KR20110049347A - Method for producing hydrogen gas and methane gas using by-product from ethanol fermentation of marine algae - Google Patents

Abstract

PURPOSE: A method for producing hydrogen gas and methane gas using ethanol fermentation by-products of sea algae is provided to efficiently use surplus resources and recycle waste algae. CONSTITUTION: A method for producing hydrogen gas and methane gas comprises a step of performing anaerobic fermentation of Sargassum thunbergii, Macroalgae, laminaria japonica, scytosiphon, brown seaweed magnet, ecklonia cava, ecklonia stolonifera, rhei Rhizoma, seersucker, or gulfweed at 10-50°C for 10-100 hours, and a step of controlling the concentration of sodium salt of ethanol fermentation by-products of sea algae.

Description

METHODS FOR PRODUCING HYDROGEN GAS AND METHANE GAS USING BY-PRODUCT FROM ETHANOL FERMENTATION OF MARINE ALGAE}

The present invention relates to a method for producing hydrogen gas and methane gas using ethanol fermentation by-product of seaweed. More specifically, the present invention relates to a method of producing hydrogen gas and methane gas, by producing bioenergy using ethanol fermentation by-products, which can efficiently use surplus seaweed resources, and effectively recycle waste seaweeds discarded.

Bioenergy refers to an energy source made from biomass such as animals, plants, and microorganisms, and is also called biomass energy.

In the past, in order to produce bioenergy, a method of directly burning biomass was used, but recently, organic or organic wastes have been 1) biochemical conversion process using enzymes or microorganisms; 2) photobiological conversion process using photosynthetic microorganisms; Or 3) a method of producing a liquid fuel such as ethanol, methanol, biodiesel, Fischer-Tropsch diesel, or a gaseous fuel such as hydrogen or methane through a thermochemical conversion process using thermal energy and a chemical catalyst. It is used. These biomass energy sources are spotlighted as alternative energy sources because they can be stored and regenerated and are environmentally safe.

Biomass, which is a raw material of bioenergy, is divided into sugar system (sugar cane, sugar beet, etc.), starch system (corn, potato, sweet potato, etc.), and wood system (wood, rice straw, waste paper, etc.). The technology for producing bioenergy using and starch-based raw materials has been commercialized. However, the bioenergy production technology using sugar and wood has a problem of using food as an energy source, and if food demand increases in the future, there may be a problem in supply and demand of raw materials, and economically using grain. This is a problem in terms of raw material costs. In addition, cultivation of crops such as sugar cane or corn requires a significant amount of pesticides, which may cause environmental problems. Extensive clearing of rainforests and grasslands for growing corn or sugar cane, which are raw materials of bioenergy. As a result, a problem of increasing greenhouse gas emissions may occur.

In order to solve this problem, bioenergy production technology using seaweed instead of onshore biomass has been studied. The algae grow fast, and green algae in the upper layer, brown algae in the middle layer, and red algae in the lower layer grow mainly according to the depth of the sea, and thus have higher productivity than the biomass on land through the complex culture. As of 2008, a total of 934,890 tons of seaweeds are produced in Korea in the shallow and aquatic fisheries, and the domestic aquaculture area is about 76,183 ha, which means that the country's exclusive economic zone is 4.49 million ha. With the development of technology such as the development of culture technology, the production of seaweed is expected to increase further.

In particular, many studies have been conducted on bioethanol production technology among bioenergy technologies using algae. Specifically, the algae are pre-treated to be glycosylated, and sugar components such as glucose and galactose generated in the saccharification process are converted to ethanol using microorganisms. Technology is commercialized.

However, bioethanol production technology using algae does not have high production efficiency of energy, and there is a problem of generating excess by-products or wastes in the process of producing bioethanol.

The present invention is to provide a production method of hydrogen gas and methane gas by using bioethanol by-products of ethanol fermentation of seaweed to efficiently use the surplus algae resources, and can effectively recycle the waste seaweeds discarded. .

The present invention provides a method for producing hydrogen gas and methane gas comprising anaerobic fermentation of ethanol fermentation by-products of seaweeds.

Hereinafter, a method of producing hydrogen gas and methane gas according to a specific embodiment of the present invention will be described.

Unless otherwise expressly stated, some terms used herein are defined as follows.

As will be apparent to those skilled in the art, 'ethanol fermentation means a method or process for producing ethanol, a bio-energy by fermenting algae using microorganisms. As a specific example thereof, bioethanol production includes converting carbohydrates contained in seaweed into monosaccharides such as glucose or galactose by biological or chemical saccharification, and fermenting the monosaccharides to ethanol using microorganisms. A method is mentioned.

