JP3193273B2 - How to use anaerobic digestion gas - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for utilizing anaerobic digestion gas generated in an anaerobic digestion tank or landfill.

[0002]

2. Description of the Related Art Anaerobic digestion gas generated by anaerobic digestion of sewage sludge and kitchen waste is generally methane 55-65.
%, 30 to 40% carbon dioxide, and 100 to several thousand ppm of hydrogen sulfide, and contains a large amount of combustible methane gas. Conventionally, this anaerobic digestion gas has been stored in a gas holder as it is and used as fuel for a boiler or the like. In recent years, gas engine power generation using this anaerobic digestion gas as an energy source has been attempted.

[0003] However it is required denitration equipment for removing NO _x in a gas engine power generation, maintains the gas engine is complicated, there are problems such that the noise and vibration generated. Therefore, the present inventors are developing a technology for generating power by a fuel cell using anaerobic digestion gas as fuel. In this case, the methane concentration in the fuel gas supplied to the fuel cell must be 90% or more, the carbon dioxide gas concentration must be 10% or less, and the hydrogen sulfide concentration must be 5 ppm or less.

As a method for increasing the methane concentration in the digested gas, there is a method in which carbon dioxide is separated by a membrane, and the collected carbon dioxide is recycled to the digestion tank. However, it is not easy to increase the methane concentration to 90% or more by this method.
In addition, there are cryogenic separation method and adsorption method as general methods for carbon dioxide gas separation, but all of them have the disadvantage that the equipment scale is large and the structure is complicated, and the adsorption method has low methane recovery rate. . Further, there is a dry method using iron oxide as a method for removing hydrogen sulfide, but there is a drawback that methane purification is impossible and power generation efficiency of the fuel cell cannot be improved.

As one method for solving the above-mentioned drawbacks, the present inventors desulfurize anaerobic digestion gas by bringing it into gas-liquid contact with alkaline treated water, increase the methane concentration, and increase the fuel concentration. A method for use as fuel for a battery has been developed and has already been proposed in Japanese Patent Application Laid-Open No. 7-996. However, in the method disclosed in this prior application, there are problems that neutral treated water cannot be used, power generation is not stable due to fluctuations in the composition of anaerobic digestion gas, and fluctuations in pH of treated water, fluctuations in water temperature, etc. As a result, the concentration of hydrogen sulfide in the fuel gas supplied to the fuel cell may exceed 5 ppm, and the problem of shortening the life of the fuel cell remains.

[0006]

SUMMARY OF THE INVENTION The present invention solves the above-mentioned conventional problems, enables stable power generation by a fuel cell using anaerobic digestion gas as a raw material, reduces running costs, and reduces the length of the fuel cell. The purpose of the present invention is to provide a method of using an anaerobic digestive gas that can extend the life.

[0007]

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems. The present invention relates to a method in which an anaerobic digestion gas is subjected to gas-liquid contact with a neutral or weakly alkaline liquid to carry out desulfurization and decarboxylation. It is characterized in that the methane concentration is increased by performing desulfurization and decarboxylation treatment by bringing it into gas-liquid contact with an alkaline liquid to use it as a fuel for a fuel cell.

As the neutral or weakly alkaline liquid, treated water having a pH of 6 or more and less than 10 obtained in a water treatment facility can be used. As the alkaline liquid, a pH of 10 or less can be used.
The above NaOH aqueous solution, KOH aqueous solution, Ca (OH) ₂ aqueous solution and the like can be used. In this desulfurization / decarboxylation treatment with a neutral or weakly alkaline liquid, it is preferable to remove 90% or more of the required amount of carbon dioxide gas removed. Also, while controlling the supply amount of alkali in the desulfurization / decarboxylation treatment with the alkaline liquid by the power generation amount of the fuel cell, or circulating and using a part of the wastewater in the desulfurization / decarboxylation treatment with the alkaline liquid, It is preferable to control the circulation amount by the pH of the drainage. As the anaerobic digestion gas, in addition to anaerobic digestion gas obtained by anaerobic digestion of sewage sludge and kitchen waste, gas generated in a landfill can also be used.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described below. FIG. 1 shows a first embodiment, in which 1 is a first-stage reaction tower using a neutral or weakly alkaline liquid,
Is a second-stage reaction tower using an alkaline liquid. These reaction towers 1 and 2 are used for gas-liquid contact of anaerobic digestion gas, and a packed tower, a tray tower, a bubble tower (aeration tank), a wet wall tower, and the like can be used. Most preferably, a packed tower packed with structures is used.

