JP5159710B2 - Microbial culture method and culture apparatus, biological hydrogen production method and fuel cell system - Google Patents

Description

  The present invention relates to a method for culturing a microorganism capable of producing hydrogen and a method for producing hydrogen using the microorganism.

  Unlike fossil fuels, hydrogen is attracting attention as the ultimate clean energy source that does not generate substances of concern due to environmental problems such as carbon dioxide and sulfur oxides even when burned. The amount of heat per unit mass is more than three times that of petroleum, If supplied to the fuel cell, it can be converted into electric energy and heat energy with high efficiency.

For the production of hydrogen, techniques such as pyrolysis steam reforming of natural gas or naphtha have been proposed as chemical production methods. This method requires high-temperature and high-pressure reaction conditions, and since the produced synthesis gas contains CO (carbon monoxide), when used as fuel for a fuel cell, it prevents the deterioration of the electrode catalyst of the fuel cell. Therefore, it is necessary to perform CO removal with a high degree of technical problem solving difficulty.
On the other hand, the biological hydrogen production method using microorganisms is a reaction condition at normal temperature and pressure, and the generated gas does not contain CO, so that it is not necessary to remove it.
From this point of view, biological hydrogen production by microorganisms has attracted attention as a more preferable method for supplying fuel for fuel cells.

  Biological hydrogen production methods can be broadly classified into methods using photosynthetic microorganisms and methods using non-photosynthetic microorganisms (mainly anaerobic microorganisms). Since the former method uses light energy for hydrogen generation, it requires a large light condensing area due to its low light energy utilization efficiency, and there are problems to be solved such as price problems and difficulty in maintenance management of the hydrogen generator. Many are not practical.

  The conventional hydrogen production method using the latter anaerobic microorganisms relies on the division and growth of these anaerobic microorganisms, but the growth is extremely slow (Patent Documents 1 and 2). Therefore, since the concentration of anaerobic microorganisms having hydrogen generation capacity is small and the hydrogen generation rate is not sufficient, it is possible to obtain anaerobic microorganisms having hydrogen production ability that is qualitatively and quantitatively feasible industrially. It was not easy. In this regard, further improvement is required.

US Pat. No. 5,834,264 Published Patent Publication No. Hei 8-252089

As a conventional method for growing anaerobic microorganisms having hydrogen-producing ability, culture under anaerobic conditions has been mainly used. That is, a method for producing hydrogen simultaneously with the division and growth of anaerobic microorganisms. However, the growth of anaerobic microorganisms accompanied by the production of hydrogen under anaerobic conditions makes it difficult to increase the concentration of microorganisms in the culture medium compared to the growth under aerobic conditions. Thus, although it is easy to grow the microorganism concentration to a high concentration under aerobic conditions, it is difficult to obtain a microorganism capable of producing hydrogen.
The above-mentioned problems of the conventional hydrogen production method depending on the division and growth of anaerobic microorganisms are, in other words, the acquisition of high-density anaerobic microorganisms and the hydrogen generation function of anaerobic microorganisms in the conventional technology. This is because we have not found a way to achieve the acquisition of
An object of the present invention is to solve these technical problems relating to a method for producing hydrogen by anaerobic microorganisms. An object of the present invention is to achieve anaerobic microorganisms having a sufficient number of cells for hydrogen generation reaction in a short time, anaerobic microorganisms to acquire a hydrogen generation function in a short time, and industrially advantageous production of hydrogen. It is to provide a method. Further, the present invention is not a method that relies on long-term division growth of anaerobic microorganisms under anaerobic conditions, and the hydrogen generation rate is sufficiently high from the beginning of the reaction, and the fuel cell can be operated at a practical level. It aims to provide a method.

  That is, the present invention relates to a method for culturing anaerobic microorganisms capable of producing hydrogen, and a method for producing hydrogen using the microorganisms, in order to solve these technical problems, unless relying on long-term division growth. An object of the present invention is to provide a method and apparatus for culturing microorganisms having hydrogen production ability in a relatively short time, and a biological hydrogen production method using the same.

