KR100479646B1 - Apparatus and Method for Environment-friendly Treatment of Industrial Wastewater Using the Combined Electrocoagulation and Magnetic Fluid Separation - Google Patents

Abstract

The present invention electrochemically combines contaminants in industrial wastewater with metal cations eluted from the anode to produce flocs, which are metallic hydroxides, and magnetizes the flocs to remove and remove them with magnets. The object is to provide a processing device that can be processed much faster and with higher quality.

According to the present invention, the pH of the wastewater introduced by adjusting the amount of supply of the magnetic fine powder 13 and the pH adjuster 12, the supply facility 2 and the pH adjuster 12 supplied from the supply facility (2) PH adjustment facility (1) for adjusting the temperature, electroaggregation unit (3) for electrocondensing contaminants in the wastewater passing through the pH adjustment facility (1) to form a floc, and magnetic rice supplied from the supply facility (2). The floc magnetization part 4 which stirs and mixes the powder 13 and the electrocoagulated water 14 discharged from the electroaggregation part 3 to form the magnetic flocs on the surface of the flocculated floc. And a magnetic floc separator 6 for collecting the magnetic floc 19 from the mixed slurry 18 discharged from the floc magnetization part 4 to separate the magnetic floc 19 and the treated water 20. An apparatus for treating wastewater is provided.

Description

Apparatus and Method for Environment-friendly Treatment of Industrial Wastewater Using the Combined Electrocoagulation and Magnetic Fluid Separation}

The present invention relates to an apparatus for treating industrial wastewater, and in particular, an electrocoagulation process for electrochemically agglomerating contaminants such as solid organics, dissolved organics, heavy metal ions, toxic and hardly decomposable substances present in industrial wastewater, and The present invention relates to an environmentally friendly treatment device for industrial wastewater, in which magnetic flux separation processes are combined in terms of floating particles in a fluid.

The present invention also relates to an environmentally friendly method for industrial wastewater that can purposely remove contaminants such as solid organics, dissolved organics, heavy metal ions, and toxic and hardly decomposable substances present in industrial wastewater.

In order to treat industrial wastewater, until now, acid or alkali is added to adjust pH, and chemical flocculation precipitation using inorganic and high molecular organic materials has been widely used.

In addition, in the case of a large amount of dissolved matter, flocculation and adsorption of suspended solids and some dissolved substances are agglomerated and removed by the flocculation sediment, followed by treatment by decomposing or adsorbing contaminants not precipitated through biological follow-up treatment using microorganisms such as activated sludge method. Doing. Such flocculation and sedimentation of wastewater prior to biological treatment has many advantages, such as removal of solids and dissolved organics, reduction of pollutant load during biological treatment, and removal of toxic and hardly degradable substances to increase the activity of microorganisms.

However, the flocculation requires a lot of flocculant and the chemicals used in the treatment are serious secondary pollution, especially aftertreatment such as sedimentation or flotation to remove flocculation flocs. It is quite uneconomical in terms of space. In addition, when the flocculated floc is removed through sedimentation and flotation, it is impossible to remove the fine floc of 10 μm or less. Thus, the removal rate of the suspended solids in the treated water is only about 80-90%.

Thus, instead of the chemical coagulation method described above, electrocoagulation based on the formation of a metal hydroxide floc by electrochemically combining metal cations eluted at the anode has attracted attention. However, flotation, filtration or sedimentation used in the case of chemical coagulation is applied to the removal of the electrocoagulated floc. As a result, the treatment time is long and the removal efficiency is limited. to be.

Accordingly, the present invention has been made in order to solve the problems of the prior art as described above, the electrochemical coupling of the metal cation eluted from the anode and the contaminants in the industrial wastewater to produce a floc which is a metallic hydroxide and then the floc It is an object of the present invention to provide an industrial wastewater treatment apparatus and a method of treating the pollutants in the industrial wastewater, which can be treated quickly and much better than the discharged water discharge regulation by magnetizing and removing them by magnets.

According to the present invention for achieving the above object, a supply facility for supplying the magnetic fine powder and the pH adjuster, and a pH adjustment facility for adjusting the pH of the wastewater introduced by adjusting the supply amount of the pH adjuster supplied from the supply facility; And magnetic agglomeration of the magnetic agglomerate to form a floc by electrocondensing contaminants in the wastewater that have passed through the pH adjusting facility, and by mixing and mixing the magnetic fine powder supplied from the supply facility and the electrocoagulated water discharged from the electrocoagulation part. Industry comprising a flocc magnetization section for forming a magnetic floc on the surface of the flocculated powder and a magnetic floc separating section for collecting the magnetic flocs from the mixed slurry discharged from the flocc magnetization section to separate the magnetic flocs and the treated water. An apparatus for treating wastewater is provided.

