KR20110129210A - Organic Waste Disposal System with Improved Methane Yield and Method - Google Patents

Abstract

PURPOSE: Organic waste treating apparatus and method of improved methane yield are provided to reduce the generating amount of sludge, to improve the generating efficiency of methane, and to use the efficiency of the organic waste. CONSTITUTION: An acid fermenting bath, a solid-liquid separating bath, an anaerobic digesting bath, an autothermal thermophlic aerobic digesting(ATAD) bath, a stabilizing bath, a precipitating bath, and a sludge digesting bath are prepared. The acid fermenting bath implements a hydrolyzing reaction and an acid generating reaction by introducing pre-treated food waste, sewage sludge, wastewater sludge, agricultural waste, and livestock waste. The solid-liquid separating bath eliminates acid fermented microorganisms. The anaerobic digesting bath generates methane gas by digesting acetic acid and alcohol-containing organic materials. The ATAD bath decomposes the organic materials from the anaerobic digesting bath and eliminates nitrogen without nitration. The weight of sludge is reduced through the ATAD bath. The stabilizing bath changes the characteristic of the sludge. The precipitating bath precipitates the sludge and implements a solid-liquid process with respect to liquid from the stabilizing bath. The sludge digesting bath methane-ferments the sludge from the precipitating bath.

Description

Organic waste disposal apparatus and method thereof with improved methane yield {omitted}

The present invention promotes the digestion of organic waste contained in high concentration organic waste such as food waste, sewage sludge, wastewater sludge, agricultural waste, livestock waste, etc., reduces sludge generation, maximizes the efficient use of organic waste and methane generation efficiency. The present invention relates to an organic waste treatment apparatus having improved methane yield using an anaerobic digestion method and a method thereof.

In recent years, the development of high-density organic wastes such as food waste, sewage sludge, wastewater sludge, agricultural waste, livestock manure, etc., which occur in large quantities as the material life becomes more abundant, is roughly classified into incineration, landfill, and recycling technologies. Recycling technologies are divided into feed and compost.

These organic wastes contain a large amount of water, so incineration of these organic wastes requires pretreatment to remove moisture from the organic wastes or lower the moisture content before incineration. Therefore, such incineration methods increase the cost and time for treating organic wastes. There is a problem, and it is a technology specified as a serious problem causing secondary environmental pollution due to the generation of dioxins due to incomplete combustion due to low calorific value and moisture content.

Landfilling of organic waste is a national ban on the grounds of polluting soil by secondary leachate of organic waste, and generating odor, and waste of resources that can effectively use and recycle limited land.

Feeding technology is the most prevalent technology in terms of resource recycling, but it is a technology that requires very difficult procedures in the process of treatment. Recently, there are many problems. Composting technology has aerobic and anaerobic methods, but aerobic methods are breathing aerobic microorganisms. The use of a moisture control agent (sawdust, etc.) is required to smoothly reduce the economical efficiency and disadvantages in the air. On the other hand, anaerobic treatment is blocked from the atmosphere to solve the odor problem. There is an advantage in that the available biogas (about 70% methane component) is generated and uses energy.

In more detail, the biogas generation technology has been recently developed technologies related to the utilization of energy resources using organic waste. For example, as a method of producing biogas by anaerobic digestion of organic waste, This is a technology that can be converted to electricity and thermal energy using the produced biogas, and can be used as a fertilizer as a by-product, so its utilization is high and continuous development is required.

In particular, as part of the process of recycling food waste, research on the recycling of food waste into methane gas has been actively conducted, that is, the anaerobic digestion, and the anaerobic digestion means that various complex symbiotic microbial communities are anaerobic. It is the process of decomposing organic matter into methane and carbon dioxide in the state.

Theoretically, about 90% of the biodegradable organics in the waste can be converted to methane, and moreover, the sludge produced after the anaerobic digestion by stabilizing the organic wastes does not cause any environmental hazards to the soil and water, so that the soil improver and fertilizer It can be used as a further energy savings.

In addition, methane, a major component of biogas, is a flexible form of renewable energy that can be converted into heat and electricity and used as a vehicle fuel.

In conclusion, anaerobic digestion reduces the potential risks to global climate change in two ways: First, methane, which has a global warming contribution of about 21 times that of carbon dioxide, is about the amount of greenhouse gas emissions in Korea. As it accounts for 15%, the capture of biogas through anaerobic digestion can reduce methane emissions in the natural state. Second, if biogas produced in anaerobic digestion can be replaced with fossil fuels, carbon dioxide generated from chemical fuels can be avoided, thereby reducing global warming agents.

However, the anaerobic digestion process has problems such as low growth rate of microorganisms, odor of treated effluents, and the need for a large amount of buffer for pH control, and the aerobic treatment is difficult to overcome these problems with existing technologies. It is not attracting much attention compared to the process because the various species of anaerobic bacteria form a symbiotic relationship and the conversion of various organic materials to methane requires a very complicated and multi-step route for successful anaerobic process operation. This is because monitoring and control were relatively difficult.

Looking at the technology of organic waste treatment for recovering methane using anaerobic digestion recently developed, Korean Patent No. 10-0374485 discloses organic waste (sewage sludge, animal waste, food waste) mixed organic waste (1) crusher ( 3) pre-treatment step of crushing and conveying to the screw type sorter (5) and cyclone separator (6) to separate the contaminants, and breaks the structure of the organic component so that the organic waste through the pretreatment step is easy to decompose the organic component Hydrolysis step by adding chemicals to remove odors and corrosive hydrogen sulfide.Hydrogenated slurry is heated to 35-42 ℃ through a heat exchanger to maintain an easy temperature for anaerobic microorganisms to act as a digester. In the feeding step, the injected slurry in a single phase anaerobic state, the digestion step and the generated methane gas is supplied as fuel. Organic waste treatment has been developed, which consists of dewatering and drying the sludge and producing compost, but this treatment is based on data measured by measuring pH, temperature, residence time, mixing and agitation in a single-phase digester. It is also difficult to monitor and control for successful anaerobic process operation in order to obtain the maximum methane yield by operating in optimal conditions.

