KR20000036253A - Waste water treatment apparatus - Google Patents

Abstract

PURPOSE: A treatment method of waste water is provided, which is characterized in that an aerobic tank, a first oxygen tank, an anoxic tank, a second oxygen tank, and a settling tank are arranged in order, and a pathway for returning is provided between the settling tank and the first oxygen tank. CONSTITUTION: Wastewater that contains BOD is transferred into an aerobic tank (11), and BOD components are changed into suspended solid and carbon dioxide. Autotrophic bacteria like nitrosomonas and nitrobacter change ammonium nitrate into nitrogen oxide. Treated waste water is transferred into the first oxygen tank (13), so, microorganisms intake excess phosphorus, and nitrogen oxide is oxidized. In the anoxic tank (14), total nitrogen is decreased, and, in the second oxygen tank, dissolved oxygen is increased. Water is discharged after settling tank (16), sludge is returned to anoxic/anaerobic tank (19). Microorganisms discharge phosphorus, and these phosphorus are removed in the first oxygen tank (13).

Description

Waste water treatment apparatus

The present invention relates to a wastewater treatment apparatus for removing nutrient salts contained in wastewater, and more particularly, to a wastewater treatment apparatus for biologically removing nitrogen and phosphorus in wastewater.

Biological wastewater treatment is a kind of secondary treatment of wastewater and is mainly used as sludge treatment or wastewater treatment containing a large amount of organic matter. Biological wastewater treatment is a method of removing organic matter degradable by living organisms from microorganisms. The unit process for this is spraying water phase, activated sludge method, aerobic and anaerobic digestion, oxidation oxidation method, and decay tank. It is a method of treating wastewater by oxidizing suspended, dissolved or colloidal biodegradable organic matter in water and into water and carbon dioxide or precipitated microorganisms.

The trickling filter method uses a biological fixation membrane, which is based on sprinkling the effluent from the primary sedimentation basin on crushed stone or other plastic media covered with a microbial membrane. Organics are decomposed by microorganisms and colloidal organics are adsorbed on the surface. Oxygen to maintain the aerobic state is supplied by air flowing naturally in the opposite direction to the wastewater along the space between the media from the bottom of the filter bed to the surface. However, if the space in the filter bed is blocked or the organic load is large, an anaerobic condition may occur to generate odor.

Another method of using a fixed membrane is the rotating disc method, where about 40% of the disc is submerged in water and the disc has a large surface area for microorganisms to attach. When the disc is submerged, food is supplied to the microorganisms and oxygen is supplied when the disc is exposed to the atmosphere.

The activated sludge method injects wastewater into the aeration tank under aerobic conditions in which dissolved oxygen is present at least 2 mg / l, so that the microorganisms ingest and decompose the organic matter, and the grown microorganisms are condensed. It is partially returned to the wastewater, and part of the wastewater treatment method to allow the supernatant of the terminal settler to flow out as treated water while being discarded as waste sludge.

The configuration of the wastewater treatment apparatus for performing this activated sludge method varies. The first part of the aeration tank can be converted to an anaerobic tank so that the returned activated sludge can be mixed with the waste water in the anoxic tank, an airless reaction tank, and the inside of the aerobic tank, the beginning of the aeration tank, at the end of the aeration tank to increase the removal efficiency of nitrate nitrogen. Circulation may also be added. In addition, devices have been proposed for the removal of not only nitrogen but also sideways. In other words, a process has been developed in which an anaerobic tank is placed at the front end so that phosphorus is released from the microorganisms into the wastewater and then the phosphorus released into the wastewater in the subsequent aerobic tank causes the microorganisms to ingest excessively to remove the phosphorus.

However, there are some difficulties in the modification of the apparatus for carrying out the activated sludge method, in particular, there is a problem that the additional removal of nitrogen and phosphorus is not sufficient. For example, there are cases of using phosphorus removal materials such as alum or iron chloride and denitrification materials such as methanol, which generate excessive sludge for phosphorus removal and require a separate reactor for nitrogen removal. Excessive methanol sometimes results in operating conditions that are not compatible with changes in the concentration of nitrate nitrogen.

