JP2003073680A - Desulfurization apparatus for methane fermentation gas of organic waste - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a desulfurization apparatus which can realize a low cost, and a desulfurization method which comprises a technique indispensable for accelerating effective utilization of generated methane gas. SOLUTION: In the method wherein organic waste is subjected to methane fermentation and generated methane gas is recovered, digested liquid after fermentation and the generated methane gas mixed with oxygen in a concentration not higher than the explosion limit are heated to a temperature enabling microorganisms to act and are fed into a gas-liquid contact apparatus. An example of the gas-liquid contact apparatus is a horizontal long thin pipe.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to the effective use of generated methane gas in a method for treating organic waste such as livestock urine, food waste, and sewage sludge by methane fermentation to recover the methane gas. The present invention relates to a desulfurization device that can easily and inexpensively carry out a desulfurization method, which is an indispensable technique for promoting the

[0002]

BACKGROUND ART Methane gas obtained by methane fermentation treatment of organic waste such as livestock urine is an excellent fuel for recovering electricity and heat, but hydrogen sulfide is contained in the gas generated by methane fermentation. It is often contained in the order of several thousand ppm, and it is necessary to desulfurize it when it is used as fuel. For desulfurization of methane fermentation gas, usually, a method of removing as a sulfide by contact with an iron oxide-based packing and a method of adsorbing with activated carbon or the like are adopted.

For example, Japanese Unexamined Patent Publication No. 7-16430 discloses a technique for removing hydrogen sulfide by introducing methane gas generated in a methane fermentation tank into a desulfurization apparatus using a wet or dry desulfurization agent. In addition, Japanese Patent Laid-Open No. 2001-2001
Japanese Patent No. 170695 discloses a technique of removing hydrogen sulfide by introducing a digestion gas generated by methane fermentation into a desulfurizer filled with a desulfurizing agent.

[0004]

In the conventional methods for desulfurizing methane fermentation gas, the adsorbent and the desulfurizing agent are regularly replaced because the packing is deactivated by adsorption or reaction in any of the above methods. Is indispensable, and there is a problem in that it takes time and cost. In addition, it is necessary to prepare a method for treating the waste packing and store the replacement packing.

On the other hand, for example, the greatest concern in the field of livestock production is the treatment of a large amount of livestock urine discharged every day, and one of the most excellent treatment methods is the methane fermentation treatment method for generating electricity and recovering heat of methane gas. As one means for promoting the spread of the above, it is desired to develop a desulfurization device that can solve the above problems. The present invention has been made in view of the above points, and an object of the present invention is to promote effective utilization of generated methane gas in a method for treating organic waste while subjecting the organic waste to methane fermentation to recover methane gas. An object of the present invention is to provide a desulfurization device that can easily and inexpensively carry out the desulfurization method, which is an essential technique.

[0006]

In order to achieve the above object, a desulfurization apparatus for methane fermentation gas of organic waste according to the present invention comprises a methane gas generated by methane-fermenting an organic waste and after methane fermentation. A digestive liquid of, a desulfurization device equipped with a gas-liquid contact device for heating to a temperature at which microorganisms can be activated under the condition that oxygen below the explosion limit is added to make a gas-liquid contact,
The gas-liquid contact device consists of a tubular member installed substantially horizontally,
At least the bottom of the tubular member is filled with the digested liquid after methane fermentation, and the tubular member is filled with the generated methane gas so that gas-liquid contact can be achieved (FIG. 1, FIG. 2, FIG. 3).
reference). The tubular member that constitutes the gas-liquid contact device is preferably an elongated pipe that meanders in a substantially horizontal direction (see FIG. 2).

Further, the desulfurization apparatus of the present invention enables the activity of microorganisms under the condition that the methane gas generated by methane-fermenting an organic waste and the digested liquid after the methane fermentation are added with oxygen below the explosion limit. A desulfurization device equipped with a gas-liquid contact device for heating to temperature to make gas-liquid contact, the gas-liquid contact device consisting of a gas holder having a liquid tank at the bottom, and filling the bottom with digestive liquid after methane fermentation The gas holder is filled with the generated methane gas so that gas-liquid contact can be achieved (see FIGS. 4, 5, and 6).