In addition, according to the present invention, in the treatment of the non-magnetic flocculation in the treatment of industrial wastewater combined with electro-aggregation and magnetic fluid separation, the first step of adjusting the pH of the industrial wastewater introduced; The second step of forming a floc by electrocondensing the contaminants in the wastewater discharged in the first step, and the magnetic powder is a magnetic floc on the surface of the floc by stirring and mixing the electrocoagulated water discharged in the second step and the magnetic fine powder There is provided a method for treating industrial wastewater comprising a third step of forming a and a fourth step of collecting the magnetic flocs from the mixed slurry discharged in the third step to separate the magnetic flocs and the treated water.

According to the present invention, there is also provided a method for treating an electrocoagulation flocks having magnetic characteristics in the treatment of industrial wastewater by combining electrocoagulation and magnetic fluid separation, comprising: a first step of adjusting the pH of the industrial wastewater introduced; And a second step of forming a magnetic floc by electrocondensing contaminants in the wastewater discharged in the first step, and collecting the magnetic flop from the mixed slurry discharged in the second step to separate the magnetic flop and the treated water. Provided is a method for treating industrial wastewater comprising three steps.

In the following, with reference to the accompanying drawings, a preferred embodiment of a treatment apparatus and a method for treating industrial wastewater combining the electro-aggregation and magnetic fluid separation according to the invention will be described in detail.

1 is a block diagram of an industrial wastewater treatment apparatus combining electrocoagulation and magnetic fluid separation in accordance with one embodiment of the present invention.

As shown in FIG. 1, the treatment apparatus for industrial wastewater of the present invention includes a pH adjusting facility 1 for adjusting the pH of the industrial wastewater 11 introduced through an inlet pipe, a pH adjusting agent 12, and magnetic fine powder 13. ), A pH adjuster for storing and supplying a) and a supply facility of magnetic fine powder (2). The pH adjusting facility 1 is connected to an electroaggregation unit 3 for electrocoagulating contaminants in wastewater to form flocs.

Then, the electroaggregation unit 3 is stirred and mixed with the electrocoagulation water 14 discharged from the electrocoagulation unit 3 and the magnetic fine powder 13 supplied from the supply facility 2. The floc magnetization section 4 is connected to form a magnetic floc on the surface of the flocculated floc. In addition, the electromagnetizing unit 3 collects the magnetic flocks 16 from the mixed slurry 15 discharged from the electroaggregating unit 3 to separate the magnetic flocks 16 and the treated water 17. The floc separating part 5 is connected, and the floc magnetization part 4 is connected to the first magnetic floc separating part 5. At this time, the magnetic plug 16 is collected by a plurality of magnets installed on the outer periphery of the transfer pipe.

In this way, the flocculation magnetization part 4 and the first magnetic floc separating part 5 are connected to the agglomeration part 3, respectively, when the flocculation flocks generated in the agglomeration part 3 have magnetic properties. In order to change that supply line. That is, when the electrocoagulation flocks generated by the electrocoagulation part 3 have magnetic properties, the flocculation part 4 is supplied to the floc magnetization part 4 via the first magnetic floc separating part 5, otherwise the direct floc magnetization part is performed. In order to be supplied to (4).

Then, the magnetic flux 19 is collected by the magnetization unit 4 by collecting the magnetic flux 19 by a plurality of magnets installed on the outer periphery of the transfer pipe from the mixed slurry 18 discharged from the flux magnetization unit 4. And the second magnetic floc separator 6 separating the final treated water 20 are connected. In addition, the magnetic powder is separated and recovered from the magnetic powder 13 after the pH adjustment, ultrasonic irradiation, and electrostatic treatment of the concentrated magnetic flux 19 sludge collected therein are carried out in the second magnetic flux separation unit 6. The recovery part 7 is connected.

The magnetic fine powder 13 of the present invention described above is used to form a floc by generating cohesive force such as van der Waals force between the floc in the electrocondensed water, and the iron making process in the magnetite and steel mills. Pulverized magnetite ore used in the sintering furnace, magnetite powder generated from the reduction furnace of hematite, steelmaking sludge discharged from the steelmaking process, dust of the electric furnace or the iron processing work is used to pulverize to 10 ㎛ or less.

In the present invention, it is preferable that the mass ratio of the floc and the magnetic fine powder in the electrocondensed water is mixed in the range of 1: 0.5 to 1: 4.