In Korean Patent No. 10-0592492, anaerobic microorganisms including hydrolysis microorganisms, acid-fermenting microorganisms and methane-producing microorganisms are planted in a high temperature reactor and a medium temperature reactor connected in series, respectively, and organic wastes are maintained by maintaining a symbiotic relationship between these anaerobic microorganisms. A method of treating organic wastes, the method comprising: (1) introducing organic waste into a high temperature reactor containing anaerobic microorganisms and maintained at 50 to 55 ° C to react with the anaerobic microorganisms, (2) The anaerobic microorganism is contained, and the supernatant after the step (1) treatment is introduced into a middle temperature reactor maintained at 30 to 35 ° C. to react with the anaerobic microorganisms, and (3) the organic matter treated in the medium temperature reactor after step (2). Organic using a continuous batch high temperature / mid temperature two-stage anaerobic digestion process comprising the step of draining the waste Waste treatment methods are well known, which means that organic waste can be recovered by continuous batch operation of high temperature and medium temperature reactors to maximize the volume loss to be disposed of and to convert the liquefied organics into methane gas, a useful energy source. Although it is disclosed that it can significantly increase, there is a problem that the technical difficulties in maintaining the symbiotic relationship of anaerobic microorganisms in the high temperature / medium temperature two-stage anaerobic digestion tank.

Korean Patent No. 10-0745186 has an input tank into which food waste, agricultural waste, etc. are input; An automatic crushing separator installed at one side of the feeding tank to automatically grind the food waste put into it to crush the organic solids and separate the impurities; A storage tank connected to the automatic crushing sorter and into which food waste automatically ground therefrom is input and stayed; An acid fermentation tank in which the organic wastes staying connected to the storage tank are charged and the organic wastes injected are hydrolyzed and acid fermented to liquefy the solids; An anaerobic digestion tank which is connected to the acid fermentation tank and digests unreacted polymer organic substances introduced therefrom into carbon dioxide gas and methane gas; A gas holder connected to the anaerobic digester and storing methane gas generated therefrom; An organic waste treatment apparatus using an anaerobic digestion method, which is connected to the anaerobic digester and separates suspended solids and waste liquid from the treated water supplied therefrom, is known, but it can recycle biogas. As a general anaerobic digestion method, there is a problem that does not increase the methane generation efficiency.

Korean Patent Application Publication No. 10-2009-0123384 discloses the recycling of organic wastes, such as livestock wastes and urine from domestic households, by using anaerobic digestion to produce biogas as an energy resource. An apparatus for producing a fuel, comprising: agitation means for mixing organic wastes such as food waste and animal waste, urine, which are introduced through a hopper; The base surface has a predetermined slope gradually going from the front to the rear, and partitions the enclosed space into a first wall and a second wall in which the lower side communicates with each other so that organic waste flows from the stirring means through the screw feeder. An anaerobic digestion tank consisting of an acid fermentation space on the side and a methane fermentation space having at least one flotation to increase and decrease the surface area of fermentation of the treatment while rising and lowering according to the liquid level of the organic waste on the upper side; Regenerated fuel production apparatus using organic wastes has been developed, characterized in that it is equipped with a collection pipe for recovering the generated methane gas on the upper side of the methane fermentation space of the anaerobic digestion tank, At the same time, the liquid level of organic waste is lowered due to the filling pressure of the methane gas, and organic waste adheres to the surface as the floating bodies are exposed, thereby increasing the fermentation surface area, thus increasing the efficiency of treatment and reducing the time and gas generation. Of course, to increase the yield, but there is a problem in the economics of using a separate floating body and equipment.

Korean Patent No. 10-0883676 discloses a raw material storage tank in which an object to be treated is stored; An acid fermentation tank in which acid fermentation of the processing object flowing from the raw material storage tank is performed; A methane fermentation tank formed in a separate space from the acid fermentation tank, in which the fermentation broth of the acid fermentation tank is introduced to perform methane fermentation; And a gas collecting device for collecting the gas of the fermentation broth from which the methane fermentation is made in the methane fermentation tank, wherein a buffer tank is further provided between the acid fermentation tank and the methane fermentation tank to adjust the pH of the acid fermentation tank while passing through the buffer tank. After being put into the methane fermentation tank, the acid fermentation tank or methane fermentation tank or buffer tank or both, the sensor for measuring pH is installed, the sensor is connected to an external monitor to monitor the pH value of each reactor, When the buffer tank is connected to the lime tank for lime injection, when the pH value measured by the pH measuring sensor installed in the buffer tank is less than 6.8, the lime is automatically injected into the buffer tank from the lime tank and the pH value of the buffer tank is 6.8. PH control through real-time pH monitoring, characterized in that to maintain more than 7.2 or less Abnormal anaerobic digestion apparatuses are known, and these abnormal anaerobic digestion apparatuses are buffered to control the pH in the anaerobic digestion system in order to prevent the pH lowering caused by the acid fermentation liquid flowing out of the acid fermentation tank directly into the methane fermentation tank. The tanks were introduced, and each reactor was equipped with a sensor for measuring pH to perform pH monitoring in real time, so that the impact of the impact loads in each reactor could be immediately responded, maximizing the efficient use of food waste and the generation of biogas. Although the pH control is made through real-time pH monitoring that can be stabilized, this also has a problem in economic efficiency in that a separate buffer tank is installed, and it is difficult to monitor and control for successful anaerobic process operation.

Korean Patent No. 10-0903062 discloses a high pressure homogenizer for crushing and liquefying solids contained in an organic waste liquid; A solid-liquid separation acid fermentation tank for acid fermenting and solid-liquid separation of the treated water flowing out from the high pressure homogenizer; High-efficiency anaerobic tank for recovering methane by digesting the organic matter discharged from the solid-liquid separation acid fermentation tank; And a nutrient recovery tank for recovering nitrogen and phosphorus contained in the treated water flowing out of the high-efficiency anaerobic tank, wherein the nutrient recovery tank returns the discharged water from which the nitrogen and the phosphorus have been recovered to the solid-liquid separation acid fermentation tank. The organic waste liquid treatment apparatus is known, and it is disclosed that the high efficiency anaerobic tank has an effect of increasing the efficiency of the high-efficiency anaerobic process by including a high-efficiency anaerobic tank that recovers methane. As a method, there is a problem that does not substantially increase the methane generation efficiency.

