KR20000074638A - Method and Apparatus of denitrification for the purification of wastewater by using reduction of electric energy - Google Patents

Abstract

PURPOSE: A biological nitrification system is provided, which is characterized in that the system can remove efficiently organic matter and nutrients such as nitrogen and phosphorous by using the reducing power of electric energy. CONSTITUTION: A biological nitrification system using the reducing power of electric energy consists of the following parts: a reactor divided into an anode reactor added with potassium chloride and a cathode reactor added with microbe growth media and CO2, which is used alternatively a hydrogen-generator; ion exchange membranes; an electric power part; a cathode and an anode composed of non-woven carbon; an oxidation-reduction measuring part; a standard electrode; and an operating electrode.

Description

Biological denitrification method and apparatus for sewage and wastewater using reducing power of electric energy {Method and Apparatus of denitrification for the purification of wastewater by using reduction of electric energy}

The present invention relates to a denitrification apparatus and method for converting various nitrogen compounds dissolved in wastewater into inert nitrogen gas and radiating them to the atmosphere. Particularly, organic matter and nitrogen in wastewater and wastewater are used by using electrical energy as reducing power. The present invention relates to a biological denitrification method of sewage and wastewater using a reducing power of electrical energy to remove nutrients, and the like.

In recent years, as lakes, reservoirs, and rivers, which have been used as water sources, have deteriorated in water quality due to eutrophication, nitrogen and phosphorus, which are the causes of eutrophication, have to be removed during sewage treatment. Since only the sludge process, which is a secondary treatment, is operated, the nitrogen and phosphorus in question are discharged to the rivers or flowing into lakes and reservoirs as they are almost untreated.

Therefore, not only agricultural wastewater, but also human waste, food waste discharged from the kitchen to sewage, concentrated inorganic phosphate compounds used in various household detergents, etc., are generated in the wastewater to not only eutrophicate the environmental waters with phosphorus and nitrogen. But there was a problem that promotes the growth of aquatic plants.

In addition, when the nitrogen is released into the environment mainly composed of organic nitrogen and ammonia nitrogen in the waste water, the organic nitrogen and ammonia nitrogen is converted to nitrite in nature, and then become nitrate, which requires a large oxygen demand. There was this.

Therefore, the removal principle of treating nitrogen and phosphorus simultaneously by a biological method will be described to solve such a problem. Biological nitrogen and phosphorus removal principles are independent of each other, and how to properly apply them in the treatment process is a problem.

First, let's look at the reaction of phosphorus. The removal of phosphorus biologically uses the release and intake of phosphorus in the anaerobic and aerobic processes, and the suspended solids are removed from the initial settling tank and the microbial body weight returned by the excess sludge conveying pump in the anaerobic state from the effluent flowing into the anaerobic reactor. As a result, organic matter is ingested and stored, and phosphorus release begins, and phosphorus is removed by accumulating polyphosphoric acid in the body of the microorganism together with the growth of the microorganism in the aerobic state of the subsequent process. That is, ortho-P is released from the poly-P stored in the cell in the anaerobic process, and the polyphosphate accumulated in the cell is a linear bond of the regular phosphoric acid, and the ring of the bond becomes an energy source. . In addition, PO ₄ ⁺ by hydrolysis of the polyphosphate is Glass is released into the liquid, is referred to as the phenomenon of being released (phosphorus release).

At this time, the extracellular organic matter is transferred into the cell by energy, which is called active transport, and the absorbed organic matter is stored as PHB (poly-B-hydroxy buthylate) and then stored in the cell when it is aerobic. PHB is broken down to synthesize ATP, and this energy is absorbed and stored as polyphosphoric acid in cells. At this time, the ingestion of excess phosphoric acid from the solution to synthesize the inorganic phosphoric acid is the excessive intake (lusuary uptake) of phosphorus. Phosphorus biological elimination is achieved by releasing in the form of sludge the microorganisms that ingested excess phosphorus in aerobic state.

Next, let's look at the reaction of nitrogen.

Generally, the nitrogen components in sewage and wastewater are classified into organic nitrogen (organic-N), ammonia nitrogen (NH ₄ -N), nitrite nitrogen (NO ₂ -N) and nitrate nitrogen (NO ₃ -N). do. The process of removing these nitrogen components from wastewater and wastewater includes a nitrification process in which ammonia and organic nitrogen in the influent are converted to nitrates under certain conditions, and the nitrates nitrated by the nitrification process are subjected to nitrogen by biological reduction. It is composed of a denitrification process to convert to gas, which will be described in more detail as follows.