In the following, it will be described in detail the process relationship of the industrial wastewater treatment apparatus combining the electro-aggregation and magnetic fluid separation of the present invention configured as described above.

First, a case in which the electrocoagulation flocks generated in the electrocoagulation unit 3 are nonmagnetic with no magnetism will be described with reference to FIG. 2.

2 is a process diagram of a method for treating industrial wastewater combining electrocoagulation and magnetic fluid separation in accordance with the present invention when the electrocoagulation floc is nonmagnetic.

As shown in Figure 2, the industrial wastewater 11 introduced through the inlet pipe is adjusted to pH in the pH adjusting facility 1 is supplied to the electrocoagulation unit (3). Then, the contaminants in the industrial wastewater in the electrocoagulation unit 3 are electroaggregated in the form of a floc and the electrocoagulated water 14 thus formed flows into the floc magnetization unit 4 and is supplied from the supply facility 2. The magnetic powder 13 is attached to the surface of the floc while being stirred and mixed with the powder 13 so that the floc becomes magnetic and then flows into the second magnetic floc separator 6. Then, the magnetic flux 19 is collected and separated by magnetic force in the second magnetic flux separation unit 6, thereby removing almost all of the contaminants in the industrial wastewater.

In this way, the treated final water 20 is reused in the process or discharged to the river. Then, the magnetic flux 19 in the concentrated state collected in the second magnetic floc separating part 6 is treated in the magnetic powder recovery part 7 so that the floc solids are taken out and disposed of, and the recovered magnetic powder is floc magnetic. It is sent to the fire department 4 and reused.

Next, a case in which the electrocoagulation flocks generated by the electrocoagulation part 3 have magnetic properties will be described with reference to FIG. 3.

3 is a process diagram of a method for treating industrial wastewater combining electrocoagulation and magnetic fluid separation in accordance with the present invention when the electrocoagulation floc is magnetic.

As shown in FIG. 3, the industrial wastewater 11 introduced through the inlet pipe is adjusted to pH in the pH adjusting facility 1 and supplied to the electrocoagulation unit 3. Then, the contaminants in the industrial wastewater in the electrocoagulation unit 3 are electroaggregated in the form of a floc, at which time the electrocoagulation floc has magnetic properties. This magnetic is because the iron-based cations eluted from the anode in the electro-aggregation unit 3 and the contaminants in the industrial wastewater.

The mixed slurry 15 in which the magnetic flux having its own magnetic mixture is introduced is introduced into the first magnetic flux separation unit 5. Then, the magnetic flux 16 is collected and separated by magnetic force in the first magnetic flux separation unit 5 to remove contaminants in the industrial wastewater. The treated water 17 thus treated is reused in a process or discharged to a stream, and the floc solids are taken out and disposed of.

On the other hand, when the concentration of the nonmagnetic or fine magnetic flux remaining in the treated water 17 is higher than the discharged water quality standard, the magnetic fine powder 13 supplied from the treated water 17 and the supply facility 2 is removed. From the flocc magnetization section 4 and the mixed slurry 18 discharged from the floc magnetization section 4, by stirring and mixing, the magnetic powder 13 forms a magnetic floc on the surface of the nonmagnetic floc or the fine magnetic floc. A second magnetic floc separator 6 for collecting and separating the magnetic flocs 19 is optionally used.

In this case, when the floc magnetization part 4 and the second magnetic floc separation part 6 are selectively used, almost all contaminants in the industrial wastewater are removed. The final treated water 20 thus treated is reused in a process or discharged to a stream, and the magnetic powder 19 sludge collected in the second magnetic floc separator 6 is sludged in the magnetic fine powder recovery part 7. The floc solids, which are processed in the c), are taken out, disposed of and recovered, and the recovered magnetic fine powder is sent to the floc magnetization section 4 for reuse.

When the environmentally friendly treatment apparatus of the industrial wastewater of the present invention configured as described above is used, it can be treated with suspended solids concentration of 5 mg / l or less, turbidity of 5 NTU or less, and heavy metal removal rate of 99% or more.

In the following, the case of treating the treated wastewater at 25 m ³ per day I will be described as an example.

In this experimental example, an electrocoagulation device having a structure in which a direct current flows in a wastewater passing between an anode (+) tube and a cathode (-) tube in a tubular shape, the pH of which is charged through the compressed compression tube The adjusted dye wastewater flows into the cathode tube and then passes through the outer anode tube and is then discharged.