Further, the desulfurization apparatus of the present invention enables the activity of microorganisms under the condition that the methane gas generated by methane-fermenting an organic waste and the digested liquid after the methane fermentation are added with oxygen below the explosion limit. A desulfurization device equipped with a gas-liquid contact device for heating to a temperature to make gas-liquid contact, the gas-liquid contact device consisting of a gas holder and a digestive liquid storage tank provided under the gas holder, and the digestive liquid storage tank containing methane. It is characterized in that the digested liquid after fermentation is supplied to seal the gas holder, and the gas holder is filled with the generated methane gas so that gas-liquid contact can be achieved (see FIG. 5). In the desulfurization apparatus described above, at least a part of the gas holder can be a balloon-shaped member made of an inflatable material (see FIG. 6).

Further, in these desulfurizers, at least a part of the wall surface of the gas-liquid contactor has a double structure through which hot water can flow, or a trace pipe through which hot water can flow through at least a part of the wall surface. It is possible to adjust the temperature inside the device to a temperature at which the activity of microorganisms becomes active by using hot water that has been placed and heated using waste heat generated by power generation and / or heat utilization by methane gas after desulfurization. preferable.

Further, in these desulfurizers, the gas outlet of the gas-liquid contactor may be provided with a cooling means and a condensed water recovery means for condensing and removing water in the desulfurized methane gas. Further, in these desulfurizers, it is preferable that the gas-liquid contactor is provided with a digestive liquid flow rate adjusting means and / or a methane gas flow rate adjusting means.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described. However, the present invention is not limited to the following embodiments, and can be appropriately modified and implemented. . 1, 2 and 3 show a first embodiment of the present invention.
1 shows a schematic configuration of a desulfurization apparatus for methane fermentation gas of organic waste according to a form. As shown in Fig. 1, methane gas generated by methane fermentation of organic waste (biogas containing methane as a main component) is mixed with air (oxygen may be used) so that the oxygen concentration is below the explosion limit. After that, it is introduced into one end of the gas-liquid contactor 10 in which a long and narrow pipe is installed horizontally. A digestive liquid (slurry) obtained by methane-fermenting an organic waste is supplied to one end of the pipe-shaped vapor-liquid contacting device 10, and gas-liquid contact is performed on the liquid surface of the digestive liquid accumulated in the device 10. Is planned. The methane gas in the apparatus 10 is aerobically biodesulfurized by desulfurizing microorganisms in the digestive fluid or desulfurizing microorganisms acclimatized in the desulfurizing apparatus.

As described above, the gas-liquid contactor 10 has a long and slender pipe installed horizontally. In this case, for example, as shown in the piping diagram of FIG. 2, the slender pipe is meandered in the horizontal direction. Can be By making the pipe meander, the residence time of the digestive liquid in the gas-liquid contacting device 10 becomes long, the biodesulfurization of methane gas can be sufficiently performed, and a compact device can be obtained. In FIG. 2, 12 is a digestive fluid inlet, 14 is a biogas inlet, and 16 is a drain outlet.

The residence time of the digestive liquid in the gas-liquid contactor 10 and the flow rates of methane gas, etc. are controlled by the flow rate control valves 20, 22 respectively.
It is possible to adjust with. Reference numeral 24 is an air flow rate control valve. As an example, when the hydrogen sulfide contained in the generated methane gas has a high concentration, the digestive liquid is constantly supplied, and when the hydrogen sulfide contained in the generated methane gas has a low concentration, the digestive liquid is supplied intermittently. In this way, it is possible to keep desulfurizing microorganisms in a suitable state at all times.

The inside of the gas-liquid contacting device 10 needs to be at a temperature at which desulfurizing microorganisms can be activated, but the device 10 is set at a temperature at which the microorganisms are active (about 30 ° C.). It is preferable to have a configuration capable of heating. In this case, for example, as shown in FIG.
In order to allow hot water to flow in the gas-liquid contact device 1
Temperature control within 0 can be performed. As the warm water, it is preferable to use warm water heated by using waste heat generated by power generation and / or heat utilization by methane gas after desulfurization. Also, instead of making the pipe a double pipe structure,
A hot water trace pipe may be arranged on the outer wall of the pipe. In the rare case where the outside air temperature exceeds 35 ° C., it is preferable to cool instead of heating.