The anaerobic digestion gas is first sent to the lower part of the reaction tower 1 and comes into gas-liquid contact with the neutral or weakly alkaline liquid sprayed from the upper nozzle 3 in a counterflow. As mentioned above,
Methane 55 in anaerobic digestion gas generated from sewage treatment facilities
~ 65%, carbon dioxide gas 30 ~ 40%, hydrogen sulfide 100 ~ several 1000ppm
Although most of the carbon dioxide gas and hydrogen sulfide are dissolved in water and removed by the reaction tower 1 using the neutral or weakly alkaline liquid, the dust and suspended solids contained in the anaerobic digestion gas are contained. Material is also removed. While passing through the reaction tower 1, 90% of the required amount of carbon dioxide removed
The flow rate is adjusted so that the above can be eliminated. If treated water with a pH of 6 or more and less than 10 that is abundantly obtained in water treatment equipment as a neutral or weakly alkaline liquid,
Extremely economic processing is possible.

Next, the anaerobic digestion gas is sent to the reaction tower 2,
It comes into gas-liquid contact with the alkaline liquid sprayed from the nozzle 4 in a counterflow. Here, an alkaline liquid with a pH of 10 or more
NaOH aqueous solution is used. Hydrogen sulfide reacts with the alkali while passing through the reaction tower 2 made of the alkaline liquid and is almost completely removed, and its concentration is reduced to 5 ppm or less. Carbon dioxide gas is also removed until it becomes 10% or less, and the methane gas concentration becomes 90% or more. Thus, the gas having the increased methane concentration is sent to the fuel cell 5 and used as fuel for the fuel cell.

As described above, according to the present invention, the anaerobic digestion gas is subjected to desulfurization and decarboxylation by reaction with a neutral or weakly alkaline solution and an alkaline solution, and the methane concentration is 90% or more, and The fuel cell has a satisfactory property as a fuel for a fuel cell having a gas concentration of 10% or less and a hydrogen sulfide concentration of 5 ppm or less. As a result, the fuel cell 5 can be operated for a long time without deterioration.

FIG. 2 shows a preferred embodiment when the present invention is implemented in a water treatment facility. As shown in FIG. 2, the anaerobic digestion gas generated from the anaerobic digestion tank 7 is sent to the reaction tower 1 using a neutral or weakly alkaline liquid,
The treated water of the water treatment facility 6 is sprayed from the nozzle 3 as a neutral or weakly alkaline liquid. At this time, the wastewater discharged from the reaction tower 1 is returned to the raw water side of the water treatment facility 6.

The anaerobic digestion gas that has passed through the reaction tower 1 made of a neutral or weakly alkaline liquid is then sent to the reaction tower 2 made of an alkaline liquid. The nozzle 4 of the reaction tower 2 using the alkaline liquid is connected to an alkaline tank 8. An alkali is supplied to the alkali tank 8 together with the treated water of the water treatment facility 6. The gas whose methane concentration has been increased while passing through the reaction tower 2 made of an alkaline liquid is sent to the fuel cell 5 and used as fuel for the fuel cell, and the hot water generated at that time is heated in the anaerobic digestion tank 7. Used for The wastewater discharged from the reaction tower 2 by the alkaline liquid is also returned to the raw water side of the water treatment facility 6. As described above, when the present invention is implemented in combination with the water treatment facility 6, desulfurization using a neutral or weakly alkaline liquid is performed.
Inexpensive treated water of the water treatment facility 6 can be used for the decarbonation treatment, and running costs can be reduced.

FIG. 3 shows a third embodiment of the present invention. In FIG. 3, a part of the effluent of the reaction tower 2 using the alkaline liquid is circulated and used, and the amount of alkali supplied to the recirculated liquid is controlled by the amount of power generated by the fuel cell 5. That is, since the amount of power generated by the fuel cell 5 changes depending on the methane concentration in the gas supplied to the fuel cell 5, when the amount of power generation decreases, the supply of alkali is increased to increase the methane concentration. The amount can be undone. Conversely, when the amount of power generation increases, the amount of power generation can be restored by reducing the supply amount of alkali to lower the methane concentration. As a result, it is possible to secure a stable power generation amount regardless of the composition fluctuation of the anaerobic digestion gas and the composition fluctuation of the reaction tower 1 outlet gas. At the same time, the circulation amount of the alkaline liquid in the reaction tower 2 can be controlled by the pH of the discharged liquid.