In this experiment, electroaggregation [electroaggregation part (4)] adopted a two-pass system in which two electrocoagulation tubes were connected in series. That is, a 3 "cathode tube x 2" cathode tube x a 1000 mm long tube was used, and iron (Fe) or aluminum (Al) was used as the material. In addition, the magnetic fluid separation device (the floc magnetization unit 4, the magnetic floc separation unit 5) is a magnetic fluid separation tower, a mixer of wastewater and magnetic fine powder, slurry (waste water + magnetic fine powder) supply pump, on / off It consisted of (On / Off) type magnet set.

The magnetic fluid separation tower was made of a glass tube with a diameter of 15 cm and a height of 100 cm, and the magnet set was installed in two stages on the outer wall circumference of the fluid separation tower with an electromagnet having a surface magnetic force of 1500 Gauss. The length of one step is 15 cm and the distance between each step is 20.5 cm. In the coagulation, the current was 20 A, the voltage was 36 V, and the flow rate was 36 l / min. The materials of the electrode were electro-aggregated by different materials such as Fe electrode and Al electrode, and the electrocoagulated waste water was separated from the magnetic fluid. The device was connected to allow for removal of aggregates, ie flocs.

At this time, the electrocondensed wastewater was subjected to a two-step magnetic fluid separation process. First, firstly, the electrocondensed wastewater itself was passed through a magnetic fluid separation tower. Subsequently, the concentration of the suspended matter remaining in the primary treated water was estimated based on the turbidity, and thus, the magnetic fine powder was introduced into the primary treated water so that the mass ratio of the magnetic fine powder / floating solid had a constant value. Then, the magnetic flocs were formed in the form of magnetic powder attached to the surface of the floc by stirring for about 5 minutes, and then reflowed into the lower part of the magnetic fluid separation tower to undergo secondary treatment. At this time, the tower liquid flow rate during the first and second treatment was adjusted in the range of 0.55-1.94 cm / s. As the magnetic fine powder, magnetite for reagents having an average particle diameter of 3.2 μm was used, and the mass ratio of the magnetic fine powder to the suspended solids was adjusted in the range of 1.09 to 2.82.

The results processed in the above manner are shown in FIGS. 4 and 5, respectively.

4 is a graph showing the relationship between the concentration and turbidity of suspended solids in the treated water in the magnetic fluid separation of the electrocoagulated water using the Fe electrode, Figure 5 is a magnetic fluid separation of the electrocoagulated water using the Al electrode The graph shows the relationship between the suspended solids concentration and turbidity in the treated water.

As shown in FIGS. 4 and 5, the difference in the electrodes was particularly evident in the primary treatment. In the case of using the Fe electrode of FIG. 4, the concentration of suspended solids in the electrocoagulated water was about 1100 ppm, and the turbidity was approximately 30 ppm and 40 NTU after the first treatment at about 400 NTU. About 90% was removed. It is possible to remove a large amount of contaminants only by the first treatment of magnetic fluid separation, and the amount of magnetic fine powder injected during the second treatment is reduced to within several%, thereby reducing the sludge generation. It means you can be satisfied at the same time.

On the other hand, in the case of the Al electrode of FIG. 5, the concentration and turbidity of the suspended solids in the electrocoagulated water were about 450 ppm and 100 NTU after the first treatment at 750 ppm and 230 NTU, respectively, and the suspended solids were about 40% and the turbidity. Showed a low removal rate of only 56%. This is due to the difference in susceptibility of the electroflocculated flocs, as mentioned earlier. In the secondary treatment of the magnetic fine powder, the concentration and turbidity of the suspended solids in the Fe electrode were lowered to about 2-4 ppm and 10 NTU, and in the case of the Al electrode, 5 ppm and 10 NTU. In the case of the secondary treatment, the difference in electrode was reduced in terms of the water quality of the secondary treated water.

As described in detail above, the apparatus for treating industrial wastewater combining the electroaggregation and magnetic fluid separation of the present invention is a metal eluted from the anode and pollutants such as solid organics, dissolved organics, heavy metal ions, toxic and hardly decomposable substances in industrial wastewater. The cations are electrochemically bonded to form flocs, which are metallic hydroxides, and the flocs are magnetized to remove them with magnets, which makes it possible to treat contaminants in industrial wastewater much faster than treated water discharge limits.

In addition, since the industrial wastewater treatment apparatus of the present invention does not use a separate chemical, secondary environmental pollution due to the use of chemicals can be minimized.

In addition, in the method of treating industrial wastewater of the present invention, when the flocculated floc is magnetic, the step of magnetizing the floc by inputting and stirring magnetic fine powder may omit the resulting sludge.