Korean Patent No. 10-0853287 discloses the separation of gaseous and acid-producing tanks and methane-producing tanks from anaerobic digestion of high concentration livestock wastewater to improve organic matter removal efficiency, increase methane recovery rate, and methane in operating the anaerobic digestion method. Livestock wastewater digestion systems are known to reduce the quality of the initial operation and maximize the efficiency of methane generation by intermittently injecting methane, known as anaerobic methane, in maximizing recovery. In order to inject methane-generating bacteria in addition to the general anaerobic digestion method, there is a cost problem, and there is a problem that does not increase its own methane generation efficiency.

In the meantime, with the global interest in the development of renewable energy, the first integrated biogas plant was completed in November 2008 at the Asan Environmental Office in Korea, and the integrated biogas plant started using a single raw material. Unlike existing plants that produce biogas, biogas is produced by integrating and digesting sewage sludge, food wastewater, and livestock manure.

This biogas plant is a treatment facility that utilizes biogas generated from anaerobic digestion of organic waste such as food, livestock manure and sewage sludge as fuel. 25 tons of food wastewater, 50 tons of livestock manure and 25 tons of sewage sludge A total of 100 tons of organic matter is processed per day to produce about 1250 m3 of biogas (methane gas), which is similar to natural gas with a mixture of methane and carbon dioxide. When the cogeneration unit is operated with 1250 m 3 of biogas thus generated, about 2900 kW of electricity is generated, which is equivalent to the daily consumption of about 300 households. The electricity generated in this way is used to operate the stirrer in the sewage treatment plant to supply 12% of the daily power consumption of the sewage treatment plant. In addition to this, about 5700 Mcal of hot water is issued daily to be used for heating the biogas plant.

The integrated biogas plant is composed of a storage tank, a heat exchanger, an acid fermentation tank, a methane fermentation tank, a solid-liquid separator, a cogeneration generator, and a deodorization facility for each waste, and organic wastes such as livestock manure stored in each storage tank are transferred through a transfer pump. Organic wastes mixed and mixed into a mixing tank at a constant mixing ratio are introduced into an acid fermentation tank.

The mixed wastes must be raised in temperature before they are introduced into the acid fermentation tanks because the anaerobic digestion of the acid fermentation and methane fermentation tanks takes place at 35 ° C. Therefore, the heat exchanger goes through the heat exchanger before being introduced into the acid fermentation tank. The inside of the heat exchanger is configured to increase the temperature by flowing hot water along each layer.

And after staying in the acid fermentation tank for about 1.5 days, the liquid component from the solid-liquid separator passes through the methane fermentation tank to generate biogas with a methane content of 70-75%. The generated biogas is used as a fuel for the generator after removing water and hydrogen sulfide before being transferred to the gas storage tank, and beforehand, is subjected to a siloxane and fine dust removal device. The biogas thus produced is used as fuel for the generator.

However, the conventional patented technology and biogas plant have a simple anaerobic digestion method, increase the contact surface area of fermentation, control the pH in the anaerobic digestion method, or intermittently inject methane arch, or As methane gas is generated by using an integrated plant, the existing simple anaerobic digestion system is used as it is, or a separate additional facility is installed. There is an urgent need to develop an organic waste treatment system that can improve the quality of wastewater.

Accordingly, the present invention has been made to solve the above problems, to promote the digestion of organic waste contained in high concentration organic waste, such as food waste, sewage sludge, wastewater sludge, agricultural waste, livestock waste, etc. The present invention has been made in an effort to solve the problem of providing an organic waste treatment apparatus and a method of improving methane yield using an anaerobic digestion method that maximizes the efficient use of organic waste and the efficiency of methane generation.

In the organic waste treatment window, organic wastes of pretreated food waste, sewage sludge, wastewater sludge, agricultural waste, and livestock waste are introduced to hydrolysis (low molecular weight of high molecular organic material) and acid production (organic acid of low molecular weight material). Acid fermentation tank in which the reaction takes place; A solid-liquid separation tank for removing acid-fermented microorganisms predominant in the acid fermentation tank; An anaerobic digestion tank connected to the solid-liquid separation tank and digesting organic matter including acetic acid and alcohol introduced therefrom to generate methane gas; The organic material introduced from the anaerobic digester is maintained at 45 ° C. to 70 ° C., which is suitable for the activity of high temperature microorganisms, to quickly decompose the organic material, remove nitrogen by ammonia stripping, and reduce sludge without undergoing nitrification. Autothermal Thermophlic Aerobic Digestion (ATAD); High temperature aerobic digestion tank and operating conditions to further treat the remaining organic matter and nutrients (nitrogen, phosphorus) in the treatment liquid introduced from the high temperature aerobic digestion tank, cooling the ATAD treated water, stabilizing the high temperature microorganisms and / or microorganisms to replace the general microorganisms Stabilizing tank for changing the sludge properties to a substrate suitable for the sludge digestion tank by different; A settling tank which solid-separates the treated liquid introduced from the stabilization tank, precipitates and discharges the sludge or is connected to a sewage treatment system; Sludge digestion tank to introduce a portion or all of the sludge of the sedimentation tank into the sludge digestion tank to multiply the methane spawn while fermenting methane and return to the anaerobic digestion tank to improve the methane yield of the anaerobic digestion tank. An organic waste treatment apparatus having an improved methane yield is a solution to the problem.