In addition, the 'ethanol fermentation by-product' used in the specification of the present invention includes all remaining solids and soluble components after the ethanol fermentation process using the seaweed, and specifically includes alginate, laminaran, mannitol or other organic substances. Include.

In general, since a large amount of seaweed must be used to produce bioethanol, the amount of the ethanol fermentation by-products generated during the ethanol fermentation process of seaweed is also considerable, which makes it difficult to process and recycle methods thereof. none.

On the other hand, according to one embodiment of the invention, there can be provided a method for producing hydrogen gas and methane gas comprising the step of anaerobic fermentation of ethanol fermentation by-product of seaweed.

The inventors have found out that fermentation of ethanol fermentation by-products of algae can be produced under anaerobic conditions to produce hydrogen gas and methane gas as bioenergy. As a result, not only bioethanol can be produced using algae, but also ethanol fermentation by-products can be used to produce hydrogen gas and methane gas, which are biogases, thereby increasing the efficiency of bioenergy production from algae and reducing waste algae. It can be recycled effectively.

In addition, methane gas produced from algae has a higher content of methane and higher calorific value than natural gas, which can increase the output of a mechanical engine when used as fuel, and the exhaust gas is also environmentally friendly. In addition, hydrogen gas produced from seaweed has little emission of pollutants, except that a very small amount of nitrogen is produced during combustion, and is easily applied to fuels such as direct combustion and fuel cells. Therefore, according to one embodiment of the present invention, it is possible to produce hydrogen gas and methane gas which are high in fuel efficiency, applicable to various fields, and are environmentally friendly and bioenergy.

Meanwhile, the algae may include green algae, brown algae and algae, preferably brown algae, and more preferably kelp. The green algae include greens, chlorella (cheongtae) or the auditory, and the like, the red algae include laver, sea urchin, or carrageenan, and the brown algae are brown seaweed, kelp, halibut, fresh green onion, shellfish, hooked plum, and brown seaweed. It may include iron, Ecklonia cava, gompi, rhubarb, iron seaweed cousin, mother and child, mackerel, mackerel, or larvae.

The algae used for the ethanol fermentation may be subjected to a pretreatment step performed by thermal treatment, physical treatment and chemical treatment alone or in combination. And, the ethanol fermentation step may include a known saccharification method that can be applied to convert the carbohydrates contained in the algae to monosaccharides. Specific examples of the saccharification method include a biological saccharification method that decomposes carbohydrates of algae using mold, bacteria, yeast or enzymes, or a chemical saccharification method that decomposes carbohydrates of algae into monosaccharides by adding an acid or a base. have. Accordingly, the ethanol fermentation by-product of the seaweed may contain a large amount of salt components due to the acid or base added during the ethanol fermentation. However, it is apparent to those skilled in the art that the pretreatment step and the saccharification method applied in the ethanol fermentation step are not limited to the above description, and any method known to be applicable to the step of fermenting algae to produce ethanol can be used without particular limitation. .

As a result of the experiments, the inventors have found that the production of hydrogen gas and methane gas increases rapidly within the range of the sodium salt concentration of the ethanol fermentation by-product of the seaweed is 0.01 to 1.00 N, preferably 0.05 to 0.50 N. Specific examples of the sodium salt include sodium chloride (NaCl) and sodium sulfate (Na ₂ SO ₄ ). As described above, in the ethanol fermentation process of seaweeds, since acids or bases are added for hydrolysis of seaweeds, ethanol fermentation by-products may include a large amount of salt components. In one embodiment of the present invention, As described in Examples and Experimental Examples, it was confirmed that the production amount of hydrogen gas and methane gas varies depending on the concentration of the salt contained in the ethanol fermentation by-product, and the optimum concentration of sodium salt showing the maximum gas yield was found. Thus, by adjusting the sodium salt concentration of the ethanol fermentation by-products it is possible to further increase the amount of hydrogen gas and methane gas that can be produced from the ethanol fermentation by-products and their production efficiency.

Accordingly, one embodiment of the invention may further comprise the step of adjusting the concentration of the sodium salt of the ethanol fermentation by-product of seaweed. Sodium salts such as sodium chloride (NaCl) or sodium sulfate (Na ₂ SO ₄ ) may be added to adjust the concentration of the sodium salt.

The anaerobic fermentation may use a solution containing anaerobic microorganisms or anaerobic microorganisms.