As described above, according to the present invention, stable power generation by a fuel cell using anaerobic digestion gas as a raw material is possible, and running cost can be reduced and fuel cell life can be extended. The number of reaction towers is not necessarily limited to two.

[0017]

EXAMPLES Next, examples in which the present invention is implemented on a laboratory scale will be described. SUS304 in a column with a diameter of 300 mm and a packing height of 1200 mm
The reactors filled with the packing material are connected in series as reaction towers 1 and 2, and 5 m ³ / h of working water is supplied to the reaction tower 1.
Is a 0.2 m ³ / h NaOH aqueous solution (NaOH supply: 44.5 g-NaOH /
h) was supplied. An anaerobic digestion gas as shown in Table 1 was supplied to this apparatus, and gas compositions at the outlet of the reaction tower 1 and the outlet of the reaction tower 2 were measured.

[0018]

[Table 1]

As shown in Table 1, by supplying 33 g or more of NaOH per 1 Nm ^{3 of} the processing gas, the gas can be purified into a gas having a property that can be supplied to the fuel cell, and the present invention can be applied to actual equipment in terms of cost. It was confirmed that. In this example, it was confirmed that hydrogen sulfide could be removed to 0.2 ppm or less. In addition, in order to remove all the carbon dioxide gas removed in this example by reacting with NaOH, the processing gas amount is 1.
12 nm ³ / NaOH in 609g-NaOH / Nm ³ when h is required, as well as the process gas quantity ^{1.35Nm 3 / h 618g-NaOH /} Nm 3 of NaOH when
There, 556g-NaOH / Nm ³ of NaOH when the process gas volume 1.55 nm ³ / h
Is required. Therefore, the NaOH input amounts in this example were 39.7 / 609 = 6.5%, 33.0 / 618 = 5.3%, and 28.7 / 5, respectively.
56 = 5.2%, and the NaOH input amount was 5
It was confirmed that it could be reduced to ６6%.

[0020]

As described above, according to the present invention, stable power generation by a fuel cell is possible using anaerobic digestion gas generated in an anaerobic digestion tank or landfill as a raw material. In addition, since the running cost can be reduced and the life of the fuel cell can be prolonged, the practical value is high from an economic viewpoint.

[Brief description of the drawings]

FIG. 1 is a flow sheet showing a first embodiment of the present invention.

FIG. 2 is a flow sheet showing a second embodiment of the present invention.

FIG. 3 is a flow sheet showing a third embodiment of the present invention.

[Explanation of symbols]

1 reaction tower with neutral or weakly alkaline liquid, 2 reaction tower with alkaline liquid, 3 nozzles, 4 nozzles,
5 fuel cell, 6 water treatment equipment, 7 anaerobic digester, 8
Alkaline tank

Continuation of front page (56) References JP-A-56-161896 (JP, A) JP-A-5-68849 (JP, A) JP-A-4-177013 (JP, A) JP-A-5-345200 (JP) , A) JP-A-7-996 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) C02F 11/04

Claims (5)

(57) [Claims] An anaerobic digestion gas is subjected to desulfurization / decarboxylation treatment by bringing it into gas-liquid contact with a neutral or weakly alkaline liquid, and then is brought into gas-liquid contact with an alkaline liquid to carry out desulfurization / decarboxylation treatment. The use of anaerobic digestion gas, characterized in that the methane concentration is increased by using the anaerobic digestion gas. 2. The method for utilizing anaerobic digestion gas according to claim 1, wherein treated water obtained in a water treatment facility is used as a neutral or weakly alkaline liquid. 3. In a desulfurization / decarboxylation treatment with a neutral or weakly alkaline liquid, the required amount of carbon dioxide gas removed is 90%.
The use of the anaerobic digestion gas according to claim 1, wherein the anaerobic digestion gas is removed. 4. The method of using an anaerobic digestion gas according to claim 1, wherein in the desulfurization / decarboxylation treatment with the alkaline liquid, the supply amount of the alkali is controlled by the power generation amount of the fuel cell. 5. The anaerobic digestion gas according to claim 1, wherein a part of the effluent is circulated and used in the desulfurization and decarboxylation treatment with the alkaline liquid, and the circulating amount is controlled by the pH of the effluent. How to Use.