KR20140075050A - Method for Culture of algae, method for storage thereof, and uses thereof - Google Patents

Abstract

The present invention relates to a culture device for culturing a large number of algae required for providing a biological soil crust inducer, a culturing method of algae using the same, a storing method of the cultured algae, a storing kit for the same and a biological soil crust inducer comprising the cultured algae.

Description

[0001] The present invention relates to a method for culturing algae,

TECHNICAL FIELD The present invention relates to a method for culturing algae, a method for storing algae, and a use thereof, and more particularly to a method for algae culture, a method for culturing algae using the same, a method for storing algae and a storage kit therefor, An induction agent and a production method thereof.

Conventionally, a cylindrical culture apparatus was used as a culture apparatus for culturing algae, as shown in Fig. Such a cylindrical incubator has a structure in which air is supplied to the lower portion and the upper portion is sealed with a lid or the like (see FIG. 1).

However, the conventional cylindrical incubator has a structure suitable only for small capacity cultivation. Because it is a closed structure, it is difficult to supply carbon dioxide necessary for growing algae, and it is difficult to control the proper amount when carbon dioxide is mixed into the lower air supply portion. There was a problem that it adversely affected. In addition, algae tend to attach to the substrate and grow in a stable state. Therefore, when the culture is carried out over a certain amount, sufficient light source is not sufficiently penetrated through the wall of the incubator. In addition, there is a problem that collection of algae after culturing is not easy.

In addition, there have been various problems when conventional algae are cultured and stored for a long period of time. Specifically, when the collected algae are centrifuged and stored in a refrigerator at a temperature of about 5 ° C, the storage period of the algae is as short as one month, and the stored algae can not be used after about one month. When the collected algae are centrifuged and transferred to a sterilized liquid medium and refrigerated in a state in which a weak light source is supplied, the collected algae can be stored for about 2 months longer than 1 month, but they can not be used because of corruption. It was troublesome to periodically change the liquid medium.

On the other hand, due to the recent environmental changes caused by industrial development, desert regions, which occupy more than one third of the entire land area, are gradually expanding. These desert areas are generally barren lands where vegetation is low and vegetation is hardly growable, while rainfall is low.

The main causes of desertification are considered to be a combination of anthropogenic and climatic causes. Anthropogenic causes include irrigation, deforestation, and environmental pollution. Climatic factors include drought and desiccation. Desertification is a rapidly growing area, especially in areas where precipitation is less than evapotranspiration in terms of climatic conditions. According to the 1984 report of the UNEP, the desert is expanding around the area of existing deserts, as well as in other regions as a speed 60,000 km ² per year. Countries that are experiencing serious drought or desertification are working together to conclude the Convention on the Prevention of Desertification.

The desert is a dry area with strong day and night temperature differences. It does not have enough rainfall to absolutely lack water for people, plants and animals. To supply water to these areas, And the like are used. However, these methods have the disadvantage of requiring a separate water feed system in a remote area from the sea and drastically deeper drilling for groundwater development, so that it takes a lot of time and cost to obtain water. In other words, the existing irrigation system for desert greening is troublesome to supply water to the plant through the water supply facility every day or every 3-5 days, and more than 65% of the water supply is evaporated during the water supply, And the waste of water has been repeated. However, there is a limitation in that it is not possible to plant trees in places where there are no facilities for the construction of water pipes or irrigation facilities, or trees that can withstand drought are planted. However, this is also a very high rate of mortality. Also, the desert is very windy with sand because of the remarkable temperature difference between day and night. Even if you plant trees in the desert by the sand wind, there is a problem of buried in the sand before it grows properly.

Accordingly, the present inventors have made efforts to develop a desertification prevention method using a lichen as a method for preventing desertification without a high-cost irrigation facility, and a method for mass culturing algae, The present invention has been completed by developing a bio-soil film-directing agent for applying these algae to desertification prevention.

It is an object of the present invention to provide a culture apparatus for mass-culturing algae for application to a biological soil film-forming agent.

It is another object of the present invention to provide a method for culturing algae using the culture apparatus.

It is another object of the present invention to provide a method for storing algae for application to a biological soil film-directing agent.

It is another object of the present invention to provide a biological soil film-directing agent comprising the above-mentioned cultured or stored algae and vermiculite.