In addition, the present invention is organic waste treatment method, pre-treated food waste, sewage sludge, wastewater sludge, agricultural waste, organic waste of livestock waste is introduced into the hydrolysis (low molecular weight of high molecular organic material) and acid production (low molecular weight material) Acid fermentation step of the reaction); A solid-liquid separation step for removing acid-fermenting microorganisms predominant in the acid fermentation step; An anaerobic digestion step of producing methane gas by digesting an organic material including acetic acid and alcohol generated in the acid fermentation step after the solid-liquid separation step; Maintaining 45 ℃ ~ 70 ℃ suitable for the activity of the medium, high temperature microorganism to the organic material that has undergone the anaerobic digestion step to decompose organic matter quickly, remove nitrogen by ammonia stripping without nitrification process and reduce sludge High temperature aerobic digestion step; High temperature aerobic digestion tank and operating conditions to further treat the remaining organic matter and nutrients (nitrogen, phosphorus) in the treatment liquid introduced from the high temperature aerobic digestion tank, cooling the ATAD treated water, stabilizing the high temperature microorganisms and / or microorganisms to replace the general microorganisms Stabilizing step of changing the sludge properties to a substrate suitable for the sludge digestion tank by different; A sludge settling step of solid-liquid separation of the treated liquid introduced through the stabilization step and settling and discharging the sludge or connected to the sewage treatment system; The sludge digestion step of introducing a portion or all of the sludge in the sludge precipitation step to multiply the methane spawn while fermenting methane and return to the anaerobic digestion step to improve the methane yield of the anaerobic digestion step; The organic waste treatment method with improved methane yield is a solution to the problem.

Organic waste treatment apparatus and method of improved methane yield of the present invention promotes the digestion of organic waste contained in high concentration organic waste such as food waste, sewage sludge, wastewater sludge, agricultural waste, livestock waste, etc. In addition, there is an advantageous effect to improve the efficient use of organic waste and methane generation efficiency.

1 is a block diagram of an organic waste treatment apparatus is improved methane yield of the present invention.
Figure 2 is a conceptual diagram of the pressurized flotation for separating oil that is an embodiment of the pretreatment of the present invention
Figure 3 is a methane gas production mechanism by anaerobic digestion of the present invention.
4 is a schematic diagram of sludge reduction by high temperature aerobic digestion (ATAD) of the present invention.
5 is a schematic diagram of nitrogen removal by high temperature aerobic digestion (ATAD) of the present invention.

The organic waste treatment apparatus having improved methane yield of the present invention is an organic waste treatment window, in which organic wastes of pretreated food waste, sewage sludge, wastewater sludge, agricultural waste, and livestock waste are introduced and hydrolyzed (low molecular weight of high molecular organic material). ) And an acid fermentation tank in which acid production (conversion of low molecular weight organic acids) occurs; A solid-liquid separation tank for removing acid-fermented microorganisms predominant in the acid fermentation tank; An anaerobic digestion tank connected to the solid-liquid separation tank and digesting organic matter including acetic acid and alcohol introduced therefrom to generate methane gas; The organic material introduced from the anaerobic digester is maintained at 45 ° C. to 70 ° C., which is suitable for the activity of high temperature microorganisms, to quickly decompose the organic material, remove nitrogen by ammonia stripping, and reduce sludge without undergoing nitrification. Autothermal Thermophlic Aerobic Digestion (ATAD); High temperature aerobic digestion tank and operating conditions to further treat the remaining organic matter and nutrients (nitrogen, phosphorus) in the treatment liquid introduced from the high temperature aerobic digestion tank, cooling the ATAD treated water, stabilizing the high temperature microorganisms and / or microorganisms to replace the general microorganisms Stabilizing tank for changing the sludge properties to a substrate suitable for the sludge digestion tank by different; A settling tank which solid-separates the treated liquid introduced from the stabilization tank, precipitates and discharges the sludge or is connected to a sewage treatment system; Sludge digestion tank to introduce a portion or all of the sludge of the sedimentation tank into the sludge digestion tank to multiply the methane spawn while fermenting methane and return to the anaerobic digestion tank to improve the methane yield of the anaerobic digestion tank. do.

In addition, the organic waste treatment method of the improved methane yield of the present invention is organic waste treatment method, pretreated food waste, sewage sludge, wastewater sludge, agricultural waste, livestock waste organic waste is introduced into the hydrolysis (polymerization of the organic material) An acid fermentation step in which the reaction of low molecular weight) and acid production (conversion of low molecular weight organic acid) occurs; A solid-liquid separation step for removing acid-fermenting microorganisms predominant in the acid fermentation step; An anaerobic digestion step of producing methane gas by digesting an organic material including acetic acid and alcohol generated in the acid fermentation step after the solid-liquid separation step; Maintaining 45 ℃ ~ 70 ℃ suitable for the activity of the medium, high temperature microorganism to the organic material that has undergone the anaerobic digestion step to decompose organic matter quickly, remove nitrogen by ammonia stripping without nitrification process and reduce sludge High temperature aerobic digestion step; High temperature aerobic digestion tank and operating conditions to further treat the remaining organic matter and nutrients (nitrogen, phosphorus) in the treatment liquid introduced from the high temperature aerobic digestion tank, cooling the ATAD treated water, stabilizing the high temperature microorganisms and / or microorganisms to replace the general microorganisms Stabilizing step of changing the sludge properties to a substrate suitable for the sludge digestion tank by different; A sludge settling step of solid-liquid separation of the treated liquid introduced through the stabilization step and settling and discharging the sludge or connected to the sewage treatment system; The sludge digestion step of introducing a portion or all of the sludge in the sludge precipitation step to multiply the methane spawn while fermenting methane and return to the anaerobic digestion step to improve the methane yield of the anaerobic digestion step; It features.

Hereinafter, a detailed technical configuration of an organic waste treatment apparatus and a method of improving methane yield according to the present invention will be described with reference to the accompanying drawings.

The present invention comprises an acid fermentation tank, solid-liquid separation tank, anaerobic digestion tank, high temperature aerobic digestion tank, stabilization tank, sedimentation tank, sludge digestion tank as shown in FIG.

First of all, before the organic waste is introduced into the acid fermentation tank, it is subjected to a pretreatment with a screen of 1 to 5 mm eyes to protect the rear end machinery caused by large contaminants, to prevent troubles, and to increase the hydrolysis rate.

In addition, the organic fermentation tanks are separated from the organic fermentation tank, and food waste liquids contain up to 5% of oil, which not only adversely affects the process but also causes various side effects such as secondary pollution. As a result, the oil may be separated as a pretreatment.

