JP2016030248A - Exhaust gas treatment method, and exhaust gas treatment equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an exhaust gas treatment method and an exhaust gas treatment equipment for wet-cleaning an exhaust gas to be produced at an incineration time of an organic combustible and for clarifying the adverse containing waste water produced by the wet cleaning, by a biological treatment, thereby to produce grease as a by-product.SOLUTION: An exhaust gas to be generated at the burning timing of an organic waste is sprayed with water or sea water into adverse containing waste water thereby to cultivate heterotrophic algae employing said adverse containing waste water as a nutrient source, and said adverse containing waste water is clarified by the biological treatment of said heterotrophic algae thereby to solid-liquid separate and recover said heterotrophic algae stored with fat in the bacterial cell, by said cultivation.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an exhaust gas treatment method and an exhaust gas treatment apparatus that wet-cleans exhaust gas generated during incineration of organic combustibles, purifies harmful substance-containing wastewater generated by wet cleaning by biological treatment, and produces fats and oils as by-products. About.

  Exhaust gas generated when combusting organic combustibles such as municipal waste and sewage sludge contains harmful substances such as dust, sulfur oxide, chlorine oxide, and nitrogen oxide. However, there is currently no universal treatment method that can efficiently remove these harmful substances at once, such as bag filters, electrostatic precipitators for removing soot dust, and wet methods for removing sulfur oxides and chlorine oxides. A cleaning device (wet scrubber) and a dry denitration device for removing nitrogen oxides are connected in series to purify the exhaust gas.

The exhaust gas contains ammonia and cyanide together with nitrogen oxides. In particular, when the combustion air is insufficient or when the air and sludge are not sufficiently mixed, ammonia and cyan are contained in the exhaust gas at a high concentration due to insufficient oxygen. In the wet cleaning apparatus provided in the front stage of the exhaust gas treatment apparatus, ammonia, cyanide, and nitrogen peroxide are dissolved in water to form harmful substance-containing wastewater, and N ₂ O does not dissolve in water, and therefore passes through the wet cleaning apparatus. N ₂ O is removed by a dry denitration apparatus using a catalytic reaction, which is installed at the subsequent stage of the exhaust gas treatment apparatus. Patent Documents 1 and 2 disclose inventions related to dry denitration of N ₂ O.

  On the other hand, the hazardous substance-containing wastewater containing ammonia, cyanide, and nitrogen peroxide is purified by chemical treatment or biological treatment. Patent Document 3 discloses a scrubber wastewater treatment method in which scrubber wastewater discharged from a scrubber that performs wet treatment of incinerator exhaust gas is oxidized using manganese dioxide as a catalyst in the presence of an oxidizing agent in the range of pH 5-10. Has been.

Japanese Patent Laid-Open No. 10-128065 JP 2009-183827 A JP-A-11-165180

  However, with regard to the wastewater treatment of the harmful substance-containing wastewater, for example, in the chemical treatment described in Patent Document 3, it is necessary to input an oxidizing agent such as sodium hypochlorite, potassium permanganate, or ozone, and the environment. It is not preferable to comprehensively determine the impact on the environment. On the other hand, in the conventional biological treatment, activated sludge is generated as a by-product, but this activated sludge has little value for reuse, and eventually it is incinerated, which has become an uneconomical exhaust gas treatment method.

  Therefore, an object of the present invention is to exhaust gas generated at the time of incineration of organic combustible materials, and to purify harmful waste water generated by wet cleaning by biological treatment to produce fats and oils as a by-product. And providing an exhaust gas treatment apparatus.

  In order to achieve the above object, the exhaust gas treatment method of the present invention removes the exhaust gas generated during the incineration of the organic combustible material by bringing water or sea water into contact with the exhaust gas and dissolving the harmful substances in the exhaust gas in the water or sea water. By cultivating heterotrophic algae having the ability to produce and accumulate fats and oils using the harmful substance-containing wastewater obtained as a nutrient source, the harmful substance-containing wastewater is purified, and the fats and oils are stored in the cells by the culture. In addition, the heterotrophic algae are recovered by solid-liquid separation.

  Moreover, the exhaust gas treatment method of the present invention can further collect the fats and oils from the heterotrophic algae subjected to the solid-liquid separation.

