KR20160031839A - Photoreactive Apparatus and method for culturing microalgae - Google Patents

Abstract

The present invention relates to an apparatus and a method for culturing photoreactive microalgae which, more specifically, mixes a culture medium therein by a vortex phenomenon generated by spraying a culture solution and gas to the inside of the culture apparatus and can uniformly transmit light from a light source, installed in an outer center of the culture apparatus, to the culture medium as a plurality of culture apparatus are connected to each other by a discharge pipe and a supply pipe which are formed on one side of the culture apparatus. The apparatus for culturing photoreactive microalgae includes: the culture apparatus which has the bottom and the height with certain area, accommodates microalgae and the culture medium and has a gas outlet on an upper end portion; a supply pipe which is connected to one side of the culture apparatus and supplies the culture solution mixed with gas; a gas injection nozzle which is joined to one side of the supply pipe and can be controlled with pressure at a certain level; an injection hole which is formed on one end portion of the supply pipe and sprays the culture medium mixed with the gas to the inside of the culture apparatus; a discharge pipe which is formed on one side of a lower end portion of the culture apparatus and discharges the culture medium; and the light source which is installed on the outside of the culture apparatus and irradiate the culture apparatus with light.

Description

[0001] The present invention relates to a photoreactive microalgae culture apparatus,

The present invention relates to a photoreaction microalgae culture apparatus, and more particularly, to a photoreaction microalgae culture apparatus capable of agitating a culture liquid in a culture vessel through a vortex phenomenon generated by injecting a culture liquid in which a gas is mixed, Is connected to each other by a discharge pipe formed at the center or one side of the lower part of the incubator and a supply pipe so that the culture liquid can move and the light necessary for photosynthesis can be uniformly delivered from a light source installed outside the incubator.

Algae are generally referred to as 'all kinds of photosynthetic oxygen-producing photosynthetic organisms except for land plants (mossy plants, ferns, seed plants)' and 'it is impossible to define algae' Algae are a collection of diverse organisms.

Algae can be roughly divided into two categories: visible size, called macroalgae, and small size, which can only be seen by microscopes called microalgae (phytoplankton). Microalgae have the same structure as that of land plants, and their production capacity is higher than that of land plants. Most of them are single cell organisms with a diameter of about 3 ~ 30 ㎛, and they mainly proliferate by dividing into silent.

Because microalgae have higher CO ₂ absorption capacity than plants, they are fast growing and have no seasonality, so annual growth is possible if temperature conditions are met. The microalga also survive under the Far East, Antarctic ice, and also in the desert, a barren land. It also exists in soils, fresh water, seawater, air and tree trunks, and it reproduces everywhere, but many of the bird species have not been identified yet. The number of microalgae estimated to be present on the earth now is 200,000 to 10 million, and it is said that the microalgae are still unknown even though the number of reported microalgae is very low to about 40,000.

Since microalgae are cultivated in aquatic conditions such as freshwater seawater, the cultivation area of seaweeds is emerging as a new possibility for greenhouse gas reduction. In particular, the government is promoting algae as a carbon dioxide sink in international conventions in order to preserve and protect domestic industries against the International Climate Change Convention (UNFCCC).

Since microalgae can reach 30-70% of the biomass available, microalgae exhibits higher fuel productivity than conventional crops and does not compete with other crops in terms of land or space. Therefore, the current price of food resources and forest destruction It does not cause a secondary environmental problem.

In addition, bio-energy is expected to be greater effective in so different a contrast to the intangible of renewable energy such as wind power, solar power, solar power to produce energy, such as heat or electric type and the advantages that the preservation of Energy Excellence, CO ₂ emissions In addition, there is an advantage that birds do not compete with food, and they do not cause environmental destruction such as tropical forests, unlike plant cultivation. Therefore, biodiesel production technology using microalgae shows high productivity per unit area, so it can be said that it is suitable for domestic situation because there is no competition with food resources because it is easy to secure resources.

Recently, microbial utilization research has focused on biofuel production by raising prices of cereal resources due to biofuel production and concerns about food resources. In addition to basic research on genomes and genes of photosynthetic microorganisms, microbial improvement, Have been developed on a large scale.

Accordingly, it is possible to produce high value-added materials using photosynthetic microorganisms, and in particular, a technique for mass-culturing photosynthetic microorganisms in large quantities is essential for the biological carbon dioxide immobilization process, and thus the demand for a microalgae culture apparatus with high culture efficiency is increasing .

However, in the conventional microalga culture apparatus, when the microalgae, which are food organisms, are cultivated in the culture tank of 1 ton or more, the light source is installed on the upper part of the culture tank and the light source does not reach the lower part of the culture tank together with the increase of microalgae, A very small amount is scattered and absorbed only in the upper part of the tank, so that the light source is not properly supplied to the microalgae, and the efficiency of photosynthesis is lowered. In addition, there is a problem that as the algae are precipitated in the culture container, they become a warmth of the bacteria, and the culture liquid decays and the algal growth by other bacteria is suppressed.

In order to solve this problem, in the present invention, the culture liquid is agitated in a culture vessel through a vortex phenomenon generated by injecting a culture liquid mixed with a gas into a culture vessel, and a discharge tube formed at one side of the culture vessel is connected to a supply tube of another culture vessel, Is fed into the inside of another incubator to keep the micro-algae growth density in the incubator evenly, micro-algae are precipitated to prevent the culture liquid from being spoiled, and the light source and nutrients can be uniformly transferred to the microalgae .