  As a result of intensive studies aimed at solving the above-mentioned problems, the present inventors have cultivated microorganisms having a formate dehydrogenase gene and a hydrogenase gene under aerobic conditions to thereby formate dehydrogenase gene. It was also found that a microorganism having a hydrogenase gene can be obtained (or produced) in a large amount in a short time, that is, an industrially advantageous method for growing or culturing the microorganism can be obtained. The microorganism obtained in this way has a formate dehydrogenase gene and a hydrogenase gene, but usually does not have the ability to generate hydrogen. The present inventors have a high hydrogen production ability by culturing a microorganism obtained under the above aerobic conditions while controlling the concentration of organic acid and / or alcohol in a culture solution under anaerobic conditions. It has been found that a large amount of microorganisms can be obtained.

Furthermore, the present inventors have shown that hydrogen can be produced at a much higher rate of hydrogen generation per reaction volume by bringing the microorganisms thus obtained into contact with a reducing hydrogen generation solution and an organic substrate. The present invention was completed by the headings and further various studies.
That is, the present invention
(1) Controlling the concentration of organic acid and / or alcohol in a culture solution under anaerobic conditions for a microorganism obtained by culturing a microorganism having a formate dehydrogenase gene and a hydrogenase gene under aerobic conditions A method for culturing a microorganism having hydrogen-producing ability, characterized by
(2) The method for culturing a microorganism according to (1), wherein the organic acid is at least one selected from acetic acid, lactic acid, butyric acid, malic acid, fumaric acid, succinic acid, and propionic acid,
(3) The method for culturing a microorganism according to (1), wherein the alcohol is at least one selected from ethanol, butanediol, isopropanol, and butanol,
(4) The method for culturing a microorganism according to (1), wherein the organic acid is cultured in a culture solution having a concentration of 200 mM or less,
(5) The method for culturing a microorganism according to (1), wherein the culture is performed in a culture solution having an alcohol concentration of 200 mM or less,
(6) An organism characterized in that the microorganism obtained by the method according to any one of (1) to (5) is added to a hydrogen generation solution in a reduced state, and an organic substrate is supplied to the solution. Hydrogen production method,
(7) A system including a fuel cell, wherein hydrogen produced by the method according to (6) is used as a fuel gas for a fuel cell,
(8) A culture apparatus for the microorganism culture method according to (1), wherein a hydrogen sensor is mounted.
(9) A culture apparatus for the method for culturing a microorganism according to (1), wherein a detection device capable of detecting a generation rate of a generated gas is mounted,
(10) A microorganism obtained by culturing a microorganism having a formate dehydrogenase gene and a hydrogenase gene under an aerobic condition is used to control the concentration of an organic acid and / or alcohol in a culture solution under an anaerobic condition. And a microorganism-cultivating apparatus having a hydrogen-producing ability, characterized in that a hydrogen sensor is placed in a vessel for culturing, and (11) a microorganism having a formate dehydrogenase gene and a hydrogenase gene under aerobic conditions A detection device capable of detecting the generation rate of the generated gas is placed in a container for culturing the microorganisms obtained by cultivating the microorganisms while controlling the concentration of organic acid and / or alcohol in the culture solution under anaerobic conditions. An apparatus for culturing microorganisms having hydrogen-producing ability,
About.

  The present invention uses a microorganism having a formate dehydrogenase gene and a hydrogenase gene to culture a microorganism obtained by culturing under an aerobic condition while controlling the concentration of organic acid and / or alcohol under an anaerobic condition. Thus, microorganisms capable of producing hydrogen can be obtained in a short time, and further, a hydrogen generation solution in a reduced state is added to the obtained microorganisms, and an organic substrate is supplied. It is possible to provide a hydrogen production method that can improve the hydrogen generation rate and can be used as a fuel for a fuel cell.