  In the exhaust gas treatment method of the present invention, it is preferable that the heterotrophic algae is one or a plurality selected from the genus Aurantiochytrium, Pariechichytrium, Schizochytrium, and Throstochytrium.

  In the exhaust gas treatment method of the present invention, the heterotrophic algae is preferably cultured by adjusting the pH of the harmful substance-containing wastewater to be 4 to 8.

  In the exhaust gas treatment method of the present invention, the heterotrophic algae is preferably cultured by adding organic waste water so that the C / N ratio of the harmful substance-containing waste water is 1 to 40.

  The exhaust gas treatment apparatus of the present invention is a wet cleaning apparatus for bringing water or seawater into contact with exhaust gas generated during incineration of an organic combustible material, and dissolving and removing harmful substances in the exhaust gas in water or seawater, and the wet process A wastewater treatment tank for purifying the wastewater containing harmful substances by culturing heterotrophic algae having the ability to produce and accumulate fats and oils, using the wastewater containing harmful substances obtained by the cleaning device as a nutrient source, And a solid-liquid separator for collecting heterotrophic algae in which oil and fat are accumulated.

  The exhaust gas treatment apparatus of the present invention can further include an oil and fat recovery device that recovers the oil and fat from the heterotrophic algae that have accumulated the oil and fat.

  The waste water treatment tank of the exhaust gas treatment apparatus of the present invention can include a hydrogen ion concentration meter and a pH adjustment device that supplies a pH adjusting agent according to the pH required by the hydrogen ion concentration meter.

  The waste water treatment tank of the exhaust gas treatment apparatus of the present invention can include an organic waste water supply device for adjusting the C / N ratio.

  According to the present invention, exhaust gas generated during incineration of organic combustibles can be wet-cleaned, and harmful substance-containing wastewater generated by wet cleaning can be purified by biological treatment to produce fats and oils as by-products.

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

  First, the heterotrophic algae having the ability to produce and accumulate fats and oils used for biological treatment of wastewater containing harmful substances in the present invention will be described.

  The heterotrophic algae according to the present invention can grow organic compounds in water as nutrients without photosynthesis, efficiently produce fats and oils, and accumulate them in the cells. Specifically, a microorganism belonging to the genus Aurantiochytrium, a microorganism belonging to the genus Parietichytrium, a microorganism belonging to the genus Schizochytrium, and a microorganism belonging to the genus Thraustochytrium. One kind or a plurality of kinds can be used.

  The heterotrophic algae listed here can be cultured in fresh water, but all are halophilic and can grow even at a salt concentration of 6%. Since the salt concentration of seawater is 3 to 3.5%, seawater can be used as a culture solution.

  The microorganisms belonging to the genus Aurantiochytrium are inferior in the ability of degrading starch, cellulose and protein in the enumeration, but doubled in 2 to 6 hours on LB medium containing 50% artificial seawater. The growth rate is prominent.

  Here, “artificial seawater” means sodium chloride 3.0 w / v%, potassium chloride 0.07 w / v%, magnesium chloride 1.08 w / v%, magnesium sulfate 0.54 w / v%, calcium chloride 0. An aqueous solution having a composition of 1 w / v%.

  Microorganisms belonging to the genus Aurantiochytrium may be cultured alone, but when cultured with microorganisms that secrete amylase, cellulase, protease, etc., decomposition of organic compounds in water is promoted by the enzymes, and oils and fats are highly efficient. Can be produced. On the other hand, microorganisms belonging to the genus Aurantiochytrium have a cell wall thickness as thin as 2 to 3 μm with respect to the cell size of 30 to 100 μm. For example, the cell wall can be broken by pressing to extract oils and fats. Oils and fats can be efficiently recovered at low cost by the extraction method. As strains, for example, Aurantiochytrium NBRC102614, NBRC103268, NBRC103269, etc. can be used (the strains with the NBRC number can be sold from the National Institute of Technology and Evaluation Technology. The same). Among these, auranthiochytrium NBRC102614 is particularly preferable in the exhaust gas treatment method of the present invention because it has a short doubling time and a high fat content.