It is another object of the present invention to provide a method for producing the biological soil film-forming agent.

The alga culturing apparatus of the present invention comprises: a case through which a light source can pass; A water current motor and an aeration device provided in a lower portion of the case; And a culture unit for culture by attaching algae, wherein the culture unit comprises: first and second adsorption plates attached at the same height on both opposite sides of the inside of the case; Third and fourth adsorption plates attached to the first and second adsorption plates at a position shifted a certain distance to the left or right side in a direction directly underneath the first and second adsorption plates; A first connection unit connecting the first and third adsorption plates; A second connecting portion connecting the second and fourth attracting plates; And an attachment part fixed to the first and second connection parts and to which at least one of a lichen symbiotic alga and a cyanobacteria is attached and cultured.

The attachment portion of the culture apparatus of the present invention has a space of a certain area.

The attachment portion of the culture apparatus of the present invention is characterized by being a fabric or a net.

The culturing method of the present invention is characterized in that any one or more of a lichen symbiotic algae and a cyanobacteria are supplied to the culturing apparatus and at least one of a lichen symbiotic alga and a cyanobacteria is attached to an attachment portion of the apparatus, do.

The storage method of the present invention is characterized in that a plurality of vermiculite grains having a size of 1 cm ³ or less on the upper and lower surfaces of the attachment portion where the at least one of the ligament symbiotic algae and the cyanobacteria are adhered and cultured by the above- And the bottom surface is covered with all of them.

The storage method of the present invention is characterized in that any one or more of the lichen symbiotic algae and the cyanobacteria is mixed with a large number of vermiculite particles having a size of 1 cm ³ or less and stored.

Further, the storage method of the present invention is characterized in that storage is performed at a temperature of 22 to 27 캜 and a relative humidity of 60 to 80%.

The storage method of the present invention is characterized in that the vermiculite particles contain 10 to 50% by weight of water relative to the weight of the vermiculite particles.

Further, in the above-mentioned storage method of the present invention, the mixing is characterized in that the weight ratio of the vermiculite to the at least one of the vermiculite algae and the cyanobacteria is 2 to 5: 1.

The biological soil film-directing agent of the present invention is characterized by containing at least one of vermiculite, a symbiotic algae and a cyanobacteria.

Further, at least one of the lichen symbiotic algae and the cyanobacteria contained in the biological soil film-forming agent of the present invention is characterized in that it is attached to the vermiculite.

In addition, the biological soil film-forming agent of the present invention is characterized by being stored by the above-mentioned storage method.

According to the present invention, it is easy to cultivate a large amount of algae for application to a biological soil film-forming agent, and it can be stored over a long period without any additional apparatus and conditions. In addition, the bio-soil-encapsulating agent containing algae according to the present invention can be safely transported to an area where restoration of an ecosystem such as desert is required, and can be applied to restoration of an ecosystem.

1 is a photograph of a conventional algae culture apparatus.
2 is a perspective view of a bird's culture apparatus according to an embodiment of the present invention.
3 is a front view of a bird's culture apparatus according to an embodiment of the present invention.
FIG. 4 is a detailed view illustrating a culture unit provided in the apparatus for culturing algae according to an embodiment of the present invention.
FIGS. 5 and 6 are electron microscopic images of alga cultured in an algae culture apparatus according to an embodiment of the present invention.
FIG. 7 is a photograph of an attachment part of a culture part in which a bird is adhered and cultured in an algae culture apparatus according to an embodiment of the present invention.
FIG. 8 is a view illustrating a state in which an attachment part is placed on vermiculite particles for storing algae using an attachment part of a culture apparatus in which algae have been cultivated according to an embodiment of the present invention.
FIG. 9 is a view showing a state in which vermiculite grains are accumulated on upper and lower portions of an attachment portion in order to store algae using an attachment portion of a culture apparatus in which algae have been cultivated according to an embodiment of the present invention.
FIG. 10 is a view showing a state where algae are mixed with vermiculite and then stored according to an embodiment of the present invention.
FIG. 11 is a view showing a state where algae are mixed with vermiculite and then stored according to an embodiment of the present invention.
12 and 13 illustrate a state where algae are attached to vermiculite according to an embodiment of the present invention.