In the above description, the technical details of the treatment apparatus and treatment method for industrial wastewater combining the electrocoagulation and magnetic fluid separation of the present invention have been described together with the accompanying drawings, which are illustrative examples of the best embodiments of the present invention. It is not intended to limit. In addition, it is obvious that any person skilled in the art can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

1 is a block diagram of an industrial wastewater treatment apparatus combining electrocondensation and magnetic fluid separation in accordance with one embodiment of the present invention;

2 is a process chart of a method for treating industrial wastewater combining electrocoagulation and magnetic fluid separation in accordance with the present invention when the electrocoagulation floc is nonmagnetic;

3 is a process chart of a method for treating industrial wastewater combining electrocoagulation and magnetic fluid separation according to the present invention when the electrocoagulation floc is magnetic;

4 is a graph showing the relationship between the concentration of suspended solids in turbidity and turbidity in the magnetic fluid separation of electrocoagulated water using Fe electrodes,

5 is a graph showing the relationship between the concentration of suspended solids in turbidity and turbidity in magnetic fluid separation of electrocoagulated water using an Al electrode.

  ♠ Explanation of symbols on the main parts of the drawing ♠

1: pH adjusting facility 2: Supplying pH adjusting agent and magnetic fine powder

3: electrocoagulation part 4: floc magnetization part

5, 6: magnetic floc separation part 7: magnetic powder recovery part

11: industrial wastewater 12: pH adjuster

13: magnetic fine powder 14: electrocoagulated water

15, 18: mixed slurry 16, 19: magnetic flocs

17, 20: treated water

Claims (8)

In the apparatus for removing contaminants such as solid organics, dissolved organics, heavy metal ions, toxic and hardly decomposable substances present in industrial wastewater, A supply facility for supplying magnetic fine powder and a pH adjuster, a pH adjuster for adjusting the pH of the wastewater introduced by adjusting a supply amount of the pH adjuster supplied from the supply facility, and contaminants in the wastewater passing through the pH adjuster The magnetic floccules are formed on the surface of the floc with the magnetic fine powder being agglomerated by stirring and mixing the magnetic agglomerate forming the floc by electrocoagulating the magnetic fine powder supplied from the supply facility and the electrocoagulated water discharged from the electrocoagulated part. And a magnetic flux separation unit for collecting the magnetic flocs from the mixed slurry discharged from the flocc magnetization unit to separate the magnetic flocs and the treated water. The magnetic powder recovery unit of claim 1, further comprising a magnetic fine powder recovery unit for separating and recovering the magnetic fine powder after pH adjustment, ultrasonic irradiation, and electrostatic treatment of the magnetic flux sludge collected in the magnetic floc separation unit. Treatment apparatus for industrial wastewater. The method of claim 1, wherein the magnetic flocculation unit and the magnetic flux between the magnetic flocculation unit is characterized in that the magnetic flux is separated from the mixing slurry discharged from the electroaggregation unit to separate the magnetic flocs and the treated water is installed, characterized in that Treatment equipment for industrial wastewater. According to any one of claims 1 to 3, wherein the magnetic powder is characterized in that the magnetite, magnetite ore, magnetic powder, steelmaking sludge, dust of the electric furnace dust or iron processing operation is used to grind to 10 ㎛ or less. Treatment apparatus for industrial wastewater. In a method for removing contaminants such as solid organics, dissolved organics, heavy metal ions, toxic and hardly decomposable substances present in industrial wastewater, A first step of adjusting the pH of the introduced industrial wastewater, a second step of electrocoagulating contaminants in the wastewater discharged in the first step to form a floc, and an electric coagulation water discharged from the second step A third step of stirring and mixing the fine powder to form a magnetic floc on the surface of the floc, and a fourth step of collecting the magnetic floc from the mixing slurry discharged in the third step to separate the magnetic floc and the treated water. Industrial wastewater treatment method comprising a. In a method for removing contaminants such as solid organics, dissolved organics, heavy metal ions, toxic and hardly decomposable substances present in industrial wastewater, A first step of adjusting the pH of the industrial wastewater introduced therein; a second step of electrocondensing the contaminants in the wastewater discharged in the first step to form a magnetic flop having its own magnetism; and the discharge in the second step And collecting a magnetic flop from the mixed slurry to separate the magnetic flop and the treated water. The method of claim 6, wherein the magnetic powder is agitated and mixed with the treated water treated in the third step to collect magnetic flux from the mixed slurry formed by attaching the magnetic powder to the residual floc to separate the magnetic floc and the final treated water. Industrial wastewater treatment method comprising a further. The method for treating industrial wastewater according to claim 5 or 7, further comprising separating and recovering the magnetic fine powder contained in the magnetic floc by pH adjustment, ultrasonic irradiation, and electrostatic treatment.