  Microorganisms belonging to the genus Pariechititrium secrete enzymes that degrade proteins, starches, and cellulose, and can degrade organic compounds in water. However, the doubling time in the above medium is 3 to 8 hours, and the growth rate is inferior to that of Aurantiochytrium. The cell wall thickness is as thin as 2 to 3 μm with respect to the cell size of 20 to 30 μm, and the oil can be easily recovered by the same method as described above. Examples of strains that can be used include pariechichytrium NBRC104108 and NBRC102984.

  Microorganisms belonging to the genus Schizochytrium are capable of secreting enzymes such as amylase, cellulase and protease to decompose organic compounds in water, and are particularly excellent in the decomposition of starch. However, the doubling rate in the above medium is as slow as 8-24 hours. The cell wall thickness is as thin as 4 to 6 μm with respect to the cell size of 20 to 30 μm, and the oil and fat can be easily recovered by the same method as described above. As strains, Schizochytrium ATCC20888, ATCC20889, ATCC28209 (the strains numbered ATCC can be sold from the American Type Culture Collection. The same applies below), or MYA-1391 (also from ATCC) Can be used).

  Microorganisms belonging to the genus Throstochytrium are capable of secreting enzymes such as amylase, cellulase and protease to degrade organic compounds in water, and are particularly excellent in protein degradation. However, the doubling rate in the above medium is very slow at 24 hours. The cell size is 30 to 100 μm, and the cell wall thickness is 20 to 30 μm. Extraction of fats and oils requires extraction with an organic solvent after crushing the cells. As the strain, Throstochytrium ATCC18907, ATCC20890, ATCC20891, ATCC20892, ATCC24473, ATCC26185, ATCC28210, ATCC34304 and the like can be used.

  Next, the exhaust gas treatment apparatus of the present invention will be described in detail below with reference to FIG.

  The exhaust gas treatment apparatus of the present invention shown in FIG. 1 obtains waste water containing harmful substances by bringing water or seawater into contact with an incinerator 1 for incinerating organic combustibles and exhaust gas discharged from the incinerator 1. A wet cleaning apparatus 2 for cultivating heterotrophic algae using the harmful substance-containing wastewater as a nutrient source, and a wastewater treatment tank 3 for purifying the harmful substance-containing wastewater by biological treatment of the heterotrophic algae, The solid-liquid separation device 4 collects heterotrophic algae that have accumulated fats and oils in the cells by the culture. The waste water treatment tank 3 is provided with a hydrogen ion concentration meter 5 and a pH adjusting device 6 for supplying a pH adjusting agent according to the pH required by the hydrogen ion concentration meter 5. The wastewater treatment tank 3 is connected with an organic wastewater supply device 7 for supplying organic wastewater to adjust the C / N ratio. The wastewater treatment tank 3 is connected to an algal culture tank 9 for introducing the heterotrophic algae. The solid-liquid separation device 4 is provided with an oil and fat recovery device 8 for recovering oil and fat from the heterotrophic algae recovered as a solid content. Although not shown, a C / N ratio analyzer can be attached to measure the C / N ratio.

  The above is a description of the equipment configuration of the exhaust gas treatment apparatus that can cope with process fluctuations. However, when the process is stable, some equipment can be omitted and operated.

  For example, if there is no change in the composition of the organic combustible material to be incinerated in the incinerator 1 and the treatment amount is constant, the pH of the waste water containing harmful substances discharged from the wet cleaning device 2 and supplied to the waste water treatment tank 3 will be described. Therefore, the hydrogen ion concentration meter 5 and the pH adjusting device 6 may be omitted, and the pH may be manually adjusted as necessary.

  If the cleaning liquid used in the wet cleaning apparatus 2 contains an organic compound and the C / N ratio required for the growth of heterotrophic algae is secured, the organic waste water supply apparatus 7 is omitted. be able to.

  Further, the oil and fat recovery device 8 is not necessarily installed in the same site as the solid-liquid separation device 4. For example, the oil-and-fat recovery apparatus 8 can be made independent and installed in another place, and sludge containing heterotrophic algae separated by solid-liquid can be transported to and processed there.

  Hereinafter, details of each device used in the exhaust gas treatment device of the present invention will be described.