The desulfurized methane gas is sent to a gas holder (in some cases, via a secondary desulfurizer), stored in the gas holder, and then used as fuel for power generation and / or heat utilization. . The digested liquor after desulfurization is sent to the digestive liquor storage tank together with the rest of the digested liquor (after methane fermentation), and is delivered as liquid fertilizer or the like.

As described above, when the gas-liquid contactor 10 is heated to perform desulfurization treatment, the desulfurized methane gas contains saturated water, so that it is useful as a fuel as it is. Will be low. Therefore, for example, as shown in FIG. 3, at the gas outlet of the gas-liquid contact device 10,
It is preferable to install a cooler 26 for condensing water in the gas and a drain tank 28 for collecting the condensed water to dehumidify the methane gas. When biodesulfurization is performed at a relatively low temperature (however, the temperature at which desulfurizing microorganisms can be activated) without heating the gas-liquid contactor 10, the dehumidifying means for methane gas is not always necessary.

FIG. 4, FIG. 5 and FIG. 6 show the second embodiment of the present invention.
1 shows a schematic configuration of a desulfurization apparatus for methane fermentation gas of organic waste according to a form. As shown in Fig. 4, methane gas (biogas containing methane as a main component) generated by methane fermentation of organic waste is mixed with air (oxygen may be used) so that the oxygen concentration is below the explosion limit. After that, it is introduced into the gas-liquid contactor 30 which is composed of a gas holder having a digestive liquid storage tank at the bottom. The digestive liquid (slurry) obtained by methane-fermenting the organic waste is supplied to the bottom of the gas-liquid contacting device 30 including a gas holder, and the digestive liquid accumulated at the bottom of the device 30 is vapor-liquid. Contact is made.

As described above, the gas-liquid contact device 30 is the gas holder 32, and the digestive liquid storage tank 34 at the bottom is filled with the digestive liquid after methane fermentation. Further, the gas-liquid contact device 30
It is necessary to set the inside temperature to a temperature at which the activity of the desulfurizing microorganisms is possible, but it is preferable that the apparatus 30 can be heated in order to reach a temperature at which the activity of the microorganisms becomes active (about 30 ° C.). In this case, for example, the temperature of the gas-liquid contact device 30 can be controlled by arranging the hot water trace pipe 36 on the outer wall of the device and allowing the hot water to flow through the pipe. As the warm water, it is preferable to use warm water heated by using waste heat generated by power generation and / or heat utilization by methane gas after desulfurization. Also, instead of providing hot water trace piping, the outer wall of the device has a jacket structure (double structure)
As a result, warm water may be allowed to flow in the inside.

Further, in the present embodiment, as shown in FIG. 5, for example, as the gas-liquid contact device 30a, the digestive liquid after methane fermentation is supplied to the digestive liquid storage tank 34a to seal the gas holder 32a. The configuration can be used. Further, for example, as shown in FIG. 6, the gas-liquid contact device 30b may have a configuration in which the gas holder 32b is a balloon-shaped member made of an inflatable material. In this case, it is not necessary to seal the gas holder with the liquid.
By expanding the gas holder 32b, a large volume of methane gas can be stored, so that the gas holder for storing methane gas in the subsequent stage can be omitted. As a material for the balloon-shaped member, for example, a Teflon (registered trademark) coating resin film or the like can be used. Other configurations and operations are
This is similar to the case of the first embodiment.

[0020]

Since the present invention is configured as described above, it has the following effects. (1) When contacting the methane gas generated by methane fermentation with the digested liquid after methane fermentation to perform biodesulfurization, gas-liquid contact can be achieved with a device with a long thin pipe installed horizontally and a device composed of a gas holder. A simple and inexpensive desulfurization device can be realized. (2) The temperature of the gas-liquid contactor can be easily controlled, and it is economical to use hot water heated using waste heat generated by power generation and / or heat utilization by methane gas after desulfurization. (3) Compared with the conventional desulfurization method of contacting the generated methane gas with the filler such as an adsorbent or a desulfurizing agent, the labor and cost for exchanging the filler are not required, and the treatment of the waste filler is unnecessary.

[Brief description of drawings]

FIG. 1 is a schematic configuration explanatory view showing an example of a desulfurization device for methane fermentation gas of organic waste according to a first embodiment of the present invention.

FIG. 2 is a piping diagram showing a desulfurization device for methane fermentation gas of organic waste according to the first embodiment of the present invention.