That is, as shown in Figure 2 when the micro-bubbles generated in the pressure tank flows into the diffuser installed in the lower portion of the pressure flotation tank for oil separation, the introduced micro bubbles adsorb the oil present in the pressure flotation tank for oil separation The floating oil is separated into the upper part of the pressure flotation tank for oil separation, and the injured oil is stored in a separate oil storage tank by SKIMMER, which is an oil water separation device, and transferred to a stagnation facility, and the organic waste is an acid fermentation tank with oil separated. Is put into.

When the organic waste from which the oil is separated is introduced into an acid fermentation tank, the organic waste is hydrolyzed and acid fermented to liquefy the solids. The organic waste put into the acid fermentation tank has a residence time of about 2 days and liquefies as the polymer organic material is hydrolyzed and acid fermented. Therefore, the organic wastes that passed through the acid fermentation tank are organically oxidized, and most of them are converted into soluble organics, thereby facilitating their treatment.

In other words, in acid fermentation tanks, pretreated food waste, sewage sludge, wastewater sludge, agricultural waste, and organic wastes from livestock wastes are introduced, resulting in hydrolysis (low molecular weight of high molecular organic material) and acid production (low molecular weight organic acid conversion). The polymers in the organic wastes introduced are polymerized by extracelluar Enzymes such as cellobiase, amylase, protease, and lipase which are secreted by various microorganisms through the hydrolysis step. Organic substances are hydrolyzed and acidified into low molecular weight chains.

As shown in FIG. 3, acid production is used as an electron donor and an electron acceptor of microorganisms in which the hydrolysis reaction products, such as monosaccharides, amino acids, glycerol, and organic monomers such as LONG CHAIN FATTY ACIDS, are involved in acid production. The reaction is converted to short chain fatty acids. Lower fatty acids are further fermented and finally produce methane-producing precursors, acetic acid, alcohol, carbon dioxide and hydrogen.

Acid-fermenting microorganisms include acetobacter spp., Lactobacillus spp, lactobacillus spp., Streptococcus speices, pediococcus spp., Propionibacterium spp. Any one selected from microorganisms such as) or two or more may be used.

The acid fermentation tank is a fully mixed reactor, and the inside of the fermentation tank is always operated to maintain a uniform state, and when the acid fermentation tank is full, the inlet pump is automatically stopped.

On the other hand, acid fermentation tanks maintain a high temperature above 45 ° C to 70 ° C and a high oxygen concentration (narrow redox potential) to oxidize alcohols and organic substances to organic acids in order to increase the speed of fermentation and the yield of organic acids. It is preferable to use the one equipped with the self-heating system and the automatic ORP holding system as the structure of the acid fermentation tank.

That is, the acid fermentation tank absorbs the air inside the acid fermentation tank and circulates the unreacted oxygen inside the acid fermentation tank in the acid fermentation tank in the process of absorbing and circulating water in the acid fermentation tank. Inflow can promote temperature rise and decomposition, and can be recycled to the heat required for fermentation by circulating to the high temperature aerobic digestion tank using the self-heating of the acid fermentation tank.

The waste slurry fermented in the acid fermentation tank is warmed to about 40 ° C. in a heat exchanger and then transferred to the solid-liquid separation tank. The solid-liquid separation tank removes the acid-fermented microorganism predominantly in the acid fermentation tank, acid fermentation microorganisms occupy most of the organic acid bacteria inhibit the growth of methane bacteria when introduced into the anaerobic digestion tank. In particular, raw water, which has a strong propagation of organic acid bacteria, such as food, is predominantly in the anaerobic digester when it is introduced into the anaerobic digester without removing the organic acid bacteria, thereby greatly reducing the yield of methane.

Therefore, the solid-liquid separation tank, as shown in Figure 4, the flocculation chemicals in the acid slurry fermentation in the acid fermentation tank and agglomeration reaction to form a floc by stirring, fine to the waste slurry introduced from the flocculation reaction tank It comprises a dissolved pressure floating solid-liquid separation tank for generating a sludge layer at the top by combining with the floc, micro-agglomerates, and fine solids by diffusing the bubbles and removing the sludge layer with a scraper, and a micro-bubble generating device for generating the micro-bubbles. do.

Subsequently, the organic waste flowing from the solid-liquid separation tank is sent to an anaerobic digester to produce methane gas. In the anaerobic digester, methane gas is produced by decomposing butyric acid and propionic acid, and methane gas is produced. The decomposition step of butyric acid [C3 H7 COOH + 2H2 O → 2CH3 COOH + 2H2], the decomposition step of propionic acid [C2 H5 COOH + 3H2 O → CH3 COOH + 3H2 + H2 CO3], methane production [CH3 COOH → CH4 + CO2 → CO2 + 4H2 → CH4 + 2H2O] step to produce methane gas.

However, in the conventional anaerobic digester, methane gas is generated by acid fermentation and methane fermentation of organic waste at the same time, so that the maximum concentration of methane gas can be generated in the waste by measuring variables such as concentration, pH, temperature and residence time of the waste. It was necessary to control the operating conditions of the anaerobic digester in the optimum condition, but there was a technical difficulty.

In other words, the conventional anaerobic digester was fermented by the action of acid-forming bacteria and methane-forming bacteria at the same time. In this case, the rate of methane production of methane-producing bacteria is relatively slower than that of acid-forming bacteria. Accumulation of volatile fatty acids) results in lowering of pH and inhibiting the activity of methane forming bacteria. Moreover, acid-forming and methane-forming bacteria differ greatly in their physiological properties, nutritional requirements, growth kinetics, and sensitivity to their environment.

For this reason, if the existing anaerobic digester fails to satisfy the growth conditions of the microorganisms in the anaerobic digester, such as failure to adjust the pH, it may inhibit the growth of the microorganisms, leading to a decrease in the efficiency of biogas (methane) production. There was a problem in not responding properly to the load stratum.