The fixed membrane process, such as the above-described water spraying or spinning disc apparatus, mainly oxidizes ammonia nitrogen to nitrate nitrogen, and requires an extra reactor and chemicals to remove nitrate nitrogen and phosphorus. Therefore, the general trend is to adopt the activated sludge method instead of the fixed membrane method, or to perform the activated sludge method after the fixed membrane method, which is expensive and can not ignore the problems accordingly.

Nitrogen in wastewater is classified into organic organic nitrogen and ammonia and nitrate inorganic nitrogen. These are collectively called total nitrogen (TN), and organic nitrogen and ammonia nitrogen are collectively called TKN (Total Kjeldahl Nitrogen). . Most of the nitrogen components flowing into the sewage and wastewater exist in the form of TKN, which must be converted to nitrate nitrogen (NO _x ) in order to remove these nitrogen components biologically. Some of the incoming nitrogen components (organic nitrogen) are removed by being used as a nutrient source for microbial cell synthesis, and the remaining nitrogen components are converted to the form of nitrate nitrogen (nitrification) by the action of the microorganisms and then converted into N ₂ gas ( Denitrification) Release into the atmosphere. This denitrification requires organics and no dissolved oxygen.

The process of removing phosphorus present in the wastewater is a dephosphorization process, and may be performed by microorganisms. That is, in the anaerobic state, phosphorus is released and short chain fatty acid formed from soluble microorganisms in the influent is stored intracellularly as PHB (polyhydroxybutyrate) .In aerobic state, phosphorus is ingested using the stored substrate to form polyphosphate. Phosphorus in the wastewater is removed by storage. Anaerobic reactors should be free of nitrate nitrogen for the release of phosphorus by microorganisms.

Therefore, biological denitrification and dephosphorization processes in the wastewater treatment process are based on the growth of microorganisms, which use them as nutrients when microorganisms normally grow. That is, the microbial cells are composed of C, H, O, N, nitrogen and phosphorus are required to synthesize such cells. Thus, if nutrients in the wastewater are suitable for the microorganism, all dissolved nitrogen and phosphorus will be ingested by the microorganism and converted into cytoplasm. However, the microorganisms need carbohydrates or other organic materials to supply carbon and energy, and the reaction efficiency varies depending on the type of carbon source. As such, in order for denitrification and dephosphorization to be effective, an appropriate ratio of COD (or BOD): nitrogen must be maintained. Therefore, the amount of carbon source needed depends on the amount of nitrogen and phosphorus in the waste water to be removed. The organic carbon source is classified into an internal carbon source existing in the wastewater and an external carbon source additionally injected from the outside, and the residence time in the reaction tank may vary because the reaction rate and processing efficiency vary depending on the type of the external carbon source.

In biological treatment methods, microorganisms are also greatly affected by temperature, so the treatment efficiency varies depending on the temperature conditions. When the temperature is low, such as in winter, the rate of nitrification is lowered, resulting in a decrease in the rate of nitrate nitrogen required for denitrification. In this case, the dissolved oxygen must be supplied sufficiently to generate nitrate nitrogen. If the dissolved oxygen concentration is high, the removal efficiency of nitrogen and phosphorus is lowered because the operating conditions of the anaerobic / anoxic tank cannot be maintained.

Therefore, in order to biologically treat nitrogen and phosphorus contained in the wastewater, the wastewater is first introduced into an anaerobic tank / anoxic tank so that denitrification and phosphorus-release reactions by microorganisms occur, and then excess phosphorous intake and nitrification are performed in the aeration tank. This is the general way.

U.S. Patent No. 4,867,883 consists of the order of the first settling tank, anaerobic tank, anoxic tank, oxygen tank, secondary settling tank in order to go through these reaction tanks in order, from anoxic tank to anaerobic tank, oxygen tank to anoxic tank, and secondary tank to anoxic tank Disclosed is a wastewater treatment apparatus configured to convey. In the anaerobic tank of this wastewater treatment system, the treated water of the primary sedimentation tank and the return water from the anoxic tank are introduced, and reactions in which the microorganisms release phosphorus using internal organic matter occur, in which the condition is free of dissolved oxygen. In the anoxic tank, the return sludge from the secondary settling tank, the return water from the oxygen tank, and the treated water from the anaerobic tank flow in. The return water from the oxygen tank contains a large amount of nitrate nitrogen, which is included in the inflow water from the anaerobic tank. Denitrification using organic materials occurs. In the oxygen tank, the treated water from the oxygen-free tank is introduced to supply dissolved oxygen for organic matter removal and nitrification. If the nitrification does not occur in the oxygen tank, the denitrification reaction cannot occur in the anoxic tank, so the nitrification should occur in the oxygen tank for nitrogen removal. In the secondary settling tank, solid-liquid separation occurs, part of the sludge returned to the anaerobic tank and part of it is disposed of as waste sludge.