These and other objects, features and other advantages of the present invention will become more apparent by describing in detail preferred embodiments of the present invention with reference to the accompanying drawings. Hereinafter, an apparatus for culturing algae, a method for culturing algae, etc. according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In the present invention, "algae" refers to algae symbiotic algae and cyanobacteria for application to biological soil coatings.

The above-mentioned " lichen symbiotic bird "of the present invention refers to algae or cyanobacteria that constitute a part of the lichen and its body and can perform photosynthesis by chlorophyll.

The term " lichen "refers to a symbiotic complex of lichen forming fungi with algae and / or cyanobacteria.

The term "thallus" as used herein refers to a nutritional product of lichens, symbiotic algae or cells of cyanobacteria, and mycelium of fungi forming fungi, and for lichen,

The algae included in the present invention include, but are not limited to, T. asymmetrica , T. impressa , T. jamesii , T. usneae , Magna such as T. magna), Erie value (T. erici), corticotropin La (T. corticola) such Trevor woosiah (Trebouxia) genus, Pseudomonas Trevor woosiah (Pseudotrebouxia) in spa Era (Stichococcus diplosphaera) a styryl Coco coarse deep styryl Coco carcass (Stichococcus) there is a genus, etc. Transistor tepo Liao (Trentepohlia) in such Tina (Trentepohlia abietina), O rugi labor (Trentepohlia aeruginosa), Aurea (Trentepohlia aurea), are Bohrium (Trentepohlia arborum) in the AVI .

The "cyanobacteria" of the present invention refers to a bacterium that constitutes a part of a lichen and its body, and which performs aquatic photosynthesis. Examples thereof include furnace Stock comb Sori (Nostoc commune), no stock Carne Titanium (Nostoc carneum), no stock plastic gelri formate methoxy (Nostoc flagelliforme Born et Flsh) no stock (Nostoc), A ringeu via Cri Toba group or tooth, such as ( Lyngbya crytovainatus Schk) such ringeu vias (Lyngbya), a micro collection mouse Bagi or tooth (Microcoleus Vaginatus (Vauch) Gom) including a micro-collection-house (Microcoleus), An Analog vena (Anabaena), a croissant Lactococcus epitaxial repetition of the Goose ( Chrococcus epiphyticus), including the Black Cocker tm (Chrococcus) in, in Cap-four (Gloecapsa) to him, FORT Medium Te Nuevo (Phormidium tenue), such as the Fortis Medium (Phormidium) in, ski weekends and Cinema Now Pony Qom (Scytonema japonicum), etc. Scythonema genus, Synechocystis genus such as Synechocystis pevalekii , genus Calothrix genus, and genus Tolypothrix genus.

In the present invention, "verniculite" is a mineral composed of potassium nitrate (KNO ₃ ) which is produced by dry weathering of rocks or soils in a dry area such as a desert. The "verniculite" is lightweight, has excellent water absorption and moisturizing power, has a rough surface, and is excellent in air permeability because of its porous nature. Therefore, it is possible to prevent the propagation and storage of the above-mentioned lichen symbiotic algae and cyanobacteria And is useful as a bio-soil film-forming agent.

The present invention provides an alga culturing apparatus (1) as an embodiment.

Hereinafter, the algal culture apparatus 1 of the present invention will be described with reference to the drawings shown in Figs. 2 to 3. Fig.

An alga culturing apparatus (1) of the present invention comprises a case (10) through which a light source can pass; A water flow motor 30 and an aeration device 40 provided below the case 10; And a culture unit 20 for incubation with an algae.

The case 10 of the present invention is made of a material that can be transmitted by a light source for photosynthesis of a bird to be cultured. Examples of materials that the light source can transmit include glass, acrylic, and the like.

The water-current motor (30) of the present invention is for supplying water and oxygen dissolved in water in the alga culturing apparatus (1) in a predetermined direction smoothly to the algae, and a normal water current motor suffices.

The aeration device 40 of the present invention is for supplying oxygen and carbon dioxide necessary for the growth of algae into the algal culture apparatus 1, and it is sufficient that the conventional aeration device 40 is used. The aeration device 40 can timely supply an appropriate amount of oxygen and carbon dioxide during the course of culturing the algae.