Changes in organic acid and alcohol concentrations during culture under anaerobic conditions (Part 1) Changes in organic acid and alcohol concentrations during culture under anaerobic conditions (Part 2)

The steps involved in the hydrogen production method of the present invention are the following first to third steps.
That is, the present invention as a whole is a first step of cultivating specific bacterial cells under aerobic conditions to proliferate the cells, and then the grown bacterial cells in the culture solution under anaerobic conditions and / or Alternatively, the second step of cultivating while controlling the concentration of alcohol to impart hydrogen generation capability to the cells, and adding the organic substrate to the hydrogen generation solution in a reduced state by adding the cells thus provided with hydrogen generation capability to the reduced hydrogen generation solution. A third step of supplying and generating hydrogen.

  The microorganisms used in the present invention include formate dehydrogenase gene (F. Zinoni, et al., Proc. Natl. Acad. Sci. USA, Vol. 83, pp4650-4654, July 1986 Biochemistry) and hydrogenase gene (R. Boehm, et al., Molecular Microbiology (1990) 4 (2), 231-243) and mainly anaerobic microorganisms.

  Various metabolic pathways are known for hydrogen generation in anaerobic microorganisms (hydrogen generation as a metabolite in the degradation pathway of glucose to pyruvate, and pathway in which acetic acid is generated by pyruvate through acetyl-CoA. Generation of hydrogen as a metabolite and pathway of hydrogen generation from formic acid derived from pyruvic acid). The present invention relates to a microorganism culturing method and a biological hydrogen production method capable of producing hydrogen from an organic substrate such as formic acid.

  Examples of specific anaerobic microorganisms used in the present invention include microorganisms belonging to the genus Escherichia, such as Escherichia coli ATCC 9637, ATCC 11775, ATCC 4157, etc., microorganisms belonging to the genus Klebsiella, such as Klebsiella. pneumoniae ATCC 13883, ATCC 8044 etc.), Enterobacter microorganisms such as Enterobacter aerogenes ATCC 13048, ATCC 29007 etc. and Clostridium microorganisms such as Clostridium beijerinck 25 .

The growth of these anaerobic microorganisms under anaerobic conditions is much slower than that under aerobic conditions, and culture growth under aerobic conditions is preferred. In this sense, among anaerobic microorganisms, facultative anaerobic microorganisms are preferably used rather than obligate anaerobic microorganisms. Among the above microorganisms, Escherichia coli, Enterobacter aerogenes and the like are preferably used.
The first step is performed by culturing and growing the above microorganisms under aerobic conditions.

Culture of microorganisms under aerobic conditions can be performed using a normal nutrient medium containing a carbon source, a nitrogen source, a mineral source, and the like. Examples of the carbon source include glucose, fructose, galactose, mannose, lactose, sucrose, cellulose, waste molasses, glycerol, and the like, and examples of the nitrogen source include inorganic nitrogen sources such as ammonia, ammonium salt, and nitrate. In the organic nitrogen source, for example, urea, amino acids, proteins and the like can be used alone or in combination. Both inorganic and organic forms can be used in the same manner. Further, as the mineral source, for example, potassium monohydrogen phosphate, magnesium sulfate, etc., mainly containing Na, K, P, Mg, S, etc. can be used. In addition to these, nutrients such as various vitamins such as peptone, meat extract, yeast extract, corn steep liquor, casamino acid, biotin and thiamine can be added to the medium as necessary.
Examples of the culture medium in the first step include those in Table 1.

As a culture condition under an aerobic condition and an anaerobic condition, it is preferable that the temperature range is about 20 ° C. to 45 ° C., preferably about 25 ° C. to 40 ° C. The pH range is preferably about 4.0 to 10.0, preferably about 5.0 to 8.0. It is preferable to control the pH at the same time, and it is also possible to adjust the pH using an acid or alkali. In the temperature range and the pH range, the above range is the optimum temperature range and pH range for the microorganism. Usually, the carbon source concentration at the start of culture is preferably about 0.1 to 20% (W / V), more preferably about 1 to 5% (W / V). The culture period is about 0.25 days to 7 days.
Cultivation is usually carried out under aerobic conditions such as aeration stirring and shaking. The culture of these microorganisms under aerobic conditions is well known in the art and may be followed.
The concentration (w / w%) in the microorganism culture solution at the end of the culture in the first step is preferably about 2 to 1000 times that at the start of the culture.