  In FIG. 1, the incinerator 1 used in the wastewater treatment facility of the present invention is not particularly limited, and is an incinerator for municipal waste recovered by a local government, an industrial waste incinerator, and an activated sludge incinerator in a sewage treatment plant. It may be a waste gas combustion furnace, an ore roasting furnace, a blast furnace, a cement firing kiln, a thermal power plant boiler, a ship boiler, etc. of a petrochemical plant.

  The wet cleaning apparatus 2 used in the exhaust gas treatment apparatus of the present invention is not particularly limited, and a spray tower, a packed tower, a bubbling tower, a venturi scrubber, a cyclone, or the like can be used. As the cleaning liquid, fresh water is usually used, but seawater may be used. Moreover, in order to improve the absorption efficiency of the harmful substance contained in the exhaust gas, a neutralizing agent or an absorbent can be mixed. For example, when the wet cleaning device 2 is used as a cleaning device for flue gas desulfurization, a limestone slurry in which limestone powder is suspended in water is used, and sulfate ions are solid-liquid separated as gypsum, The supernatant liquid can be sent to the wastewater treatment tank 3 as wastewater containing harmful substances to be biologically treated.

  The waste water treatment tank 3 used in the exhaust gas treatment apparatus of the present invention is not particularly limited, and a water tank or tank having an air diffusion mechanism called an aeration tank can be used. Since the heterotrophic algae belonging to the genus Aurantiochytrium, Pariechichytrium, Schizochytrium, and Throstochytrium used for wastewater treatment in the present invention are aerobic, air or oxygen is diffused in the liquid. In addition, the microorganisms can be activated to biologically treat the harmful substance-containing wastewater.

  The aeration tank may be used as a single tank, but a multistage continuous tank type in which a plurality of aeration tanks are connected in series can also be adopted. In the continuous operation in a single tank, since the inside of the tank is in a completely mixed state, a part of the harmful substances is mixed with the purified water and discharged, so the purification efficiency is not high. If the multistage continuous tank type is adopted, the content of harmful substances can be reduced stepwise to obtain purified water with a high degree of purification.

  The waste water treatment of the present invention may be an oxidation ditch method. In this case, according to the oxidation ditch method using an oblong, circular or horseshoe-shaped circulation channel equipped with a rotor as the wastewater treatment tank 3, stable wastewater treatment is performed even when the amount of inflow water varies. Can do.

  The solid-liquid separation apparatus 4 used in the exhaust gas treatment apparatus of the present invention is not particularly limited, and uses a cross-flow type precipitation tank, a center drive circular precipitation tank, a circulation type precipitation tank, an inclined plate precipitation tank, and a high-speed pressurized levitation tank. be able to.

  The solid-liquid separation device 4 used in the exhaust gas treatment apparatus of the present invention further includes a dehydrator for dehydrating heterotrophic algae flocs and a dryer for drying the dehydrated heterotrophic algae cake. Can be provided. The dehydrator is not particularly limited, and a vacuum filter, a centrifugal dehydrator, a belt press, a screw press, or the like can be used. The dryer is not particularly limited, and a belt type hot air dryer or the like can be used.

  As the hydrogen ion concentration meter 5 used in the exhaust gas treatment apparatus of the present invention, a commercially available electronic type can be used.

  The pH adjuster 6 used in the exhaust gas treatment apparatus of the present invention is a tank that stores a pH adjuster, and can open and close the valve V1 automatically or manually and pour the pH adjuster into the wastewater treatment tank 3. . As the acidic pH adjusting agent, sulfuric acid, hydrochloric acid, phosphoric acid, acetic acid, nitric acid and the like can be used, and as the alkaline pH adjusting agent, sodium hydroxide, calcium hydroxide, ammonia, sea water and the like can be used.

  The organic waste water supply device 7 used in the exhaust gas treatment apparatus of the present invention is a water tank or tank for storing organic waste water, and opens or closes the valve V2 automatically or manually, and the organic waste water is supplied to the waste water treatment tank 3. Can pour. The organic waste water is not particularly limited, and sewage, industrial waste water, an artificially prepared culture solution, or the like can be used.