U.S. Patent 4,056,465 discloses a wastewater treatment apparatus having the same structure as the U.S. Patent 4,867,883 but having a difference in conveyance. That is, conveyance is made only to an anaerobic tank in an oxygen tank, and to an anaerobic tank in a secondary precipitation tank.

Therefore, the technical problem to be achieved by the present invention is to provide a wastewater treatment apparatus that can achieve a high treatment efficiency at a low cost.

1 is a schematic diagram of a wastewater treatment apparatus according to an embodiment of the present invention.

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

11: Aerobic Treatment Tank 13: First Oxygen Tank

14: the second oxygen tank 15: the second oxygen tank

16: settling tank 17: return path

18: External carbon supply means 19: Anaerobic / anaerobic tank

In order to achieve the above technical problem, in the present invention, the aerobic treatment tank, the first oxygen tank, an oxygen-free tank, the second oxygen tank, is disposed in the order of the settling tank, a conveying path is provided between the settling tank and the first oxygen tank, It is also achieved by a wastewater treatment apparatus having an anaerobic / anaerobic bath in the conveying path.

Preferably, an external carbon source supply means is connected to the anaerobic / anaerobic bath.

It is preferable to provide a second anoxic tank between the second oxygen tank and the precipitation tank.

The external carbon source may be any microorganism that can be used, but volatile fatty acids, methanol and hydrocarbons having 6 or less carbon atoms are preferable.

Hereinafter, examples of various aspects, including the principle of operation of the wastewater treatment apparatus of the present invention, will be described in detail with reference to the accompanying drawings.

First, the terms used throughout the present specification will be summarized.

"Aerobic treatment tank" means a well-known aerobic biological treatment device such as activated sludge device, which includes a fixed membrane device such as a rotating disc device and a water spraying device, a slurry device using a stabilizing paper, a lagoon, and an oxidation sphere method. This includes. The main purpose of such aerobic biological oxidation baths is the reduction of BOD by aerobic biological treatment.

"Aerobic condition" in an aeration tank means an aeration operation condition made by a well-known mechanism, such as an aeration device and an agitator. "Aerobic" means containing a certain amount of dissolved oxygen.

"Anoxic conditions" means that dissolved oxygen is not present in the wastewater, but chemically bound oxygen, such as nitrate nitrogen, is useful for microbial metabolism.

By "anaerobic condition" is meant that only anaerobic microorganisms can grow because there is no dissolved oxygen or nitrate nitrogen in the waste water.

"Sedimentation" means separation of general solids, including filtration, centrifugation, and the like.

"Volatile fatty acids" are water-soluble fatty acids that can be evaporated at atmospheric pressure, including water-soluble fatty acids of up to 6 carbon atoms, and also include hydrocarbons of volatile fatty acids.

Since biological treatment of wastewater is based on the growth of microorganisms used for biological treatment, it is necessary to create conditions favorable for the growth of microorganisms. Therefore, it is sometimes necessary to supply nutrients to the wastewater to be suitable for the growth of microorganisms. For example, when treating paper wastewater, it is desirable to maintain a ratio of nitrogen: BOD = 1: 20 and phosphorus: BOD = 1: 75, which requires the addition of nitrogen and phosphorus. The wastewater treatment apparatus of the present invention is characterized in that by optimizing the configuration of the reaction tank of the wastewater treatment apparatus, nitrogen and phosphorus can be adjusted to their proper level in the system and ultimately increase their removal efficiency.

1 is a schematic diagram of a wastewater treatment apparatus according to an embodiment of the present invention.