The nitrification process converts ammonium (NH ₄ ⁺ ) into nitrite (NO ₂ ⁻ ) and back to nitrate (NO ₃ ⁻ ) by biological oxidation. In the aerobic state rich in organic matter, organic matter is converted and appears wherever ammonium is released.

In the first stage of nitrification, ammonium is oxidized to nitrite, and the energy obtained by the microbial oxidation of ammonium makes it possible to fix carbon dioxide on microorganisms and use it for metabolism. On the other hand, the oxidation of nitrite to nitrate also takes place in the same way.

As such, two stages of metabolism are caused by different kinds of bacteria, the ammonium oxidation is carried out by microorganisms belonging to the family Nitrosomonas,

NH ₄ ⁺ + 1.5O ₂ + 2HCO ₃ ?? ^{_{NO 2 - + 2H 2 CO 3}} + H 2 O

Oxidation of nitrites is carried out by microorganisms belonging to the family Nitrobacter.

NO ₂ ^- + 0.5O ₂ ?? NO ₃ ^-

Carbon dioxide is used as the carbon source of both microorganisms, and their energy is obtained from the oxidation of inorganic nitrogen compounds (chemolithoautotrophy), while other microorganisms in activated sludge use energy from the oxidation of organic carbon compounds and use these components as carbon sources. (heterotrophy).

As described above, the organic material is decomposed and nitrified at the same time using an open pure oxygen activated sludge treatment process treated by microorganisms in an aerobic state through a denitrification process. At this time, the nitrate introduced by nitrification in the nitrification process contains a large amount of nitrogenous organic matter and ammonia, which is not decomposable but also does not have a high load of organic matter. Phosphorylation takes place and requires anaerobic denitrification to remove it.

In addition, the denitrification process is induced by a hydrogen donor to convert the nitrate obtained in the nitrification process into nitrogen gas by biological reduction. In this case, the nitrate serves as a terminal hydrogen acceptor, the denitrification microorganism is reduced to nitrite, an intermediate product of nitrate, and finally releases nitrogen gas (N2).

_{^{NO 3 - → NO 2 - →}} NO 2 → NO → N 2

On the other hand, the denitrification process requires an organic carbon source (organic carbon source) to supply carbon for biological synthesis.

As described above, biological treatment processes (hereinafter, referred to as advanced treatment processes) that simultaneously treat nitrogen and phosphorus removal by appropriately mixing them include A ² / O processes, Bandenpho processes, and the University of Cape Town. ) Process, VIP (Virginia Initiative Plant) process, etc. If this is described in more detail as follows.

In the A ² / O method, as shown in Figure 1a, the sedimentation treatment in the primary sedimentation tank 100, the inflow water, such as sewage and waste water from which the suspended solids are removed anaerobic reaction tank 200, anoxic reaction tank (300) ), And by discharge through the aerobic reactor 400, the secondary precipitation tank 500, the residence time of the oxygen-free reaction tank 300 takes about 1 hour. In the anoxic reactor 300, there is no dissolved oxygen, but chemically bonded oxygen in the form of nitrate and nitrite is introduced from the aerobic reactor into the nitrified MLSS (Mixed Liquor Suspended Solids: suspension solids mixed solution) to denitrify nitrogen nitrate. By making it so that the phosphorus discharged from the anaerobic reactor 200 is excessively absorbed in the aerobic reactor (400) and in the anaerobic reactor 200 is conveyed sludge of 0.5 times the inflow water from the secondary settling tank 500 Allow inflow.

In addition, the modified Badenpho method, as shown in Figure 1b, the anaerobic reaction tank 200, the first inlet water, such as waste water and wastewater passed through the first settling tank 100 to remove phosphorus, nitrogen and carbon 1 to be treated by an oxygen-free reactor 300, the first aerobic reactor 400, the second anoxic reactor 500, the second aerobic reactor 600 and the second settling tank 700 to discharge in series, at this time, In the first aerobic reactor 400, four times the amount of inflow water is returned, and in the second settling tank 700, the return sludge 0.5 times the return sludge is returned to the anaerobic reactor 200.

In addition, the UTC (University of Cape Town) method, as shown in Figure 1c, through the first sedimentation tank 100, the inlet water such as waste water, anaerobic reactor 200, anoxic reactor 300, aerobic reactor (400), to be discharged by processing in a series through the second settling tank 500, in this case, the anoxic reaction tank 300 is returned to the anaerobic reactor 200, 1-2 times the amount of inflow water, the aerobic reactor (400) In the 1 to 2 times the amount of inlet water is returned to the oxygen-free reaction tank 300, and the second settling tank 500 is returned to the anaerobic tank 200 of the return sludge of 0.5 times the amount of inlet water.