Therefore, the anaerobic digestion tank of the present invention is an important device for treating organic waste. In an acid fermentation tank, hydrolysis and organic acid fermentation (polymeric organic acid, ie, CH 3 CH 2 COOH-propionic acid) reaction occur, but in this anaerobic digester, unreacted polymer organic matter and The organic acid is finally converted to CH3COOH (acetic acid), and the methane bacteria react with CH4 + CO2 in acetic acid to produce methane.In anaerobic digestion tanks, the methane bacteria can be maintained in a large number, and the microorganisms and organic substances are very It should be stirred for good contact and the concentration of the microorganism should be maintained at 25,000 mg / L or more.

In order to maintain a large number of methane bacteria, conventionally, a method of intermittently injecting absolute anaerobic archaeal bacteria (methanogens) that produce methane is used, but in the present invention, some or all of the final settling sludge is sludged. Sludge digestion tank is introduced into the digestion tank to multiply methane while fermenting methane and return to the anaerobic digestion stage, or the existing idle sludge digestion tank can be used to maintain a lot of methane bacteria in the anaerobic digestion tank. There is a characteristic of technical configuration.

Methanogenic microorganisms include: metanobacterium spp., Metanobrevibacter spp., Metanospririllum spp., Metanoplanus spp., Methanplanus spp. Cacao spissis, methanosarcina spp., Methanosarcina spp., Metanoc. Trix spis. Methanolobus spp., Methanolobus spp., Metanococoid spis. Any one or more than two may be used.

Here, the pH of the acid fermentation tank and anaerobic digester is a factor that greatly affects the growth of microorganisms, and it is preferable to adjust the optimum pH because the optimum pH for the growth of microorganisms in the acid fermentation tank and anaerobic digestion tank is different. Is about 5 to 6, in the case of anaerobic digester pH is preferably adjusted to about 6.5 to 8, in particular, anaerobic digester is particularly preferably to operate at pH 7. This is because methane-producing bacteria are very sensitive to change and difficult to grow when the pH drops below 6 due to the accumulation of organic acids.

Autothermal Thermophlic Aerobic Digestion (ATAD) is used to decompose wastes decomposed into organic acids having a low molecular weight using high temperature aerobic microorganisms through an acid fermentation tank and an anaerobic digestion tank, and the high temperature aerobic digestion tank of the present invention is installed by a dust collector. During the process, volatile organic compounds (VOC) and volatile fatty acids (VFA) generated in the aerobic digestion tank can be removed.The operating conditions are 45 ℃ ~ 70 ℃, air injection, and hydrogen ion concentration of solution (PH). It is desirable to maintain the condition of ~ 8, DO concentration of 0.2ppm or more, and the foam generated in the high temperature aerobic digestion tank in conjunction with the scum defoaming tank may be re-introduced into the high temperature aerobic digestion tank by stirring and removing the foam of the waste from the scum defoaming tank. have.

The high temperature aerobic digestion tank decomposes organic matter rapidly by maintaining 45 ° C. to 70 ° C. suitable for the activity of high temperature microorganisms during the self-reaction without supplying heat energy from the outside, wherein reaction heat, biogas (BIO GAS), and fermentation by-products This is recovered and recycled by each recovery unit and is excellent for sludge reduction and nitrogen removal.

In addition, the principle of the high temperature aerobic digestion tank itself maintains a temperature suitable for the activity of the high temperature microorganisms, and the chemical energy of the organic molecules is synthesized in the microorganisms in a high state, but most of the chemical energy is released to the surroundings as heat, compared to anaerobic digestion security against the organic loading and toxic substances, and maintains a low concentration of nitrogen because it is going through the nitrification processes wherein nitrogen is NH ₄ It is degassed in the state, and high organic load improves treatment efficiency, and the maximum organic load is 10% or less.

The sludge reduction by the high temperature aerobic digestion is made as shown in FIG. 5 and the principle of sludge reduction is the high concentration organic sludge in the high temperature aerobic digester is hydrolyzed by the hydrolysis enzyme from the metabolic process of the high temperature aerobic microorganism and converted into a small molecule form. The decomposed soluble organic material is oxidized by oxygen to form CO 2 and H 2 O.

The energy generated during the decomposition of organic matter in the high temperature aerobic digestion tank is multiplied by the microorganisms, but is mostly released to the outside, such as oxygen. The heat and oxygen are recaptured and introduced into the high temperature aerobic digester to perform a continuous process. In addition, when the organic material is not supplied from the outside, the microorganism oxidizes the organic material through internal respiration, and the mass of the sludge is reduced and thermal energy is generated through the synthesis, the exothermic reaction, and the internal respiration process.

On the other hand, the overall sludge reduction by the high temperature aerobic digestion tank of the present invention is the same as [organic sludge + O2 + microorganism + nutrients → byproduct + CO2 + H2O + NH4 ↑ + energy], the aerobic metabolic process of the microorganism is [C6H12O6 + O2 + NH3 → CO2 + 4H2O + C5H7O2N + energy], and the respiration process is also the same as [C5H7O2N + 5O2 → 5CO2 + 2H2 + NH3 ↑ + energy].

In addition, nitrogen removal by a high-temperature aerobic digestion tank is made as shown in Figure 6, the principle of nitrogen removal, in the high-temperature aerobic digestion tank ammonia stripping (Ammonia stripping) occurs because of the high temperature and the elevated pH inside the digester Therefore, the effect of nitrogen removal is excellent.

The ammonia stripping refers to a phenomenon in which dissolved NH4 + ammonium ions are converted to NH3 (ammonia) and degassed in a gaseous state depending on pH and temperature conditions. In this case, three factors of PH, temperature, and air injection amount are important. If the pH is low, NH3 + H2O → NH4 + OH-, if the PH is high, NH4 + → NH3 ↑ + H + reaction occurs.

Stabilizers are intended for the further treatment of residual organics and nutrients (nitrogen, phosphorus), cooling of ATAD treated water, stabilizing high temperature microorganisms and / or replacing microorganisms with common microorganisms, and entering the aeration / non-aeration cycles of stabilization tanks. Stable handling of load fluctuations, reduced chemical input and improved sludge settling, and maintenance costs (power costs) due to intermittent aeration are reduced.

Operation conditions of the stabilization tank, hydraulic retention time 1 day or more, SRT 10-20 days, MLSS 2,000 ~ 5,000 mg / l, aeration DO 2.0 mg / l or more, non-aeration DO 0.5 mg / l or less, aeration / non-aeration It is preferable to operate with a period of 40-50 / 10-20 minutes.