In the second step, the present invention is a method in which a microorganism obtained by culturing a microorganism having a formate dehydrogenase gene and a hydrogenase gene under an aerobic condition is cultured under an anaerobic condition, Is performed under anaerobic conditions while controlling the concentration of the organic acid and / or alcohol produced.
The bacterial cells obtained by the first step have an increased number of bacteria but do not have the ability to generate hydrogen.

Next, the second step will be described. The cells cultured in the first step in this manner are preferably once separated from the culture medium and recovered and used in the second step. It is preferable to isolate the bacterial cells from the culture solution in the first step containing components (for example, ethanol, acetic acid, lactic acid, etc.) that inhibit the hydrogen generation of the bacteria grown under aerobic conditions.
As a separation method, a general method such as centrifugation or membrane separation is used. Use of aerobically cultured microorganisms without separating and recovering them may adversely affect the cultivation of microorganisms capable of producing hydrogen due to metabolites present inside and outside the cells that are produced during cultivation under aerobic conditions. Therefore, it is not preferable.
Note that cells grown under aerobic conditions do not have the ability to generate hydrogen. Examples of the separation of the cells before the second step include centrifugation and filtration. The collected microbial cells are suspended and cultured in a culture solution (hydrogen generation capability induction medium) under anaerobic conditions to impart hydrogen generation capability to the microbial cells. That is, the hydrogen generation ability is imparted to the cells by the second step.

The microorganism concentration in the culture solution under anaerobic conditions is preferably about 0.1% to 80% (wet cell mass standard) in order to obtain microorganisms that express hydrogen production ability. More preferably, it is about 1% to 80% (wet cell mass standard) in order to efficiently obtain microorganisms having hydrogen-producing ability. The change over time in the concentration of microorganisms in the culture solution under anaerobic conditions is not limitative, although it is preferable that cells are dividing and growing.
The anaerobic condition can be confirmed from the oxidation-reduction potential in the culture solution being −100 mV to −500 mV, more preferably −200 mV to −500 mV. Examples of the method for adjusting the anaerobic state of the medium include a method in which dissolved gas is removed by heat treatment, decompression treatment, or bubbling of nitrogen gas or the like. Specifically, as a method for removing dissolved gas, particularly dissolved oxygen in the culture solution, about 13.33 × 10 ² Pa or less, preferably about 6.67 × 10 ² Pa or less, more preferably about 4.00. A culture solution under anaerobic conditions can be obtained by performing a deaeration treatment under a reduced pressure of × 10 ² Pa or less for about 1 to 60 minutes, preferably about 5 to 60 minutes. Moreover, a reducing agent can be added to aqueous solution as needed, and the aqueous solution of anaerobic conditions can be adjusted. Examples of the reducing agent used include thioglycolic acid, ascorbic acid, cysteine hydrochloride, mercaptoacetic acid, thiolacetic acid, glutathione, and sodium sulfide. It is also possible to use one of these or a combination of several types.

  In the second step of the present invention, the organic acid and / or alcohol is produced mainly in the metabolic pathway of the microorganism in the culture solution under anaerobic conditions. During the culture under anaerobic conditions, acetic acid, lactic acid, butyric acid, malic acid, fumaric acid, succinic acid, and propionic acid are used as organic acids, and ethanol, butanediol, isopropanol, and butanol are used as alcohols. And so on. Controlling the concentration of the organic acid and / or alcohol produced during the culture under these anaerobic conditions to a specific concentration range is essential for obtaining the microorganisms capable of producing hydrogen of the present invention.