The culture unit 20 of the present invention comprises a first adsorption plate 22 and a second adsorption plate 23 attached to the case at the same height on both opposite sides of the inside of the case 10; A third attracting plate 24 and a fourth attracting plate 25 attached at positions shifted from the first attracting plate 22 and the second attracting plate 23 by a predetermined distance to the left or right side, respectively; A first connecting portion 26 connecting the first attracting plate 22 and the third attracting plate 24; A second connecting portion 27 connecting the second attracting plate 23 and the fourth attracting plate 25; And an attachment part (21) fixed to the first connection part (26) and the second connection part (27) and in which at least one of algae, a symbiotic algae and a cyanobacteria are adhered and cultured, do.

The first and second adsorption plates 22 and 24 and the fourth adsorption plate 25 are attached to the case while the first and second connection portions 26 and 27 are coupled to each other. . The attachment portion 21 fixed to the first connection portion 26 and the second connection portion 27 is not affected by the flow of water by the water flow motor 30 and the aeration device 40 in the case 10 And can be stably fixed.

The first adsorption plate 22 and the second adsorption plate 23 are adsorbed at the same height on the opposite surface of the case 10. The third attracting plate 24 is attracted to the first attracting plate 22 in a diagonally opposite direction from the first attracting plate 22, and is attracted to the first attracting plate 22 in a diagonal direction. The fourth attracting plate 25 is moved in the direction of one of the left and right sides of the second attracting plate 23 in the same direction as the attracting of the third attracting plate 24, Is adsorbed at the same height on one surface and forms an oblique direction to the second adsorption (23).

As described above, the adsorbed first adsorption plate 22 and the third adsorption plate 24 are fixedly connected to the first connection portion 26, and the second adsorption plate 23 and the fourth adsorption plate 25 are connected to the second connection portion 26, (27).

The first connecting portion 26 and the second connecting portion 27 serve to connect the first sucking plate 22 and the third sucking plate 24 and the second sucking plate 23 and the fourth sucking plate 25, And also serves to fix the attaching portion 21.

The attachment portion 21 is for attaching and cultivating a bird, that is, a lichen planus algae and / or a cyanobacterium. It is preferable that the attachment portion 21 is irregularly or regularly formed in the attachment portion 21 so as to facilitate attachment of algae. For example, the attachment portion 21 may be a fabric or net, and preferably a fabric. In addition, since the attachment portion 21 can be used in storage of algae described below or artificial inducer of biological soil film, it is preferable that the attachment portion 21 is decomposed and used as a nutrient source for birds after a lapse of a predetermined period of time.

On the other hand, the space is preferably 0.5 cm ² or less, more preferably 0.5 cm ² to 0.01 cm ² , and still more preferably 0.3 cm ² to 0.01 cm ² .

The algal culture apparatus (1) of the present invention may further include an exhaust port (not shown) for draining water in the algal culture apparatus (1).

The method for culturing algae using the above-described alga culturing apparatus 1 will be described in more detail.

In one specific method, water is put into the alga culturing apparatus 1 and at least one of algae, that is, algae symbiotic algae and cyanobacteria, is supplied. These supplied algae flow along with the flow of water by the water current motor 30 of the alga culturing apparatus 1 and are attached to the attachment unit 21 in the cultivation unit 20 of the algal culture apparatus 1, . In the growth, these algae are dissolved in water, oxygen and oxygen supplied from the aeration device 40, and absorb the dissolved oxygen and carbon dioxide, and grow through photosynthesis.

In another specific method, at least one of the algae, that is, the symbiotic algae and the cyanobacteria, is attached to the attachment part (21) in the culture part (20) of the algal culture device (1) And the power is applied to operate the water-current motor 30 and the aeration device 40. The water- These water motors 30 and the aeration device 40 absorb dissolved oxygen and carbon dioxide necessary for the growth of algae and grow through photosynthesis.

On the other hand, the water used in culturing the algae by the above-described method is preferably fresh water. The fresh water is also preferably passed through a filter to remove dissolved ions that are not suitable for culturing foreign matter and algae.

Further, in culturing the algae by the above-mentioned method, the incubation temperature is preferably 23 to 26 캜, and most preferably 25 캜, as a temperature suitable for culturing algae.