In addition, the VIP (Virginia Initiative Plant) method, as shown in Figure 1d, through the first sedimentation tank 100, inlet water such as waste water anaerobic reactor 200, anoxic reactor 300, aerobic reactor ( 400) and discharged after treatment through the second settling tank 500, in which the oxygen-free reaction tank 300 returns 1-2 times the amount of inflow to the anaerobic reaction tank 200, the aerobic reaction tank 400 And the second settling tank 500 conveys the return sludge 1 times the amount of inflow water to the anoxic reactor 300.

However, as described above, in the conventional method for removing nutrients in sewage and wastewater treatment, the microorganisms in the anaerobic denitrification process generate energy through nitrate breathing to reduce nitrate to nitrogen, thereby increasing the amount of nitrate in proportion to the concentration of nitrate to be removed. It is necessary to supply the organic material as the energy source, which causes a problem of causing secondary pollution by the additionally supplied large amount of organic material.

In addition, the conventional method for removing nutrients in sewage and wastewater treatment requires forced aeration of nitrogen into the reactor to remove dissolved oxygen in order to maintain an anaerobic environment requiring a large amount of organic matter. There was a difficult problem to meet.

In addition, the nutrient removal method in the conventional sewage and wastewater treatment has a problem that a separate process for removing organic matter is required because the organic matter is not completely oxidized in an anaerobic environment.

An object of the present invention is to solve the conventional problems as described above, in particular, organic materials using electrical energy for the biological reduction of the electron acceptor using oxides such as nitrates, sulfates, carbonates in the respiration metabolism of microorganisms in an anaerobic environment. It provides a method and apparatus for biological denitrification of sewage and wastewater by using the reducing power of electric energy to produce the organic acid by fixing carbon dioxide, as well as using the reducing power of the electric energy instead of the biochemical reducing power generated when oxidized. have.

Another object of the present invention is to maintain a low oxidation-reduction potential in the reactor to form a very low anaerobic environment electrochemically by using a reducing power of the electric energy to easily create an anaerobic environment without a process for aeration of nitrogen Providing a method and apparatus for biological denitrification of waste water.

It is still another object of the present invention to provide a biological denitrification method for sewage and wastewater using a reducing power of electric energy and a device for reducing the system by making the denitrification reaction overall.

In order to achieve the above object, the biological denitrification method and apparatus of sewage and wastewater using the reducing power of the electric energy of the present invention are carried out in the denitrification process without additional organic matters (step aeration, rotary disc reactor, anaerobic reactor, etc.). The wastewater introduced from) is used as an electrolyte to supply a trace amount of organic matter as a carbon source and electric energy as a reducing power for respiration of microorganisms.

1 is a schematic diagram illustrating a general biological denitrification and dephosphorization process.

Figure 1a shows an A ² / O process,

Figure 1b shows a Badenpo process,

Figure 1c shows a UCT process,

1D shows the VIP process.

Figure 2 is a schematic diagram showing a biological denitrification process of the present invention.

Figure 3 is a perspective view showing the configuration of an embodiment of the present invention.

4 is a graph comparing the removal amount of nitrates.

5 is a graph comparing nitrite concentrations.

6 is a graph comparing changes in chemical oxygen demand.

7 is a graph comparing the increase of the cells.

8 is a graph comparing the consumption of carbon dioxide of the present invention.

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

10: reactor 11: cathode reactor

12: anode reaction tank 20: cation exchange membrane

30: power supply 31: negative electrode

32: anode 40: redox measuring unit

41: reference electrode 42: working electrode

Hereinafter, an embodiment according to the technical idea of the biological denitrification method of the sewage and wastewater using the reducing power of the electric energy of the present invention configured as described above and the apparatus will be described in detail. Figure 2 is a schematic diagram showing a biological denitrification process of the present invention, Figure 3 is a perspective view showing the configuration of an embodiment of the present invention.

The biological denitrification method of sewage and wastewater using the reducing power of the electric energy of the present invention forms a potential difference by supplying power to both reaction tanks separated by an optional ion exchange membrane interposed at a predetermined position so that the closed reaction tank is separated into a predetermined oxidation-reduction. Forming the potential, using the introduced wastewater as an electrolyte to supply a small amount of organic matter as a carbon source, electrical energy to the reducing power required for the respiration of denitrification microorganisms, which will be described in more detail as follows.