  Controlling the concentration of the organic acid and / or alcohol in the culture solution under anaerobic conditions to be 200 mM or less is necessary for culturing microorganisms having hydrogen-producing ability, so that the concentration is 100 mM or less. It is more preferable to control.

  As a control method, while separating microorganisms in the culture solution, the culture solution in the specified concentration range of the present invention is continuously replaced, or the concentration of the organic acid and / or alcohol is outside the specified concentration range. Before becoming a sample, it is collected and centrifuged to separate the microorganism and supernatant, and the separated microorganism is charged with a culture solution within a specific concentration range, and the microorganism is suspended again and further cultured. Can be mentioned. In addition to the above method, the control method is not particularly limited as long as the concentration of the organic acid and / or alcohol in the culture solution under anaerobic conditions can be maintained within the concentration range of the present invention. When the culture solution is replaced, the replacement frequency is preferably 0.1 to 60 times per hour. In the case of 0.1 times or less per hour, it becomes difficult to obtain microorganisms capable of producing hydrogen due to the influence of organic acids and / or alcohols, which are metabolites of microorganisms, during stirring culture under anaerobic conditions. Therefore, it is not preferable. Replacing 60 times or more in one hour is not preferable because a large amount of medium components are required.

  Culture of microorganisms under anaerobic conditions can be performed using a normal nutrient medium containing a carbon source, a nitrogen source, a mineral source, and the like. Examples of the carbon source include glucose, fructose, galactose, mannose, lactose, sucrose, cellulose, waste molasses, glycerol, and the like, and examples of the nitrogen source include inorganic nitrogen sources such as ammonia, ammonium salt, and nitrate. In the organic nitrogen source, for example, urea, amino acids, proteins and the like can be used alone or in combination. Both inorganic and organic forms can be used in the same manner. Further, as the mineral source, for example, potassium monohydrogen phosphate, magnesium sulfate, etc., mainly containing K, P, Mg, S and the like can be used. In addition to these, nutrients such as various vitamins such as peptone, meat extract, yeast extract, corn steep liquor, casamino acid, biotin and thiamine can be added to the medium as necessary.

In addition, it is a preferable condition that a trace amount of a metal component is included for the expression of a unit function composed of formate dehydrogenase and hydrogenase. Necessary trace metal components vary depending on the microorganism species, and examples thereof include iron, molybdenum, selenium, and nickel. Examples of the compound containing these metals include sodium molybdate anhydride and sodium selenite pentahydrate. In addition, these trace metal components are contained in a considerable amount in natural nutrient sources such as yeast extract. Therefore, addition is not always necessary.
Examples of the culture medium in the second step include those shown in Table 2 below.

As a culture condition under an aerobic condition and an anaerobic condition, it is preferable that the temperature range is about 20 ° C. to 45 ° C., preferably about 25 ° C. to 40 ° C. The pH range is preferably about 4.0 to 10.0, preferably about 5.0 to 8.0. It is preferable to control the pH at the same time, and it is also possible to adjust the pH using an acid or alkali. In the temperature range and the pH range, the above range is the optimum temperature range and pH range for the microorganism. Usually, the carbon source concentration at the start of culture is preferably about 0.1 to 20% (W / V), more preferably about 1 to 5% (W / V).
The culture is preferably performed until the microorganism in the culture solution starts producing a sufficient amount of hydrogen.

  Therefore, as a culture apparatus under anaerobic conditions, a culture apparatus characterized in that a hydrogen sensor is placed in a container for culture is preferable. It can be confirmed that the concentration of hydrogen in the container increases because microorganisms capable of producing hydrogen under anaerobic conditions produce hydrogen. Further, it is preferable that a device for detecting the generated gas, for example, a flow meter, is mounted in the process of discharging the gas from the container. Thereby, the gas generation rate can be confirmed. When the rate of increase in the gas generation rate is reduced, it is possible to confirm that the culture reaction of the microorganisms capable of producing hydrogen under anaerobic conditions has reached the end point.