High BOD wastewater containing suspended solids, nitrogen and phosphorus is delivered to the aerobic treatment tank (11). As mentioned earlier, the aerobic treatment tank 11 may be an activated sludge device, a water spray device, or a rotating disc device. In this oxidizer, the BOD component is converted to suspended solids (SS) and carbon dioxide, and part of the ammonia nitrogen is converted to nitrate nitrogen. This conversion of nitrogen is called nitrification. In order for nitrification to occur due to the oxidation of microorganisms, the BOD must be reduced to 14 mg / l or less. This is because autotrophic bacteria such as Nitrosomonas and Nitrobacter are involved in the conversion of ammonia nitrogen to nitrate nitrogen. In the aerobic treatment tank 11, the activity of heterotrophic bacteria such as Bacillus is predominant, and these heterotrophic bacteria decompose BOD components. These heterotrophic bacteria limit the activity of nitrifying autotrophic bacteria until the BOD concentration is sufficiently low, and the activity of the autotrophic bacteria prevails when the activity of the heterotrophic bacteria decreases.

The outflow water from the aerobic treatment tank 11 and the outflow water from the anaerobic / anaerobic tank 19 flow into the first oxygen tank 13 and are mixed. In the first oxygen tank 13, the microorganisms excessively ingest the phosphorus to quickly remove the phosphorus in the waste water, and ammonia nitrogen is oxidized to nitrate nitrogen. Effluent from the first oxygen tank 13 flows into the anoxic tank 14 where the total nitrogen is reduced as the nitrate nitrogen is reduced to nitrogen gas. The effluent from the anoxic tank 14 flows into the second oxygen tank 15 before it is sent to the settling tank 16, where it stays briefly, increasing the concentration of dissolved oxygen. Finally, purified wastewater with significant reductions in nitrogen, phosphorus, BOD and SS and reduced turbidity is discharged from the settling tank 16. Part of the purified waste water and sludge are returned to the anaerobic / anaerobic tank 19 through the conveying path 17, the external carbon source is supplied to the anaerobic / anaerobic tank 19 via the external carbon source supply means 18, In the anaerobic tank 19, phosphorus release reaction occurs by the microorganism under anoxic / anaerobic conditions, and the effluent from the anoxic / anaerobic tank 19 flows into the first oxygen tank 13 containing a large amount of phosphorus, as described above. As described above, the phosphorus is removed from the first oxygen tank 13 by the excessive intake reaction of phosphorus by the microorganism. On the other hand, if a second anoxic tank (not shown) is provided between the second oxygen tank 15 and the precipitation tank 16, the total nitrogen is further reduced by the reduction of the nitrate nitrogen generated in the second oxygen tank 15 to nitrogen. Can be reduced.

In fact, in the case where an oxygen free tank is additionally installed between the final oxidation tank and the settling tank while using the wastewater treatment apparatus of FIG. 1, the total nitrogen content is greatly reduced due to the drastic reduction of nitrous nitrogen and nitrate nitrogen.

The external carbon source used in the present invention is not particularly limited as long as the microorganism can be used, but it is particularly preferable to use volatile fatty acids, methanol, and hydrocarbons having 6 or less carbon atoms.

While the invention has been described above by way of some embodiments, it will be understood that various modifications may be made without departing from the scope of the invention as defined by the appended claims.

In the present invention, unlike the configuration of the conventional wastewater treatment apparatus, by configuring and arranging the reaction tank, nitrogen and phosphorus in the wastewater can be removed efficiently and at low cost. In addition, by modifying the existing facilities can increase the denitrification, dephosphorization removal efficiency without excessive investment.

Claims (4)

An aerobic treatment tank, a first oxygen tank, an oxygen-free tank, a second oxygen tank, and a settling tank are disposed in this order, and a conveying path is provided between the settling tank and the first oxygen tank, and the waste water having an anoxic / anaerobic tank in the conveying path. Processing unit. The wastewater treatment apparatus according to claim 1, wherein an external carbon source supply means is connected to the anaerobic / anaerobic tank. The wastewater treatment apparatus according to claim 2, wherein the external carbon source is at least one compound selected from the group consisting of volatile fatty acids, methanol and hydrocarbons having up to 6 carbon atoms. The wastewater treatment apparatus according to any one of claims 1 to 3, further comprising a second anoxic tank between the second oxygen tank and the settling tank.