  The oil and fat recovery device 8 used in the exhaust gas treatment device of the present invention is not particularly limited, and is a combination of a device that breaks the cell walls of heterotrophic algae, an oil and fat extraction device that uses an extraction solvent, and a solid-liquid separation device. An oil and fat recovery device can be used. In order to destroy the cell walls of heterotrophic algae, a pulverizer such as an ultrasonic crusher or dynomill, or a stirred tank reactor for chemical decomposition using a chemical can be used. For oil and fat extraction, it is possible to use a stirred tank type extraction device for kneading the crushed heterotrophic algae and the extraction solvent, or an extraction tower for extracting the crushed heterotrophic algae through the extraction solvent. it can. A vacuum filter, a centrifuge, and a precipitation tank can be used for solid-liquid separation of the extraction residue and the extract.

  The algal culture tank 9 used in the exhaust gas treatment apparatus of the present invention is a culture tank for appropriately supplying heterotrophic algae to the wastewater treatment tank 3, and is always adjusted to culture conditions suitable for the growth of heterotrophic algae. It is preferable that

  Heterotrophic algae belonging to the genus Aurantiochytrium, Pariechichytrium, Schizochytrium, and Throstochytrium used for the exhaust gas treatment of the present invention have a thin cell wall, so the cell wall destruction step is omitted and the permeability is high. Direct extraction can also be performed using an extraction solvent containing a nonpolar organic solvent. In this method, the oil recovery device 8 does not include a cell wall destruction device.

  In addition to the above-described apparatus, the oil and fat recovery apparatus 8 used in the exhaust gas treatment apparatus of the present invention is provided with an oil / water separator, an evaporation concentrator, and a distillation tower in order to remove moisture or an organic solvent from the extract. can do.

  In the present invention, the C / N ratio analysis performed for determining the mixing ratio of harmful substance-containing wastewater and organic wastewater is not particularly limited. For example, a carbon and nitrogen simultaneous quantification apparatus based on the Pregl-Dumas method as a basic principle. Can be used.

  Hereinafter, the exhaust gas treatment method of the present invention will be described with reference to FIG.

  As described above, the incinerator 1 is not particularly limited, and is an incinerator for municipal waste collected by the local government, an incinerator for industrial waste, an incinerator for activated sludge in a sewage treatment plant, and a waste gas combustion furnace for a petrochemical plant. Ore roasting furnaces, blast furnaces, cement firing kilns, thermal power plant boilers, ship boilers, etc. Therefore, there are various organic wastes incinerated there, but the exhaust gas discharged from the incinerator 1 is nitrogen In addition to carbon dioxide, water, oxygen, harmful substances such as nitrogen oxides, cyanides, ammonia, sulfur oxides, organic chlorine compounds, and unburned organic compounds are contained.

  In the exhaust gas treatment method of the present invention, the exhaust gas that is discharged from the incinerator 1 and contains the harmful substances comes into contact with water or seawater in the wet cleaning apparatus 2, and the harmful substances dissolve in the water or seawater to become harmful substance-containing wastewater. The purified exhaust gas is released into the atmosphere.

  The wastewater-containing tank 3 is supplied with the toxic substance-containing wastewater from the wet cleaning device 2, and can further add organic wastewater from the organic wastewater supply device 7. The waste water treatment tank 3 is exploded by air or oxygen, and heterotrophic algae are cultured. Heterotrophic algae grow with nitrogen compounds and organic substances contained in harmful substance-containing wastewater and organic wastewater as nutrient sources, and purify wastewater mixed with harmful substance-containing wastewater and organic wastewater by biological treatment. At the same time, the heterotrophic algae accumulate fats and oils in the cells.

  The purified waste water from the waste water treatment tank 3 is sent to the solid-liquid separator 4 and separated into purified water and heterotrophic algal frogs by precipitation or flotation separation. The purified water is discharged into the river, and the heterotrophic algal frog is returned to the waste water treatment tank 3.

  In the exhaust gas treatment method of the present invention, the frog of heterotrophic algae separated by the solid-liquid separator 4 can be dehydrated and supplied to the oil recovery device 8. The extraction of the heterotrophic algae from the frog solid-liquid separation device 4 may be performed continuously, but the growth status of the heterotrophic algae in the waste water treatment tank 3 and the accumulation status of the fats and oils of the heterotrophic algae are observed. It can also be performed intermittently.

  Moreover, the said dehydration process is performed in order to reduce conveyance cost and the driving | running load in the oil-fat collection | recovery apparatus 8, and the dehydration method by vacuum filtration, centrifugal dehydration, a belt press, or a screw press can be applied. Further, the dehydrated heterotrophic algal cake may be sun dried or hot air dried.