The third step is performed by generating hydrogen by adding the microorganism obtained in the second step to the hydrogen generation solution in a reduced state and supplying an organic substrate to the solution.
Next, regarding the third step, the cells having the ability to generate hydrogen recovered and separated as described above are added to the hydrogen generation solution in a reduced state, and the organic substrate is biologically or continuously added intermittently. It is used for the hydrogen production method. The organic substrate is preferably supplied continuously, but when it is supplied intermittently, it is necessary that an amount sufficient for hydrogen generation is present in the reaction system. The recovered bacterial cells can be used without any treatment, or the recovered bacterial cells immobilized with acrylamide or carrageenan can be used.

  Regarding the recovery and separation of bacterial cells, the bacterial cells cultured under aerobic conditions are not directly used for hydrogen generation under reduced conditions, but are aerobically cultured and further anaerobically cultured as in the present invention. In order to demonstrate the effects of the method of the present invention, it is preferable to separate and recover the cells once the hydrogen generation unit function has been obtained and add this to the hydrogen generation solution to generate hydrogen in a reduced state.

  As the hydrogen generation solution, the same or similar medium as that used in the second step is used. However, since hydrogen generation is intense, an antifoaming agent (a commercially available antifoaming agent such as a silicone-based antifoaming agent, polyether) is used. It is recommended to use an antifoaming agent.

  The cell concentration is about 0.1% (w / w) to 80% (w / w) (wet cell mass standard), preferably about 5% (w / w) to 70% (w / w) ( Wet cell mass basis), more preferably about 10% (w / w) to 70% (w / w) (wet cell mass basis).

  As in the second step, a reducing agent may be used. However, since the growth of the bacterial cells does not occur, the amount of carbohydrate necessary for the growth of the bacterial cells is usually not included in the liquid composition. In this case, since it is an important point that the bacteria do not substantially grow, a carbon source such as glucose used for the growth of the bacteria in the medium is unnecessary. Although the carbon source may be used, it may be in an amount necessary only to maintain the hydrogen generation capacity of the microbial cell (because the present invention is preferably a method for producing biological hydrogen by cells that have substantially stopped growing). Depending on what)

  In addition, it is a preferable condition that a trace amount of a metal component is included for the expression of a unit function composed of formate dehydrogenase and hydrogenase. Necessary trace metal components vary depending on the microorganism species, and examples thereof include iron, molybdenum, selenium, and nickel. Examples of the compound containing these metals include sodium molybdate anhydride and sodium selenite pentahydrate. In addition, these trace metal components are contained in a considerable amount in natural nutrient sources such as yeast extract. Therefore, addition is not always necessary.

Examples of the medium in the third step include those shown in Table 3 below.
Realization of the reduced state of the hydrogen generation solution can be performed according to the anaerobic conditions of the second step. The reduction state of the solution for hydrogen generation is specified by the oxidation-reduction potential of about −100 mV to −500 mV, more preferably −200 mV to −500 mV.

  The organic substrate required for the hydrogen generation raw material is a compound that is converted to formic acid in the pathway that occurs in the bacterial metabolism in the culture solution (for example, monosaccharides such as glucose, fructose, xylose, arabinose, sucrose, maltose). And formic acids such as formic acid and formate (for example, sodium formate and potassium formate) that are directly supplied from the outside. Although an indirect supply method using a compound that can be changed to formic acid and a direct supply method can be used in combination, a direct supply method from the outside is preferable.