The anaerobic microorganism is not particularly limited in the case of a microorganism capable of smoothly performing metabolic processes in anaerobic conditions, preferably the anaerobic microorganism is Clostridium butylicum ( Clostridium butylicum ), Clostridium pasteurianum ), Clostridium kluyveri , Diplococcus glycinophilus ), Escherichia coli), Bacillus miksa poly (Bacillus polymyxa ), Aeromonas hydrophila hydrophila ), Bacillus maserans macerans ), Desulfovibrio , Desulfuricans , Nonsulfur Purple Bacteria purple bacteria , Methylotrophs , Methanogenic bacteria , Rumen bacteria), the microorganism may be one or more member selected from the group consisting of Al kaeah (Archaea) and Enterobacter (Enterobacter). In the case of anaerobic microorganisms, hydrogen gas and methane gas are produced from ethanol fermentation by-products, which is faster than the fermentation process using photosynthetic microorganisms, and a large amount of gas is generated and light energy is not required.

The anaerobic microorganism is an example of centrifugation of activated sludge in sewage at 1 ° C. to 10 ° C. and 500 to 5,000 rpm for 1 to 10 minutes, followed by an upper layer of activated sludge in the sewage. It may be obtained by separating the liquid. The activated sludge of the sewage may include activated sludge obtained during the anaerobic sewage treatment process.

The reaction solution containing the anaerobic microorganism may be a culture cultured the anaerobic microorganism, and includes the culture of the anaerobic microorganism obtained by separating the supernatant of the activated sludge to perform the centrifugation to the culture medium.

The anaerobic fermentation may be performed at 10 to 50 ° C., preferably at 25 to 40 ° C., for 10 to 100 hours, preferably for 60 to 80 hours. If the temperature of anaerobic fermentation is less than 10 ° C or more than 50 ° C, fermentation by anaerobic microorganisms may be lowered. In addition, if the time of anaerobic fermentation is too short, fermentation for the production of hydrogen gas and methane gas may not be effective, and unnecessarily long time fermentation is undesirable in view of the efficiency of the production process.

The anaerobic fermentation may be carried out in an atmosphere having a volume content of oxygen of 0 to 5%, preferably 0 to 3%, more preferably 0 to 1%. Such atmospheric conditions may be obtained by injecting nitrogen gas into the culture vessel in which anaerobic fermentation takes place for 10 to 30 minutes to remove oxygen, but are not limited thereto, and are generally used to form an atmosphere suitable for anaerobic fermentation. The method can be used without any limitation.

According to the present invention, by producing bio-energy by using ethanol fermentation by-products, there is provided a method for producing hydrogen gas and methane gas that can efficiently use the surplus algae resources, and can effectively recycle the waste algae discarded.

The invention is explained in more detail in the following examples. However, the following examples are merely to illustrate the invention, but the content of the present invention is not limited by the following examples.

< Example : Production of Hydrogen Gas and Methane Gas Using Ethanol Fermentation By-product of Seaweed>

Example 1

Saccharomyces as a Yeast Strain for Ethanol Fermentation of Seaweeds cerevisiae was used and cultured in YPD medium (glucose 20 g / L, peptone 20 g / L, yeast extract 10 g / L) and inoculated in a medium of 20 g / L kelp pulverized in a ball mill, ethanol Fermentation was carried out.

Sodium chloride solution was added to adjust the concentration of sodium salt of the ethanol fermentation by-product of kelp to 0.05N, 0.10N, 0.50N, 1.0N and 1.5N.

The precipitate was collected by centrifugation at 2,000 rpm, 10 min, and 4 ° C., and the supernatant was collected. The supernatant was collected from 20% glycerol to make a stock. Frozen at 70 ° C.

The ethanol fermentation by-product of kelp was placed in an Erlenmeyer flask, and the frozen sludge was dissolved at room temperature, and 1 ml of 1% (v / v) per 100 ml of the ethanol fermentation by-product was added as cells. In addition, nitrogen gas was injected into the Erlenmeyer flask for 20 minutes to remove oxygen, and then sealed, and cultured under anaerobic conditions for 12 hours at 144 hours in a microbial incubator to produce hydrogen and methane gas.

Example 2

Hydrogen gas and methane gas were produced in the same manner as in Example 1 except that sodium sulfate was added instead of sodium chloride to adjust the concentration of the sodium salt of the ethanol fermentation by-product of the seaweed.