In addition, in the case of culturing the algae by the above-mentioned method, the supply amount of carbon dioxide is 1,200 to 1,700 ppm, preferably 1,400 to 1,600 ppm in the daytime based on 1 kg of water. In addition, the light intensity necessary for photosynthesis of algae is 5,000 to 12,000 lux, preferably 5,000 to 11,000 lux, more preferably 8,000 to 11,000 lux.

When the algae are cultured by the alga culturing apparatus 1 and the culturing method described above, they are attached to the attachment portion 21 of the culture unit 20 rather than the inner surface of the alga culturing apparatus 1 according to the attachment properties of the algae to the substrate The light source is irradiated to the inside of the algal culture apparatus 1, so that the algae are cultured at a constant rate and at a high speed.

Particularly, in the case of culturing by the above-mentioned culturing method, it is confirmed that algae (for example, cyanobacteria) adhered to the attachment portion 21 of the culture unit 20 of the culture apparatus 1 of the present invention are closely attached and cultured (See FIG. 7). 5 and 6), a polysaccharide or the like is generated from algae, and cultivation is carried out in a state where algae and algae are connected to each other (see, for example, . In addition, the attached part 21 cultured with algae can be directly used as a component of the bio-soil film-directing agent without any special process, and the algae can be easily stored.

Another embodiment of the present invention provides a method for storing (storing) the cultured alga.

One of the methods of storing algae according to the present invention is characterized in that the vermiculite particles cover both the upper surface and the lower surface of the attachment portion 21 to which the cultured algae are attached.

Features of such a storage method can be more clearly seen from Figs. 8 and 9. Fig.

In the above-mentioned storage method, the vermiculite is as described above, and the vermiculite particles have a volume of 1 cm ³ or less, preferably 0.01 to 1 cm ³ , more preferably 0.01 to 0.5 cm ³ . When the vermiculite particles have a volume exceeding 1 cm ³ , the amount of vertebrate particles required for storage is low because of the small amount of algae adhered to the vermiculite particles, and there is a problem that a large space is required for storage thereof. Therefore, .

Further, the vermiculite particles are characterized by being sterilized. This is because there is a problem that algae adherence and growth are inhibited by other microorganisms attached to the vermiculite particles and parasitized, resulting in dead birds.

The vermiculite particles preferably contain 10 to 50% by weight, preferably 20 to 50% by weight, of water relative to the weight of the vermiculite particles. Since the vermiculite particles contain moisture, the moisture can be supplied to the algae attached to the vermiculite particles, so that the algae can be stored for a long period of time.

The above-mentioned storage method is advantageous in that it does not require a separate storage facility or pretreatment since only the upper and lower surfaces of the adhered portion 21 cultured with avian fluids are covered. Particularly, there is an advantage that the vermiculite particles protect the algae from a strong light source (for example, a light source of 15,000 lux or more) that inhibits the growth of the algae, and are stored while the algae grow in the upper and lower direction of the attachment portion 21 .

On the other hand, in the case of the above-mentioned storage method, it is preferable to maintain a temperature of 22 to 27 캜 and a relative humidity of 60 to 80% in order to prevent corruption of algae when stored.

Another method of storing algae according to the present invention is characterized by collecting only the cultured algae by washing the attachment part 21 with the cultured algae at high pressure and mixing the collected algae with the vermiculite particles do.

In the above-mentioned storage method, the volume and the sterilization state of the vermiculite particles and the moisture content are as described above.

In the above-mentioned storage method, it is preferable that the mixing is carried out at a weight ratio of 2 to 5: 1, preferably 2.5 to 3.5: 1, of algae collected from the attachment portion 21 and vermiculite particles.

After the lapse of a certain period of time, as shown in Figs. 9 and 10, the vermiculite particles are attached to each other by algae attached thereto (see Fig. 10) or attached with vermiculite particles (See Fig. 11).

According to the above-mentioned storage method, vermiculite particles protect birds from a strong light source (for example, a light source of over 15,000 lux or natural light) which can inhibit the growth of algae, and the water containing vermiculite is used by birds Therefore, there is an advantage that the bird can be prevented from drying and killing.

On the other hand, in the case of the above-mentioned storage method, it is preferable to maintain a temperature of 22 to 27 캜 and a relative humidity of 60 to 80% in order to prevent corruption of algae when stored.