By selectively supplying hydrogen instead of electrical energy to the reactor as a separate hydrogen supply means, it supplies the reducing power for respiration of microorganisms.

The redox measuring means for measuring the redox potential is provided in the reaction tank in which the electrons are generated.

On the other hand, the biological denitrification apparatus of the waste water using the reducing power of the electrical energy of the present invention by installing a cation exchange membrane 20 at a predetermined position of the reaction tank 10 to be separated into the negative electrode reactor 11 and the positive electrode reactor 12 to the negative electrode The reactor 11 is provided with a redox measuring unit 40 and a negative electrode 31, the positive electrode 12 is composed of a positive electrode 32, which will be described in more detail as follows.

The positive electrode 32 and the negative electrode 31 are formed of a carbon nonwoven fabric.

In addition, the positive electrode 32 and the negative electrode 31 are connected to the power supply 33 so that a potential difference can be formed.

In addition, the cathode reactor 11 is a microbial growth medium, the cathode reactor 12 is used potassium chloride.

In addition, the positive electrode 32 is formed in a concave-convex shape so as to maximize the electron transfer efficiency of the denitrifying microorganism by widening the surface area.

In addition, methane production bacteria, monoacetic acid production bacteria, propionic acid fermentation bacteria and butyric acid fermentation bacteria are used in the cathode reactor 11 to biosynthesize carbon dioxide as a carbon source.

In addition, the redox measuring unit 40 is provided with a reference electrode 41 and a working electrode 42 to detect the redox potential.

In addition, a carbon dioxide supply unit 50 for supplying carbon dioxide stored in the storage tank 51 to the cathode reaction tank 11 by the tubular pump 52 to aeration in the culture medium of the cathode reaction tank 11 is provided.

The following is more specifically described through the following embodiments of the present invention configured as described above. These examples are intended to illustrate the present invention, and it is obvious to those skilled in the art that the scope of the present invention is not limited to these examples.

Example 1: Denitrification System Configuration and Operation

As shown in FIG. 3, the present invention for fixing denitrification and carbon dioxide includes a rubber stopper so that an anaerobic environment is maintained in a pair of cathode reactors 11 and anode reactors 12 each having a capacity of 1.5 liters. 13) to prevent the electrolyte (100 mmol salt solution) stored in the anode reaction tank 12 and the cathode electrolyte (microbial growth medium) stored in the cathode reaction tank (12) from being mixed, and cation or hydrogen ions are prevented from mixing. Is separated into a cation exchange membrane 20 made of nylon (Nafion, manufactured by Electrosynthesis, Inc., USA) having an area of 30 square centimeters so as to be selectively moved to the cathode reactor 11 in. Therefore, the oxidation-reduction potential of the entire cathode reaction tank 11 can be maintained at a negative value by the cation exchange membrane 20, thereby maintaining the anaerobic and low oxidation-reduction potential, and thus, the cathode reaction tank ( Denitrification is made in 11), and the reaction efficiency can be improved.

In addition, using a carbon nonwoven fabric of 0.47 m 2 per gram so that reducing power is supplied to the microorganisms supplied to the negative electrode reactor 11, the negative electrode 31 of the carbon nonwoven fabric having a surface area of 1.9 m 2 is used in the cathode reactor 11. The reactor 12 is provided with positive electrodes 32 of carbon nonwoven fabric having a surface area of 2.8 square meters, respectively. The carbon nonwoven fabric electrode () is a nonwoven crimped material made of graphite fibers and has a large surface area and high porosity, and has a high contact efficiency with microorganisms. In general, the carbon nonwoven fabric electrode has a high surface contact efficiency compared to a carrier used. Due to the strong tendency of electrons to move to the species or microorganism (proportional to the voltage applied) on the surface of the carbon nonwoven fabric electrode of the cathode, the electron transfer mediator is reduced and the reduced electron transfer mediator is oxidized in contact with the microorganism to metabolize the microorganism. By transmitting electrons to a substance involved in the electrons of the electrode is used for microbial metabolism. At this time, the positive electrode 32 is fixed to the rubber stopper 13 by using a high-strength glass tube of 0.8 cm in diameter and between the positive electrode 32 and the power supply 33 to connect using a 0.5 mm diameter platinum wire. do.