When the organic substrate to be supplied is formic acid, the concentration is preferably high from the viewpoint of maintaining the microorganism concentration. For example, when formic acid is used as the organic substrate, 30 to less than 100% (w / w) is preferable. More preferably, it is 50 to less than 100% (w / w). When the concentration is low, the volume of the hydrogen generating solution increases with the supply of formic acid, and therefore the microorganism concentration also changes, which is not preferable. The supply rate of the organic substrate is not particularly limited as long as the pH of the hydrogen generating solution is controlled within the range of 4.0 to 9.0.
The reaction temperature of the hydrogen generation reaction depends on the microorganism species to be used, but in general, when normal temperature microorganisms are used, conditions of 20 ° C. to 45 ° C. are preferable, and a range of 30 ° C. to 40 ° C. is more preferable. It is also preferable from the aspect of life.
According to the method of the present invention, hydrogen gas can be produced at a rate of 0.01 to 500 L / hr / L per hour per liter of reaction volume. The measurement of the speed is performed according to a known method.

In the biological hydrogen production using the microorganism of the present invention, a gas mainly composed of hydrogen and carbon dioxide is produced, and basically no carbon monoxide is produced. In general, when used as a fuel for a current polymer electrolyte fuel cell, it is necessary to maintain CO at 10 ppm or less by using a system for removing carbon monoxide (CO converter, CO remover, etc.). However, a system using the hydrogen production method of the present invention as a fuel for a fuel cell is preferable because a system for removing CO is unnecessary and the apparatus can be simplified.
As for the temperature control of the reaction vessel during hydrogen production, the reforming method using natural gas generally requires a reforming temperature of 600 ° C. or higher, and even when methanol is used, the reforming temperature is several hundred ° C. The temperature of the reaction vessel of the present invention can be used at room temperature, while the temperature of the material is required.
From the above, the fuel cell system using the hydrogen production method of the present invention is excellent because there is little problem in terms of deterioration of the fuel cell and no high temperature system is required in terms of the hydrogen supply method. Recognize.

  EXAMPLES Hereinafter, the present invention will be specifically described with reference to examples, but the present invention is not limited thereto.

[Example 1]
Biological hydrogen production method using Escherichia coli strain (ATCC9637).
This strain was added to a culture solution having the composition shown in Table 1 below under aerobic conditions and cultured at 37 ° C.

Next, microorganisms were separated from the culture broth cultured under aerobic conditions, added to the culture broth having the composition shown in Table 2 below, and cultured under anaerobic conditions at 37 ° C. The redox potential of the culture solution under anaerobic conditions was -385 mV.
The operation under anaerobic conditions was performed in a box in which the oxygen concentration in the gas phase was controlled to 10 ppm or less.
Six hours after the start of culture under anaerobic conditions, the main culture was centrifuged (5000 rpm, 15 minutes), and the supernatant was removed. Thereafter, a culture solution for anaerobic conditions shown in Table 2 below was added to suspend the microorganisms. Then, the cells were further cultured for 6 hours under anaerobic conditions, and cultured under anaerobic conditions for a total of 12 hours.

The culture broth was centrifuged (5000 rpm, 15 minutes), and the supernatant was removed to obtain a microorganism capable of producing hydrogen.
The separated microorganisms were suspended and prepared in 100 ml of a hydrogen generation solution under reduced conditions shown in the composition of Table 3 below (microbe concentration 40% wet cell mass basis).

The reaction vessel for hydrogen generation is equipped with a formic acid supply nozzle, a stirring device, a pH adjusting device, a temperature maintaining device, and an oxidation-reduction potential measuring device, and is placed in a constant temperature water tank set at 37 ° C.
The amount of gas generated by measuring 26 mol (mol) / L (liter) of formic acid at a feed rate of 8 ml / hr continuously using a micropump was measured.
Gas generation occurred simultaneously with the formic acid supply, and the formic acid was continuously supplied. The collected gas was analyzed by gas chromatography (manufactured by Shimadzu Corporation) using a flame ionization detector. As a result, the generated gas contained 50% hydrogen and the remaining gas. The hydrogen generation rate measured by a gas flow meter was 45 L (H ₂ ) / hr / L (reaction volume) per hour, and almost constant gas generation continued for about 1 hour.

