140. ), it is possible to solve the problem of degradation of durability of the ED processing unit 20 due to load fluctuations.

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements made by those skilled in the art using the basic concept of the present invention defined in the following claims are also possible. falls within the scope of rights.

10: Wet washing tower 20: ED processing unit
100: purification space 110: inlet
120: outlet 130: main nozzle
200: ED module 201: positive electrode
202: negative electrode 203: anion exchange membrane
204: cation exchange membrane 205: dilution chamber
206: Concentration room 210: Dilution tank
220: Concentrator 230: Electrolyzer

Claims (6)

A wet washing tower is provided with a purification space through which exhaust gas containing contaminants passes, and is equipped with a plurality of spray nozzles through which washing water flows and sprays the introduced washing water into the purification space; and
Wet exhaust gas purification comprising an ED treatment unit that recovers the washing wastewater used in the wet washing tower and separates and discharges ionic contaminants from the washing wastewater recovered through electro dialysis. Electrodialysis system for managing wastewater generated from facilities and circulating cleaning water.
According to clause 1,
The ED processing unit,
An ED module in which positive and negative electrodes are disposed on one side and the other spaced apart from each other, and anion exchange membranes and cation exchange membranes are alternately arranged at regular intervals in the space between the positive electrode and the negative electrode to provide a plurality of dilution chambers and concentration chambers;
It is connected to the wet washing tower through a first circulation line to selectively introduce the washing wastewater used in the wet washing tower, and is connected to the ED module through a second circulation line to supply the received washing wastewater to the ED module. A dilution tank into which treated water flows from the dilution chamber of the ED module; and
An electrodialysis system for managing wastewater and circulating cleaning water from a wet exhaust gas purification facility, comprising: a concentration tank into which the concentrated water treated in the concentration chamber of the ED module flows.
According to clause 2,
The wet washing tower,
A storage tank for receiving washing water; and
An electrodialysis system for managing wastewater and circulating cleaning water from a wet exhaust gas purification facility, comprising: a third circulation line connecting the storage tank and the injection nozzle to circulate the cleaning water contained in the storage tank.
According to clause 3,
The storage tank is provided in the purification space of the wet washing tower,
An electrodialysis system for managing wastewater and circulating cleaning water from a wet exhaust gas purification facility, wherein the dilution tank of the ED treatment unit utilizes the storage tank.
According to clause 4,
The storage tank used as the dilution tank of the ED processing unit is equipped with one or more sensor modules that measure ion concentration in real time and transmit the measured value,
Measured values measured from the sensor module are received, load fluctuations are determined by comparing and analyzing the received measured values with a preset reference value, and the voltage and current values supplied to the ED processing unit are adjusted based on the determined load fluctuations. An electrodialysis system for managing wastewater and circulating cleaning water from a wet exhaust gas purification facility, further comprising a control unit that controls the control to the extent possible.
According to clause 3,
The enrichment tank is,
It is connected to the enrichment chamber of the ED module through a fourth circulation line, and the circulation process of flowing in and receiving concentrated water concentrated in the enrichment chamber of the ED module and supplying the received concentrated water to the enrichment chamber of the ED module is carried out at least twice. An electrodialysis system for managing wastewater and circulating cleaning water from a wet exhaust gas purification facility, which is characterized by cumulative concentration.

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