In addition, the negative electrode reactor 11 is provided with a reference electrode 41 consisting of a silver electrode with a silver chloride attached to the electrolyte and a 4-mole of potassium chloride solution to measure the oxidation-reduction electrode, and a platinum plate of 1 square centimeter The redox measuring unit 40 composed of the working electrodes 42 is provided.

In addition, in order to continuously supply carbon dioxide, the carbon dioxide storage tank 51 was connected to the cathode reactor 11 using a plastic pipe, and a tubular pump 52 was used to connect 10 milliliters of carbon dioxide per minute to the cathode reactor ( 11) was aerated in the culture solution. To control the oxidation-reduction potential and to create an anaerobic environment, the cathode reactor 11 is a gas purifying oven filled with pure copper beads (about 2-3 mm in diameter) heated to 370 ° C. before microbial inoculation (a trace oxygen contaminated with gas). Is removed to remove contaminated oxygen with nitrogen for 15 minutes, but this is to remove oxygen dissolved in the reaction solution about 5-10 before setting up the initial system. It is possible to convert the oxidation-reduction potential to anaerobic level without nitrogen aeration.

Example 2: Denitrification Efficiency Comparison

All experiments maintained the pressure and volume of hydrogen / carbon dioxide gas (8: 2) and nitrogen / carbon dioxide gas (8: 2) under a complete anaerobic condition of 30 ° C. at a pressure of 2 atmospheres and a volume of 3 times the culture. In addition, the pressure of the electrochemical reactor was maintained at atmospheric pressure, but instead of supplying carbon dioxide continuously to replace the high pressure, all the culture medium (carbonate buffer medium) used in the test was dissolved by aeration with nitrogen to remove oxygen before injecting microorganisms. The oxygen was sufficiently removed to create conditions under which anaerobic microorganisms could settle immediately. In addition, 5% (V / V) of the reaction solution of the anaerobic digestion tank of Jungnang sewage terminal treatment plant is inoculated into a sterile carbonate buffer medium to which yeast extract (1 gram per liter) is added, and nitrogen, hydrogen and electric energy are inoculated. The denitrification efficiency when used is as follows.

As shown in FIG. 4, the denitrification efficiency when the electric energy and the electron transfer medium were used was increased by about four times or more as compared to the control group using the nitrogen / carbon dioxide gas (8: 2), and the hydrogen / carbon dioxide gas. It is about 2-3 times higher than when (8: 2) is used as reducing power, which is explained in more detail as follows.

The control group that obtains energy using nitrogen is nitrate by reducing the organic matter contained in the sludge (addition of 5% by volume) in the anaerobic digestion tank without reducing supply of microorganisms to reduce nitrate in anaerobic environment. Removal efficiency of nitrite and nitrite was relatively low, whereas removal efficiency of nitrate and nitrite was greatly increased when hydrogen or electric energy was used as reducing power. Nitrate is removed by the action of a group of anaerobic bacteria contained in the sludge of an anaerobic digester with the ability to reduce nitrate by reducing hydrogen.

In addition, bacteria that use hydrogen as a reducing power have a hydrogenase, which oxidizes hydrogen to electrons and protons and uses it for metabolism. After completion of the reaction, the bacteria grown in the negative electrode reactor (11) were separated and qualitatively confirmed the activity of the hydrogen oxidase, and the activity of this enzyme was confirmed in various bacteria. In other words, many species of anaerobic microorganisms, especially nitrates, sulfates, or carbonate breaths, can use carbon as a reducing power to fix carbon dioxide or produce living energy. Therefore, the denitrification efficiency of microorganisms can be increased compared to nitrogen. Will be.

In other words, hydrogen is a simple molecule composed of electrons and protons, and in metabolism of microorganisms, it is oxidized to electrons and protons and used for microbial metabolism through an electron transport system, thereby enabling electrical energy to be used as a reducing power in microbial metabolism. In other words, when electrons are transferred to organisms through chemicals (electron transfer mediators), they have the same characteristics as electrons used in the electron metabolism of organisms, which makes them a useful reducing power to replace hydrogen or organic matter. Since the reduction reaction occurs selectively only in the negative electrode, when the electrochemical device is introduced into the process, the size of the positive electrode reaction tank 12 can be reduced (about 1/10 of the size of the negative electrode reaction tank). Both electrodes 31 and 32 can use carbon non-woven fabrics to maximize the electron transfer efficiency to microorganisms by making the surface uneven to make the surface area as wide as possible. have.