  In the oil and fat recovery device 8, after destroying the cell wall of heterotrophic algae, the oil and fat can be extracted using an extraction solvent, and solid-liquid separated into an extract and a residue, and the oil and fat can be recovered as an extract.

  In another embodiment, the cell wall disrupting step may be omitted, and a dry cake of heterotrophic algae may be directly extracted by contacting an extraction solvent containing a highly permeable nonpolar organic solvent. As the nonpolar organic solvent, one or more selected from the group consisting of normal hexane, benzene, toluene, dimethyl ether, and diethyl ether can be used.

  The recovered extract can be separated from water and solvent, and oil and fat can be purified by oil / water separation, evaporation and distillation.

  Next, the operating conditions of the wastewater treatment tank 3 will be described in more detail.

  In the exhaust gas treatment method of the present invention, one or a plurality of heterotrophic algae selected from the genus Aurantiochytrium, Pariechichytrium, Schizochytrium, and Sustochytrium can be used. The heterotrophic algae listed here are preferably cultured in an environment of pH 4-8 in the wastewater treatment tank 3, and more preferably cultured in an environment of pH 5-7. When the pH is less than 4, it is not preferable because the growth of algae is inhibited. When the pH is higher than 8, it is not preferable because the fats and oils of the algae are saponified.

  For this reason, it is preferable to install the hydrogen ion concentration meter 5 in the waste water treatment tank 3 and supply the pH adjusting agent from the pH adjusting device 6 according to the pH required by the hydrogen ion concentration meter. The pH measurement and pH adjustment may be performed manually or automatically. When the processing amount and composition of the organic combustible material incinerated by the incinerator 1 vary, the pH of the hazardous material-containing wastewater also varies. The organic waste water supplied from the organic waste water supply device 7 may also vary due to various factors. However, if the pH adjustment of the waste water treatment tank 3 is automatically controlled, the biological treatment can be stabilized regardless of the load fluctuation upstream of the waste water treatment tank 3.

  In the exhaust gas treatment method of the present invention, the C / N ratio of the liquid in the wastewater treatment tank 3 is preferably 1 to 40, and more preferably 10 to 30. If the C / N ratio is less than 1, the algae tends to proliferate and does not produce fats and oils, and is not preferable. If the ratio is higher than 40, the algae do not grow, so the number of fungi containing oils and fats does not increase. It is not preferable. Therefore, the C / N ratio can be adjusted by adding organic wastewater from the organic wastewater supply device 7 to the hazardous substance-containing wastewater supplied from the wet cleaning device 2. The C / N ratio can be measured, for example, by a carbon and nitrogen simultaneous quantification apparatus based on the Pregl-Dumas method as a basic principle. Therefore, the C / N ratio can be regularly monitored and adjusted by adding organic waste water as necessary.

  In the exhaust gas treatment method of the present invention, the water temperature of the waste water treatment tank 3 is preferably 15 to 40 ° C, and more preferably 20 to 35 ° C. If the water temperature is less than 15 ° C., the activity of the algae is remarkably reduced, and if it is higher than 40 ° C., the algae die. If necessary, the water temperature of the waste water treatment tank 3 may be adjusted by heating with a heater.

  In the exhaust gas treatment method of the present invention, the dissolved oxygen concentration in the waste water treatment tank 3 is preferably 1 mg / L to 7 mg / L, and more preferably 2 mg / L to 4 mg / L. If the dissolved oxygen concentration is less than 1 mg / L, the growth rate of algae and the amount of oils and fats produced are not preferred, and if it is greater than 7 mg / L, the aeration power increases, which is not preferred.

  In the exhaust gas treatment method of the present invention, the salinity concentration of the waste water treatment tank 3 is preferably 0.1% to 6.0%, and more preferably 1.0% to 4.0%. If the salt concentration is less than 0.1%, the nutrient salt is insufficient and the algae cannot grow, which is not preferable. If the salt concentration is more than 6.0%, the osmotic pressure of the culture solution becomes high and the growth of the algae is inhibited. Absent. If necessary, the salt concentration of the waste water treatment tank 3 may be adjusted by adding fresh water or seawater.