FIG. 3 is a schematic configuration explanatory view showing another example of a desulfurization device for methane fermentation gas of organic waste according to the first embodiment of the present invention.

FIG. 4 is a schematic configuration explanatory view showing an example of a desulfurization device for methane fermentation gas of organic waste according to a second embodiment of the present invention.

FIG. 5 is a schematic structural explanatory view showing another example of a desulfurization device for methane fermentation gas of organic waste according to a second embodiment of the present invention.

FIG. 6 is a schematic structural explanatory view showing still another example of the desulfurization device for methane fermentation gas of organic waste according to the second embodiment of the present invention.

[Explanation of symbols]

10 Pipe-shaped gas-liquid contact device 12 Digestive fluid inlet 14 Biogas inlet 16 Drain outlet 18 Double tube structure 20, 22, 24 Flow rate control valve 26 Cooler 28 Drain tank 30, 30a, 30b Gas-liquid contact device 32, 32a, 32b Gas holder 34, 34a Digestive fluid storage tank 36 Hot water trace piping

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Kozo Nagayasu             1-1 Kawasaki-cho, Akashi-shi, Hyogo Kawashige Techno             Service Co., Ltd. F-term (reference) 4D059 AA01 AA03 BA15

Claims (8)

[Claims] 1. A methane gas generated by methane-fermenting an organic waste and a digested liquid after the methane-fermentation are heated to a temperature at which microorganisms can be activated under the condition that oxygen below the explosion limit is added. A desulfurization device of methane fermentation gas having a gas-liquid contact device for liquid contact, the gas-liquid contact device consisting of a tubular member installed substantially horizontally, at least the bottom of the tubular member with the digested liquid after methane fermentation A desulfurization apparatus for methane fermentation gas of organic waste, characterized in that the tubular member is filled with generated methane gas so that gas-liquid contact can be achieved. 2. The desulfurization apparatus for methane fermentation gas of organic waste according to claim 1, wherein the tubular member is an elongated pipe meandering in a substantially horizontal direction. 3. A methane gas generated by methane-fermenting an organic waste and a digested liquid after the methane-fermenting are heated to a temperature at which microorganisms can be activated under the condition that oxygen below the explosion limit is added. A desulfurization device for a methane fermentation gas having a gas-liquid contact device for liquid contact, wherein the gas-liquid contact device comprises a gas holder having a liquid tank at the bottom, and the bottom is filled with digestive liquid after methane fermentation, A desulfurization device for methane fermentation gas of organic waste, characterized in that the holder is filled with generated methane gas to enable gas-liquid contact. 4. A methane gas generated by methane-fermenting an organic waste and a digested liquid after the methane-fermentation are heated to a temperature at which microorganisms can be activated under the condition that oxygen below the explosion limit is added. A desulfurization device of methane fermentation gas having a gas-liquid contact device for liquid contact, wherein the gas-liquid contact device consists of a gas holder and a digestive liquid storage tank provided at the bottom of the gas holder, and the digestive liquid storage tank after the methane fermentation A desulfurization device for methane fermentation gas of organic waste, characterized in that the digestive liquid is supplied to seal the gas holder, and the gas holder is filled with generated methane gas to enable gas-liquid contact. 5. The desulfurization apparatus for methane fermentation gas of organic waste according to claim 3, wherein at least a part of the gas holder is a balloon-shaped member made of an inflatable material. 6. A methane gas after desulfurization, wherein at least a part of the wall surface of the gas-liquid contact device has a double structure through which hot water can flow, or a trace pipe through which hot water can flow is arranged on at least a part of the wall surface. 6. The hot water warmed by using waste heat generated by power generation and / or heat utilization by the device can be adjusted to a temperature at which the activity of microorganisms becomes active in the device. A desulfurization apparatus for methane fermentation gas of the described organic waste. 7. The gas outlet of the gas-liquid contactor is provided with cooling means and condensed water recovery means for condensing and removing water in the desulfurized methane gas. Desulfurization equipment for methane fermentation gas from organic waste. 8. The gas-liquid contactor is provided with a digestive juice flow rate adjusting means and / or a methane gas flow rate adjusting means.
7. A desulfurization device for methane fermentation gas of organic waste according to any one of 7 to 7.