In addition, in the case of bacteria using electrical energy as a reducing power, it was confirmed that a large amount of bacteria adhere to and grow on the negative electrode 31 of the carbon nonwoven fabric. The reduced electron transfer mediator on the surface of the negative electrode 31 is reduced to provide electrons to the microorganism, and the microorganism reduces the nitrate using electrons derived from the electrode instead of hydrogen and produces energy for growth.

In other words, the reduction process of nitrate is carried out through relatively complicated metabolic pathways in the order of nitrate and nitrite in ionic state, nitrogen dioxide in gaseous state, nitric oxide, and nitrogen. Because of this characteristic, a large amount of reducing power is required. To quantitatively reduce 2 moles of nitrate to 1 mole of nitrogen, 14 moles of electrons and protons are required. This corresponds to about 7 moles of hydrogen and 7 moles of reducing power (NADH) that can be produced when 1 mole of glucose is oxidized. As such, when the nitrate is reduced, a large amount of organic matter (reducing power) is required, and in the case of a control group that does not supply additional reducing power, the denitrification efficiency must be 5 days after supplying hydrogen or electric energy as reducing power. Will be similar. In other words, when energy is obtained from nitrogen, a long reaction time is required when a suitable reducing power is not supplied. For this purpose, a suitable organic material such as methanol or acetate is used as a reducing power for denitrification at the wastewater treatment plant. Not only can the problem occur, but the reaction rate, which is the most important factor in the continuous process, is problematic in the field application.

In addition, as a result of measuring the nitrite concentration of the sample extracted to determine the effect of the electrical energy on the bioelectrochemical denitrification effect, as shown in Figure 5, when the electrical energy is supplied to the reducing power, the nitrite is not at all Although not detected, when a control group and hydrogen were used as reducing power, very small amounts of nitrite were detected in the reaction solution at the very beginning of the reaction, and nitrite was not detected as the reaction time elapsed. In this case, since the nitrite is reduced to nitrogen monoxide when the reducing power is sufficiently supplied from the microbial metabolism, and then reduced to nitrogen, measuring the concentration of the nitrite becomes an index for predicting the efficiency of the reaction in the denitrification process. Specifically, it is as follows.

When the electric energy is used as reducing power, nitrite is not produced, so that sufficient reducing power is supplied to the entire process of nitrate reduction metabolism, indicating that the nitrate is reduced to the gas phase and removed from the reactor in the stepwise reaction. That is, in the process of nitrate (NO ₃ ⁻ ) → nitrite (NO ₂ ⁻ ) → nitrogen dioxide (NO ₂ ) → nitrogen oxide (NO) → nitrogen (N ₂ ) The amount generated is a measure of the reaction efficiency. This is because the rate of the overall reaction can be determined by the activity of the enzymes acting in each stage of the multistage reduction reaction and the activity of the coenzymes that provide the reducing power to each stage. If not fed, it indicates that the reaction cannot be balanced. That is, the bottleneck, as described above, may occur when the reduction reaction by the enzyme involved in each step in the multi-step reaction, that is, when the electrons are not supplied smoothly or the function of the enzyme is reduced, This results in the accumulation of nitrates or nitrites rather than reduction. As such, the supply of additional reducing power, such as hydrogen or electrical energy, can affect the denitrification efficiency and the reaction rate and thus can be used to develop and apply the denitrification process to the field.

Example 3: Carbon Dioxide Fixation

Since denitrification bacteria are generally thermodynamically capable of producing the most free energy, sulfate-reducing bacteria, methane-producing bacteria, and anaerobic fermenting bacteria, which are unfavorable for growth in denitrification reactors, are naturally culled, reducing their investigation and relatively nitrate reduction. Bacteria increase and denitrification efficiency increases. Therefore, free energy is produced during the reduction of nitrates by the microorganisms involved in the denitrification using hydrogen or electric energy as reducing power, so that the microorganisms having the carbon dioxide fixing ability can biosynthesize the polymer required for the cell by using carbon dioxide as the carbon source. Will be. In other words, microorganisms produce energy in order to grow and perform active metabolism in the process of producing energy, so that the increase in cell mass is essential in the denitrification process, and the metabolic efficiency is also proportional to the increase rate of the cell mass. The explanation is as follows.

The amount of change in the chemical oxygen demand (COD) when the electrical energy and the electron transfer medium are supplied to the denitrification process is metabolized for biosynthesis of microorganisms as well as electrical energy as shown in FIG. 6. The result shows that it can be converted into energy. This shows that electrical energy can be converted into energy for biosynthesis of microorganisms during denitrification, such as hydrogen, because the electrons of electricity have the same thermodynamic function as the electrons produced when hydrogen is oxidized.