The sedimentation tank solid-separates the treatment liquid introduced from the stabilization tank and precipitates and discharges the sludge or is connected to the sewage treatment system. The purified water from the stabilization tank is transferred to the sedimentation tank, and the pure water is separated and discharged or sewage-linked, and some or all of the sludge precipitated by gravity is collected in the sludge accumulation device in the center of the sedimentation tank to drive the driving power of the sludge conveying pump. It is returned to the sludge digester through the return sludge inlet pipe, or discharged to the outside through the sludge reduction device such as a dewatering device.

The sludge digestion tank receives some or all of the sludge of the sedimentation tank and increases the methane spawn while fermenting methane to return to the anaerobic digestion tank. The sludge digestion tank decomposes the transported sludge by the microorganism and generates digestion gas as a by-product. As one or more than two, sludge flowing from the sedimentation tank is stabilized and reduced by gasification, liquefaction, and inorganicization under the action of anaerobic microorganisms.

More specifically, the sludge flowing into the sludge digestion tank may have a high nitrogen content and may serve as a nitrogen source for anaerobic bacteria during anaerobic digestion, and the sludge itself may be used as a spawn for anaerobic digestion.

That is, the sludge is mainly composed of aerobic bacteria or random bacteria (microorganisms that grow with or without oxygen), and by the anaerobic digestion without injecting air, random to anaerobic organic acids and methane bacteria are propagated. Done. The breeding process is a transition process of the ecosystem, when the anaerobic state is maintained, the appropriate anaerobic bacteria take advantage of the dominant species.

Looking at this process in detail, anaerobic digestion is caused by various kinds of bacteria, and is largely divided into organic acid bacteria and methane bacteria. Random to anaerobic organic acid bacteria decompose organic materials to produce organic acids and alcohols, in which small amounts of CO2, acetone, and H2 are generated. The organic acid is decomposed to generate gaseous substances such as CH 4 and CO 2, and NH 3, H 2 S, and mercaptan are also generated.

At this time, the proper activity of organic acid bacteria and methane bacteria is required, organic acid is produced by organic acid bacteria, and the organic acid is decomposed by methane bacteria to prevent the pH from dropping by the accumulation of organic acids, and the organic acid bacteria are used for In addition to producing it, it consumes oxides to produce reducing agents, creating a complete anaerobic state.

Therefore, the sludge becomes a dominant species of anaerobic microorganisms such as methane bacteria, so that anaerobic digestion occurs smoothly, and as a result, the generation of methane gas is increased, and methane is concentrated sludge supplied to the anaerobic digester, so the methane yield is improved. It will be.

Extinguishing gas generated in the sludge digestion tank has 60 to 70% of methane, 30 to 40% of carbon dioxide, and has a composition containing nitrogen, hydrogen, and hydrogen sulfide. At this time, the digestion gas, sulfuric acid gas, moisture, traces of harmful substances are contained, and the pollution load is high, so when used without purification, the calorific value is low, the toxicity is strong and severe odor is generated. Furthermore, it strongly corrodes iron, zinc, copper, etc. to corrode the mechanism of the cogeneration machine. Based on this problem, the sludge digestion tank is provided with a filter unit for removing non-combustible gas and harmful gas contained in the digested gas. By employing such a filter unit, it is possible to effectively remove the harmful gas and non-combustion gas contained in the extinguishing gas.

On the other hand, the organic waste treatment method of the improved methane yield of the organic waste treatment method, in the organic waste treatment method, pretreated food waste, sewage sludge, wastewater sludge, agricultural product waste, organic waste of livestock waste is introduced into the hydrolysis (polymeric organic material of An acid fermentation step in which the reaction of low molecular weight) and acid production (conversion of low molecular weight organic acid) occurs; A solid-liquid separation step for removing acid-fermenting microorganisms predominant in the acid fermentation step; An anaerobic digestion step of producing methane gas by digesting an organic material including acetic acid and alcohol generated in the acid fermentation step after the solid-liquid separation step; Maintaining 45 ℃ ~ 70 ℃ suitable for the activity of the medium, high temperature microorganism to the organic material that has undergone the anaerobic digestion step to decompose organic matter quickly, remove nitrogen by ammonia stripping without nitrification process and reduce sludge High temperature aerobic digestion step; High temperature aerobic digestion tank and operating conditions to further treat the remaining organic matter and nutrients (nitrogen, phosphorus) in the treatment liquid introduced from the high temperature aerobic digestion tank, cooling the ATAD treated water, stabilizing the high temperature microorganisms and / or microorganisms to replace the general microorganisms Stabilizing step of changing the sludge properties to a substrate suitable for the sludge digestion tank by different; A sludge settling step of solid-liquid separation of the treated liquid introduced through the stabilization step and settling and discharging the sludge or connected to the sewage treatment system; Sludge digestion step of increasing the methane spawn while methane fermentation of some or all of the sludge in the sludge precipitation step to return to the anaerobic digestion step.

In addition, the solid-liquid separation step is a flocculation reaction step to form a floc by injecting and stirring the flocculant in the acid slurry fermentation in the acid fermentation step, by diffusing fine bubbles in the waste slurry introduced in the flocculation reaction step It comprises a dissolved pressure flotation solid phase separation step to combine the flocs, microaggregates, microsolids to form a sludge layer on top and to remove the sludge layer with a scraper.

Hereinafter, the operation of each step is as described above, so detailed description thereof will be omitted.

Although the preferred embodiment of the present invention has been described in detail above, the scope of the present invention is not limited thereto, and may be implemented in various embodiments based on the basic concept of the present invention defined in the following claims. Such embodiments are also within the scope of the present invention.