  In the exhaust gas treatment method of the present invention, trace nutrients, vitamins and the like can be further added to the wastewater treatment tank 3 in order to increase the growth of heterotrophic algae and / or the oil production capacity.

  Embodiments of the present invention will be described in detail below.

  Artificial seawater (sodium chloride 3.0 w / v%, potassium chloride 0.07 w / v%, magnesium chloride 1.08 w / v%, magnesium sulfate 0.54 w / v%, calcium chloride 0.1 w / v%) is pure 1 ml of culture solution was prepared by adding 100 ml of artificial sewage (BOD 1000 mg / L, TN 50 mg / L) to 900 ml of artificial scrubber wastewater containing 20 mg / L of sodium nitrite in 50% artificial seawater diluted with water.

Auranthiochitrium (strain name NBRC102614) is added to the culture solution so that OD ₆₀₀ (absorbance 600 nm) is 0.2, under conditions of a liquid temperature of 30 ° C., an aeration amount of 250 ml / min, and a stirring speed of 150 rpm. Cultured for 24 hours. Aulanthiochytrium increased to 2 g / L by culture.

  Next, the culture solution was centrifuged to separate it into a culture solid (precipitate) and purified water (supernatant).

  After 10 ml of hexane was added to the cultured solid and stirred, the supernatant was collected by centrifugation and kept at 70 ° C. for 2 hours to evaporate hexane to obtain 0.5 g of oil.

  On the other hand, the purified water was chemically analyzed, and it was confirmed that BOD was reduced to 5 mg / L and NOx 2 mg / L.

1: Incinerator 2: Wet cleaning device 3: Waste water treatment tank 4: Solid-liquid separation device 5: Hydrogen ion concentration meter 6: pH adjustment device 7: Organic waste water supply device 8: Oil and fat recovery device 9: Algae culture tank V1, V2, V3: Valve

Claims (9)

Contacting water or seawater with the exhaust gas generated during the incineration of organic combustible materials, dissolving and removing harmful substances in the exhaust gas in water or seawater,
Using the harmful substance-containing wastewater obtained thereby as a nutrient source, purifying the harmful substance-containing wastewater by culturing heterotrophic algae having the ability to produce and accumulate fats and oils,
A method for treating exhaust gas, comprising solid-liquid separation and recovery of the heterotrophic algae in which fats and oils are stored in the cells by the culture.   The exhaust gas treatment method according to claim 1, wherein the oil and fat is further recovered from the heterotrophic algae subjected to the solid-liquid separation.   The exhaust gas treatment method according to claim 1 or 2, wherein the heterotrophic algae is one or a plurality selected from the genus Aurantiochytrium, Pariechichytrium, Schizochytrium, and Throstochytrium.   The exhaust gas treatment method according to any one of claims 1 to 3, wherein the heterotrophic algae is cultured by adjusting the pH of the harmful substance-containing wastewater to be 4 to 8.   The exhaust gas treatment according to any one of claims 1 to 4, wherein the heterotrophic algae is cultured by adding organic wastewater so that the C / N ratio of the wastewater containing harmful substances is 1 to 40. Method. A wet cleaning device for bringing water or seawater into contact with exhaust gas generated during incineration of organic combustibles and dissolving and removing harmful substances in the exhaust gas in water or seawater; and
A wastewater treatment tank for purifying the harmful substance-containing wastewater by culturing heterotrophic algae having the ability to produce and accumulate fats and oils, using the harmful substance-containing wastewater obtained by the wet cleaning apparatus as a nutrient source,
An exhaust gas treatment apparatus comprising a solid-liquid separation device that collects heterotrophic algae in which fats and oils are accumulated in the cells by the culture.   The exhaust gas treatment apparatus according to claim 6, further comprising an oil and fat recovery device that recovers the oil and fat from the heterotrophic algae that have accumulated the oil and fat.   The exhaust gas treatment apparatus according to claim 6 or 7, wherein the waste water treatment tank includes a hydrogen ion concentration meter and a pH adjustment device that supplies a pH adjusting agent according to a pH determined by the hydrogen ion concentration meter.   The exhaust water treatment apparatus according to any one of claims 6 to 8, wherein the waste water treatment tank includes an organic waste water supply apparatus for adjusting a C / N ratio.