In addition, the amount of carbon dioxide consumed by microorganisms can be biosynthesized in the case of anaerobic microorganisms using hydrogen as reducing power. can see. Therefore, carbon dioxide is fixed in the electrochemical denitrification process even by the electric energy identified as a reducing power capable of replacing hydrogen.

Therefore, as a result of confirming the increase in the amount of organic matter and the cell mass measured by the chemical oxygen demand in the reactor during the denitrification reaction, the concentration of the organic matter measured by the chemical oxygen demand when using nitrogen and carbon dioxide as shown in Figs. Was not increased, but the cell mass was somewhat increased. When hydrogen and carbon dioxide were used, the concentration of organic matter measured by chemical oxygen demand was increased, but the increase in cell mass was not significantly different.

This is because hydrogen acts as a reducing force in the energy metabolism of microorganisms instead of organic matter in the culture medium, whereas when nitrogen is used, organic matter present in the reaction tank is used as reducing power and carbon source. In addition, when the electrical energy is used as the reducing power, both the concentration and the cell mass of the organic matter measured by the chemical oxygen demand are increased. This is because the reducing power of the electrical energy is used for energy metabolism of microorganisms, and the organic material and carbon dioxide in the culture medium are used as carbon sources. It shows the fact that it was used for the synthesis of cell mass.

In other words, many types of anaerobic microorganisms can produce free energy by using chemical energy as reducing power and synthesize biopolymers using carbon dioxide or simple carbon compounds as carbon sources (Brock Microbiology, 1998, Prentice Hall Press). ). Therefore, when compared with the control group added with nitrogen, when supplying electricity or hydrogen as an energy source and supplying carbon dioxide as an additional carbon source, the cell mass or the amount of organic matter in the reactor can be increased.

Example 4 Oxidation-Reduction Potential Measurement

Although the measuring principle of the redox measuring electrode is very similar to the measuring principle of pH, if platinum is used instead of the glass electrode of the pH electrode and the concentration of the oxidizing material is high on the platinum surface, the electron does not actually move through the platinum, but the electron is oxidative. The oxidation-reduction potential is positive due to the tendency of the platinum electrode to move to the material and the tendency of electrons to move to the silver electrode from the chlorine anion of silver chloride fixed on the surface of the silver electrode of the reference electrode 41. Becomes

As such, the difference between the oxidation tendency of the platinum electrode and the reducing tendency of the cathode electrode is called an oxidation-reduction potential. If the concentration of the reducing material is high on the platinum surface, the tendency of electrons to move from the reducing material to the platinum becomes stronger. The electrons of the electrode tend to move to silver cations, so the redox potential becomes negative. Therefore, as the oxidation-reduction potential increases to a negative value, the microorganisms or chemical species in the cathode reaction tank receive electrons from the anode and the reducibility increases, and the oxidation-reduction electrode of the cathode reaction tank becomes a positive value. When changed, microorganisms are greatly reduced or biochemical reactions are abnormal.

This measuring electrode is to be calculated by adding a voltage of +0.19 volts after measuring the voltage difference between the silver electrode and the platinum electrode 42 after immersing in the culture medium with the silver electrode and the working electrode 42 of the reference electrode 41, The efficiency of the reaction can be predicted and the progress of the reaction can be predicted. The redox potential of the denitrification reactor is a very important factor in maintaining the anaerobic respiration of microorganisms, and the maintenance of the low redox potential below zero volts increases the efficiency of denitrification through nitrate breathing. That is, the oxidation-reduction potential in the reactor, as shown in Figure 8, the metabolism of the microorganisms as well as the oxidation-reduction potential of the growth environment of anaerobic microorganisms are advantageous to the growth and metabolism of the microorganisms by the reducing power of the electrical energy By functioning to maintain zero volts without using additional reducing agent, which will be described in more detail as follows.

Denitrification bacteria with genes that produce enzymes involved in denitrification are generally oxidative-reduced because their expression is inhibited by oxygen and most anaerobic bacteria lack enzymes that degrade oxygen radicals that occur during respiratory metabolism. When grown in an environment with high potential or oxygen, oxygen radicals generated can cause a loss of function. Accordingly, the redox potential of 0 volts or less is rich in reducing materials instead of oxygen or oxidizing materials in the denitrification reactor, which is particularly advantageous for the growth of microorganisms requiring an anaerobic environment for the reduction reaction of nitrates.