Claims (10)

In organic waste treatment window, pretreated food waste, sewage sludge, wastewater sludge, agricultural waste, and organic waste of livestock waste are introduced to hydrolysis (low molecular weight of high molecular organic material) and acid production (conversion of low molecular weight organic acid) Acid fermentation tank occurs;
A solid-liquid separation tank for removing acid-fermented microorganisms predominant in the acid fermentation tank;
An anaerobic digestion tank connected to the solid-liquid separation tank and digesting organic matter including acetic acid and alcohol introduced therefrom to generate methane gas;
The organic material introduced from the anaerobic digester is maintained at 45 ° C. to 70 ° C., which is suitable for the activity of high temperature microorganisms, to quickly decompose the organic material, remove nitrogen by ammonia stripping, and reduce sludge without undergoing nitrification. Autothermal Thermophlic Aerobic Digestion (ATAD);
High temperature aerobic digestion tank and operating conditions to further treat the remaining organic matter and nutrients (nitrogen, phosphorus) in the treatment liquid introduced from the high temperature aerobic digestion tank, cooling the ATAD treated water, stabilizing the high temperature microorganisms and / or microorganisms to replace the general microorganisms Stabilizing tank for changing the sludge properties to a substrate suitable for the sludge digestion tank by different;
A settling tank which solid-separates the treated liquid introduced from the stabilization tank, precipitates and discharges the sludge or is connected to a sewage treatment system;
Sludge digestion tank to introduce a portion or all of the sludge of the sedimentation tank into the sludge digestion tank to multiply the methane spawn while fermenting methane and return to the anaerobic digestion tank to improve the methane yield of the anaerobic digestion tank. Organic waste treatment system with improved methane yield
The method of claim 1,
The solid-liquid separation tank is a flocculation reaction tank for adding flocculation chemicals to the acid slurry fermented in the acid fermentation tank and stirred to form flocs, and by spreading the microbubbles in the waste slurry introduced from the flocculation reaction tank, floc, fine aggregate, fine Methane yield improved organic characterized in that it comprises a dissolved pressure floating solid-liquid separation tank for generating a sludge layer on top of the solid material to remove the sludge layer with a scraper, and a micro-bubble generating device for generating the micro-bubbles Waste disposal equipment
The method according to claim 1 or 2,
The pH of the acid fermentation tank is 5 to 6, the organic waste treatment apparatus with improved methane yield, characterized in that the pH of the anaerobic digestion tank is maintained at 6.5 to 8
The method according to claim 1 or 2,
The high temperature aerobic digestion tank is installed to remove the volatile organic compounds (VOC) and volatile fatty acids (VFA) generated in the high temperature aerobic digestion tank during the decomposition process, the operating conditions are the temperature 45 ℃ ~ 70 ℃, air injection Methane yield improved organic waste treatment apparatus, characterized in that the conditions of maintaining the hydrogen ion concentration (PH) of the solution 7 ~ 8, DO concentration 0.2ppm or more
The method according to claim 1 or 2,
Operation conditions of the stabilization tank, hydraulic retention time 1 day or more, SRT 10-20 days, MLSS 2,000 ~ 5,000 mg / l, aeration DO 2.0 mg / l or more, non-aeration DO 0.5 mg / l or less, aeration / non-aeration Methane yield improved organic waste treatment apparatus characterized by operating at a cycle of 40 to 50/10 to 20 minutes
In organic waste treatment method, pretreated food waste, sewage sludge, wastewater sludge, agricultural waste, and organic waste of livestock waste are introduced to hydrolysis (low molecular weight of high molecular organic material) and acid production (conversion of low molecular weight organic acid) Acid fermentation step occurs;
A solid-liquid separation step for removing acid-fermenting microorganisms predominant in the acid fermentation step;
After the solid-liquid separation step, an anaerobic digestion step of producing methane gas by digesting an organic material including acetic acid and alcohol produced in the acid fermentation step;
Maintaining 45 ℃ ~ 70 ℃ suitable for the activity of the medium, high temperature microorganism to the organic material that has undergone the anaerobic digestion step to decompose organic matter quickly, remove nitrogen by ammonia stripping without nitrification process and reduce sludge High temperature aerobic digestion step;
High temperature aerobic digestion step to further treat the remaining organic matter and nutrients (nitrogen, phosphorus) in the treatment liquid introduced from the high temperature aerobic digestion step, ATAT treated water cooling, stabilization of high temperature microorganisms and / or microorganisms to replace the general microorganisms; A stabilization step of changing the sludge properties to a substrate suitable for the sludge digester by varying operating conditions;
A sludge settling step of solid-liquid separation of the treated liquid introduced through the stabilization step and settling and discharging the sludge or connected to the sewage treatment system;
The sludge digestion step of introducing a portion or all of the sludge in the sludge precipitation step to multiply the methane spawn while fermenting methane and return to the anaerobic digestion step to improve the methane yield of the anaerobic digestion step; Organic waste disposal method with improved methane yield
The method of claim 6,
The solid-liquid separation step is a flocculation reaction step for forming a floc by injecting and stirring the flocculant in the acid fermentation waste slurry in the acid fermentation step, floc by diffusing fine bubbles into the waste slurry introduced in the flocculation reaction step, Methane yield improved organic waste treatment method comprising a dissolved pressure flotation solid-liquid separation step to form a sludge layer on top by combining with the micro-agglomerate, fine solids, and remove the sludge layer with a scraper
The method according to claim 6 or 7,
The pH of the acid fermentation step is 5 to 6, the organic waste treatment method of methane yield improved, characterized in that the pH of the anaerobic digestion step is maintained at 6.5 to 8
The method according to claim 6 or 7,
The high temperature aerobic digestion step is to install a dust collector to remove volatile organic compounds (VOC) and volatile fatty acids (VFA) generated in the high temperature aerobic digestion tank during the decomposition process, the temperature of the aerobic digestion step temperature is 45 ℃ ~ Methane yield improved organic waste treatment method characterized by maintaining the conditions of 70 ℃, air injection, pH 7 ~ 8, DO concentration 0.2ppm or more of the solution
The method according to claim 6 or 7,
The conditions of the stabilization step, hydraulic retention time 1 day or more, SRT 10-20 days, MLSS 2,000 ~ 5,000 mg / l, aeration DO 2.0 mg / l or more, non-aeration DO 0.5 mg / l or less, aeration / non-aeration Methane yield improved organic waste treatment method characterized in that the cycle 40 ~ 50/10 ~ 20 minutes

Images