< Experiment  Example>

Experimental Example 1 : Measurement of the production of hydrogen gas and methane gas

Hydrogen gas and methane gas produced in Examples 1 and 2 were measured using a high-density gas detector (Model No. XP-3140, Comos Inc., Japan). The measured results are shown in Table 1 below. In addition, the production amounts of hydrogen gas and methane gas according to the concentrations of sodium chloride (Example 1) and sodium sulfate (Example 2) are shown in FIGS.

Table 1

Salt Normal
(N) H ₂
(ml / L) CH ₄
(ml / L) Total gas
(g / L) NaCl 0.01 145.69 653.09 0.437 0.05 202.66 975.76 0.651 0.1 254.74 1375.61 0.915 0.5 220.86 1043.63 0.700 1.0 97.36 579.501 0.385 1.5 - 96.59 0.063 Na ₂ SO ₄ 0.01 103.03 632.23 0.420 0.05 236.62 1248.10 0.831 0.1 256.21 1281.041 0.854 0.5 138.901 270.091 0.178 1.0 29.65 106.73 0.066 1.5 - 89.44 0.058 Non salt * - 118.02 0.077

According to this, it can be seen that the production of hydrogen gas and methane gas is rapidly increased in the range of sodium chloride or sodium sulfate concentration of 0.01 to 1.00 N. In particular, it can be seen that within the range of sodium chloride or sodium sulfate concentration of 0.05 to 0.50 N more than 150 ml of hydrogen gas and more than 900 ml of methane gas per liter. In addition, hydrogen gas and methane gas are produced at maximum concentrations of sodium chloride at 0.1 N (254.74, 1375.61 ml / L, respectively) and hydrogen and methane gas production at maximum concentrations of sodium sulfate of 0.05 N (236.62, 1248.10, respectively). ml / L) can be confirmed.

As described above, according to one embodiment of the present invention, since hydrogen gas and methane gas can be produced using ethanol fermentation by-products of seaweed, efficient use of the seaweed surplus resources is made possible, and the effective recycling of discarded waste algae is possible. Do.

In addition, according to the production method of hydrogen gas and methane gas according to an embodiment of the present invention, the waste algae is recycled by finding the optimal concentration of sodium salt capable of producing the maximum hydrogen gas and methane gas from the ethanol fermentation by-product of seaweed. In the process, the production and productivity of hydrogen gas and methane gas can be further increased.

Figure 1 shows the amount of hydrogen gas and methane gas produced in Example 1 according to the sodium chloride concentration.

Figure 2 shows the amount of hydrogen gas and methane gas produced in Example 2 according to the sodium sulfate concentration.

Claims (10)

Process for producing hydrogen gas and methane gas comprising the step of anaerobic fermentation of ethanol fermentation by-product of seaweed. The method of claim 1, The seaweed is one or more brown algae selected from the group consisting of seaweed, kelp, barn horse, folk eggplant, shellfish, hawk seaweed, seaweed, Ecklonia cava, gompi, rhubarb, iron seaweed cousin, mabanban, hoesan mabanban, jichung and 및 Hydrogen gas and methane gas production method comprising a. The method of claim 1, The anaerobic fermentation is a method of producing hydrogen gas and methane gas using an anaerobic microorganism or a solution containing anaerobic microorganisms. The method of claim 1, The anaerobic fermentation is a method for producing hydrogen gas and methane gas at 10 to 50 ℃ for 10 to 100 hours. The method of claim 1, Always anaerobic fermentation is a method for producing hydrogen gas and methane gas in the atmosphere with a volume content of oxygen of 0 to 5%. The method of claim 1, The method for producing hydrogen gas and methane gas having a concentration of sodium (Na) salt of the ethanol fermentation by-product of the seaweed is 0.01 to 1.00 N. The method of claim 1, A method for producing hydrogen gas and methane gas in which the concentration of sodium (Na) salt of the ethanol fermentation by-product of the seaweed is 0.05 to 0.50 N. The method according to claim 5 or 6, The sodium salt is a method of producing hydrogen gas and methane gas containing sodium chloride (NaCl) or sodium sulfate (Na ₂ SO ₄ ). The method of claim 1, A method of producing hydrogen gas and methane gas further comprising the step of adjusting the concentration of sodium salt of ethanol fermentation by-product of seaweed. 10. The method of claim 9, Adjusting the concentration of the sodium salt is a method of producing hydrogen gas and methane gas comprising the addition of sodium chloride (NaCl) or sodium sulfate (Na ₂ SO ₄ ).

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