In addition, the mobility of electrons through the electron transfer enzyme is determined by the oxidation-reduction potential of the electron transfer enzymes, and electrons having an electromotive force of -0.32 volts starting from NADH corresponding to the cathode of the electron transfer system in living organisms are continuously It moves through the delivery system and captures protons scattered within the cell and pushes them out of the cell. This action is called positive movement, and the driving force of the generated protons becomes free energy for living organisms. Therefore, coenzymes involved in electron transfer in living organisms have unique redox potentials, so they receive electrons from relatively low oxidation-reduction potentials and transfer electrons to higher coenzymes. This pushes the proton out of the cell.

For example, methane-producing bacteria require low oxidation-reduction potentials below -0.3 volts, so they cannot grow in environments above -0.3 volts, whereas nitrate-reducing bacteria can reduce oxidation-reduction below zero volts. The potential is enough. For example, NADH has an oxidation-reduction potential of -0.32 volts, so when oxygen is rich, electrons are partially oxidized by oxygen, which is why it is anaerobic that the extracellular environment maintains a low oxidation-reduction potential. It is essential for metabolism. In this case, the electrochemical reduction reaction occurring on the surface of the negative electrode has a direct effect on the reduction potential of chemicals having various electrochemical activities in the reactor, so that oxidation or reduction of anaerobic microorganisms may be improved by simply supplying electrical energy. .

As described above, the biological denitrification method of the sewage and wastewater using the reducing power of the electric energy of the present invention, and the device not only make it possible to use the reducing power of electrical energy for the biological reduction of microorganisms, so as to produce organic acids by fixing carbon dioxide. By doing so, an environmentally friendly wastewater treatment system can be implemented.

In addition, the biological denitrification method of the sewage and wastewater using the reducing power of the electric energy of the present invention and the apparatus to maintain a low oxidation-reduction potential in the reactor to form a very low anaerobic environment electrochemically to simplify the process as well as the reliability of the system It will be effective to improve.

In addition, the biological denitrification method of the sewage and wastewater by using the reducing power of the electric energy of the present invention and the device is to reduce the size of the system as well as to improve the denitrification efficiency by the denitrification reaction is made to the reaction tank as a whole.

Claims (10)

In the biological denitrification method of wastewater, A potential difference is formed by supplying power to both reactors separated by a selective ion exchange membrane interposed at a predetermined position to form a predetermined oxidation-reduction potential, and a small amount of organic matter is used as a carbon source and electric energy by using the introduced wastewater as an electrolyte. Biological denitrification of sewage and wastewater using reducing power of electrical energy, characterized in that it can be supplied with the reducing power required for breathing denitrification microorganisms. The method of claim 1, Biological denitrification method of sewage and wastewater using reducing power of electrical energy, characterized in that to selectively supply hydrogen instead of electrical energy as a separate hydrogen supply means to the negative electrode reactor in which the electron is generated. The method of claim 1, A method for biological denitrification of sewage / wastewater using a reducing power of electric energy, characterized in that a redox measuring means for measuring an oxidation-reduction potential is provided in a cathode reactor in which the electrons are generated. In the biological denitrification apparatus of wastewater, The reaction tank is separated into a cathode reactor and a cathode reactor by a cation exchange membrane installed at a predetermined position of the reactor, and the cathode reactor is provided with a negative electrode, and the anode reactor has a reducing power of electric energy. Biological denitrification apparatus of wastewater. The method of claim 4, wherein The positive electrode and the negative electrode are biological denitrification apparatus for sewage and wastewater using a reducing power of electrical energy, characterized in that formed of a carbon nonwoven fabric. The method of claim 4, wherein The positive electrode and the negative electrode are biological denitrification apparatus of sewage and wastewater using a reducing power of electrical energy, characterized in that connected to the power supply. The method of claim 4, wherein Microbial growth medium is used in the cathode reaction tank, potassium chloride is used in the anode reaction tank biological denitrification of sewage and wastewater using the reducing power of the electric energy. The method of claim 4, wherein The positive electrode is a biological denitrification apparatus of sewage and wastewater using reducing power of electrical energy, characterized in that the surface is formed in an uneven shape so as to maximize the electron transfer efficiency of the denitrification microorganism by widening the surface area. The method of claim 4, wherein Biological denitrification apparatus for sewage and wastewater using reducing power of electrical energy, characterized in that the cathode reaction tank is provided with a quasi-electrode and a working electrode to detect an oxidation-reduction potential. The method of claim 4, wherein The carbon dioxide supply unit for aeration of the carbon dioxide stored in the storage tank in the culture medium of the cathode reaction tank with a pump is provided.