When the algae are stored by the above-mentioned storage method, algae attached to the vermiculite can be stored without any corruption even after about 2 months, so that algae can be used at any time in the future. As a specific example, a state in which algae (for example, cyanobacteria) are adhered to the above vermiculite particles and is growing is shown in Figs. 12 and 13. Fig.

In the meantime, the present invention provides, as one specific embodiment, a storage kit for algae containing vermiculite particles and algae for the algae storage method described above, wherein the vermiculite particles constituting the algae storage kit And algae are as described above.

As another embodiment of the present invention, there is provided a biological soil film-directing agent comprising vermiculite particles and algae.

The organism soil-inducing agent of the present invention refers to a soil cluster to induce a soil layer in an extreme environment such as in a desertification zone.

The vermiculite particles and algae contained in the biological soil film-forming agent of the present invention are as described above, and algae are attached to the vermiculite particles. Here, the presence of the algae on the vermiculite particles can be realized by the method described in the above-mentioned algae storage method.

In addition to the vermiculite particles and algae, the present invention may further include at least one of a fungus-forming fungus and a paper body in addition to the vermiculite particles and algae.

Since the vital soil film-directing agent of the present invention contains a certain amount of water in the vermiculite particles, the algae can be supplied with water even under the extreme environment, and is protected by the vermiculite particles from the light source of strong illumination which hinders growth such as natural light Therefore, birds can grow and multiply without being killed. Such algae growth and propagation ultimately result in the formation of a soil layer (soil clusters) and provide a soil in which plants can grow in extreme environments such as desert.

1: culture apparatus
10: Case
20: Culture section
21:
22: First adsorption part
23: second adsorption part
24: Third adsorption section
25: Fourth adsorption part
26: first connection part
27: second connection portion
30: Water flow motor
40: Aeration device

Claims (10)

A case through which a light source can pass; A water current motor and an aeration device provided in a lower portion of the case; And a culture unit for culturing by attaching algae,
The culture unit may include:
First and second adsorption plates attached at the same height on both opposite sides of the case; Third and fourth adsorption plates attached to the first and second adsorption plates at a position shifted a certain distance to the left or right side in a direction directly underneath the first and second adsorption plates; A first connection unit connecting the first and third adsorption plates; A second connecting portion connecting the second and fourth attracting plates; And an attachment part fixed to the first and second connection parts and to which at least one of a lichen symbiotic alga and a cyanobacteria is attached and cultured. The method according to claim 1,
Wherein the attachment portion is a fabric or a net. A method of culturing an algae culturing apparatus according to any one of claims 1 to 3, wherein at least one of a lichen symbiotic algae and a cyanobacteria is supplied, and at least one of a lichen symbiotic algae and a cyanobacteria is attached to the attachment portion of the apparatus In the culture medium. The upper and lower surfaces of the attachment portion to which at least one of the lichen symbiotic algae and the cyanobacteria of the present invention is attached is covered with a large number of vermiculite grains having a size of 1 cm ³ or less and at least one of the lichen-like algae and the cyanobacteria is stored And storing the algae. The present invention is directed to a method of collecting algae that are cultured by washing with high pressure water at an attachment portion attached with any one or more of the lichen symbiotic algae and cyanobacteria of claim ^{3 and} then mixing the collected algae with a plurality of vermiculite grains having a size of 1 cm ³ or less, A method of storing algae characterized by storing at least one of algae and cyanobacteria. The method according to claim 4 or 5,
Wherein the storage is performed at a temperature of 22 to 27 DEG C and a relative humidity of 60 to 80%. The method according to claim 4 or 5,
Wherein the vermiculite comprises 10 to 50 wt% of water relative to the weight of the vermiculite particles. 6. The method of claim 5,
Wherein at least one of the vermiculite particles, the lichen symbiotic algae and the cyanobacteria are mixed at a weight ratio of 2 to 5: 1. Wherein at least one of the lichen planus algae and the cyanobacterium is attached to the vermiculite particles, wherein the at least one of the vernal algae and the cyanobacteria comprises at least one of vermiculite particles, Soil conditioner. 10. The method of claim 9,
Wherein the biological soil film-directing agent is stored by the method of any one of claims 4 to 8.

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