[Comparative Example 1]
The test was carried out under the same conditions as in Example 1 except that the culture was continued for 12 hours under anaerobic conditions without exchanging the culture medium. The gas generation conditions were also the same as in Example 1.
When gas was generated and the hydrogen generation rate was measured, it was 12 L (H ₂ ) / hr / L (reaction volume).
The concentration of organic acid present in the liquid cultured under the above-mentioned anaerobic conditions was measured using high performance liquid chromatography (manufactured by Tosoh Corporation). The column was analyzed using an electrical conductivity detector using TSKgel Oapak-A (manufactured by Tosoh Corporation). The alcohol concentration was measured using gas chromatography (manufactured by Shimadzu Corporation). The column was analyzed with a flame ionization detector using Thermo-1000 (manufactured by Shimadzu Corporation).
FIG. 1 shows the results of examining the concentration in the culture solution during culture under anaerobic conditions by analyzing the supernatant from which the microorganisms were separated by centrifugation.

According to the results of Example 1 and Comparative Example 1, during culture under anaerobic conditions, the supernatant liquid from which the microorganisms in the culture solution were separated was removed, and the culture solution for anaerobic conditions shown in Table 2 was added to suspend the microorganisms. Microorganisms capable of effectively producing hydrogen by culturing under anaerobic conditions while controlling the concentration of organic acids and alcohols in the culture solution under anaerobic conditions by performing a turbid operation It became clear that culture | cultivation of was possible.
Furthermore, it has been found that it is effective to control the concentration of the organic acid and alcohol to be 200 mM or less.

[Example 2]
A method for producing biological hydrogen using Escherichia coli W strain (ATCC 9637).
After 4 hours from the start of the culture under anaerobic conditions, the main culture is centrifuged (5000 rpm, 15 minutes), the supernatant is removed, the anaerobic culture shown in Table 2 is added, and the microorganisms are added. Prepare the same procedure as in Example 1 except that the suspension is performed and further cultured for 4 hours, then repeated in the same manner, and cultured under anaerobic conditions for a total of 12 hours. Was measured in the same manner as in Example 1.

As a result, the hydrogen generation rate measured by the gas flow meter was 45 L (H ₂ ) / hr / L (reaction volume) per hour, and almost constant gas generation continued for about 3 hours.
The concentration of organic acid and alcohol present in the culture solution cultured under anaerobic conditions was measured using high performance liquid chromatography and gas chromatography, and the results of examining the concentration in the culture solution are shown in the figure. It is shown in 2. It was found that both the organic acid and alcohol concentrations were controlled to 100 mM or less at any stage of the culture time of 4, 8, and 12 hours.

According to the results of Example 1 and Example 2, the ability of microorganisms to generate hydrogen can be improved by controlling the concentration of organic acid and / or alcohol in the culture solution to 100 mM or less during culture under anaerobic conditions. found. From the above results, it was found that the method of controlling the concentration of the organic acid and / or alcohol in the culture solution during culture under anaerobic conditions to be in the range of 100 mM or less was found to be excellent.
Furthermore, the results of Example 2 revealed that the hydrogen generation rate necessary for the fuel cell is stable over a long period of time. This hydrogen generation rate also gives the fuel cell the ability to operate immediately when needed.

  According to the present invention, hydrogen can be produced industrially advantageously.

Claims (4)

The cells obtained by culturing Escherichia coli under aerobic conditions and proliferating are replaced under anaerobic conditions by replacing the culture medium with the culture medium before culture once every 4 to 6 hours . A method for imparting hydrogen-producing ability to Escherichia coli , wherein the culture is performed while controlling the concentration of acetic acid, lactic acid, and ethanol in the culture solution . The method according to claim 1, wherein Escherichia coli is separated from the culture solution, and the culture solution before the culture is added to suspend Escherichia coli , thereby replacing the culture solution with the culture solution before the culture. The method according to claim 1 or 2 , wherein Escherichia coli does not divide and proliferate in culture under anaerobic conditions. The method according to any one of claims 1 to 3 , wherein the concentrations of acetic acid, lactic acid, and ethanol in the culture solution are each controlled to 200 mM or less.