Korean Patent Publication No. 10-2008-0111843 relates to a submerged membrane bioreactor (MBR), which comprises an immersion type membrane module having a hollow fiber type membrane in a treatment tank, A cylindrical tube disposed to surround the outer periphery of the membrane module, and a nozzle or a porous diffuser for supplying air into the cylindrical tube. Korean Patent Application No. 10-2001-0022926) discloses a high-density culture apparatus for microalgae, which comprises a transparent aqueous culture tank having a pH sensor and a dispersing unit and a culture tank filled with the culture medium, A plurality of fluorescent lamps, each of which is equipped with a plurality of fluorescent lamps for supplying light to the culture tank, is mixed with carbon dioxide and supplied to the culture water tank through the dispersion device. Korean Patent Laid-Open Publication No. 10-2010-0083948 relates to an alga culturing apparatus and a culture method using ultraviolet irradiation, and it is an object of the present invention to provide an alga culturing apparatus and a culture method using ultraviolet irradiation, which can emit an optimal ultraviolet radiation dose to suppress algae proliferation by other bacteria, And a method for culturing an alga using the same. Korean Patent Laid-Open Publication No. 10-2011-0096377 discloses an oil extraction method and a biodiesel conversion method from microalgae. When oil is extracted from microalgae to produce biodiesel, Discloses a method for increasing the conversion of biodiesel by removing chlorophyll having a phenomenon of inhibiting the biodiesel before the biodiesel conversion reaction. The technology relating to the cultivators has a configuration in which an incubator independent of one light source is provided, or a light source is mounted in the incubator. However, in the present invention, since the injection port having the spray angle of 0 ° to 90 ° and the discharge pipe formed at one side of the incubator are connected to the supply pipe of the other incubator, a plurality of incubators are arranged equidistantly around the light source. Purpose, and composition.

In the present invention, when a food organism (microalgae) is cultured in a large water tank, since the light source is usually installed on the upper part of the water tank, the light does not reach the bottom surface of the water tank together with the increase of food organisms, In order to solve the problem that the irradiated light does not reach the center of the water tank as the capacity of the water tank and the density of the microalgae are increased due to the absorption, The present invention provides a device for cultivating a photoreactive microalgae that uniformly distributes light from a light source to microalgae through a process of agitating a culture solution using a vortex phenomenon generated in a reactor by injecting a culture solution mixed with a microalgae.

The apparatus for cultivating a photoreactive microalgae according to the present invention is an incubator having a bottom and a height of a certain area and accommodating microalgae and a culture medium therein and having a gas outlet at an upper end thereof. The culture medium is connected to one side of the incubator, A nozzle for injecting a gas, which is connected to one side of the supply pipe and is controllable at a certain pressure, an injection port formed at one end of the supply pipe for injecting a culture liquid in which a gas is mixed into the inside of the incubator, and a culture liquid is discharged to the lower side of the incubator And a light source provided outside the incubator and irradiating light to the incubator.

Further, the outlet provided at the lower part of the incubator is connected to the supply pipe of the other incubator, and the culture liquid is flowed from the incubator to the incubator to equalize the density of the microalgae. A plurality of incubators are arranged equidistantly around the light source, The present invention provides a photoreaction microalgae culture apparatus in which light is uniformly delivered and productivity is increased. The injection port is adjustable in the range of 90 ° from the horizontal to the inside of the reactor, and the discharge pipe of the incubator is connected to the supply pipe of the other incubator, and a plurality of equipments are arranged equidistantly around the light source, Can be achieved.

The apparatus for cultivating photoreactive microalgae according to the present invention is characterized in that the culture solution is stirred in the incubator and the culture liquid flows between the incubator and the incubator to equalize the density of the microalgae in each incubator and to prevent the microalgae from being precipitated and decayed in the incubator, It is possible to prevent the algae from sticking to the wall of the incubator and to transmit the light source and nutrients evenly throughout the microalgae. In addition, since a plurality of incubators are arranged at equal distances around one light source, it is possible to save energy and increase the production efficiency of microalgae, thereby obtaining economical benefits, rather than operating only one incubator as a light source have.

1 is a perspective view showing a device for culturing a photoreactive microalgae according to the present invention.
FIG. 2 is a photograph showing a process of injecting carbon dioxide or oxygen air by inoculating a microalgae to be cultivated in a photoreactive microalgae culture apparatus.
3 is a photograph showing a gas supply pipe connected to one side of the supply pipe.
4 is a photograph showing a configuration in which a discharge tube is connected to a supply tube of another incubator and the culture solution is circulated to the inside of another incubator through a discharge tube.
FIG. 5 is a perspective view illustrating a connection between incubators of a photoreactive microalgae culture apparatus according to the present invention. FIG.
6 is a top plan view showing a plurality of incubators connected to the apparatus for culturing photoreactive microalgae according to the present invention.
7 is a photograph showing microalgae cultured evenly from the microalgae incubator of the present invention.

1 is a perspective view of a device for culturing photoreactive microalgae according to the present invention. The apparatus for cultivating a photoreactive microalgae of the present invention comprises an outer wall having a floor and a height of a predetermined area and containing a microalgae and a culture medium, and an upper cover at an upper part thereof. The incubator 10 is connected to one side of the incubator, A feed pipe (20) for feeding the mixed culture liquid; A gas injection nozzle (22) connected to one side of the supply pipe and controlled at a constant pressure; An injection port 21 formed at one end of the supply pipe and injecting a culture solution mixed with gas into the incubator 10; A discharge tube 30 through which the culture liquid is discharged to the lower center or one side of the incubator; And a pneumatic pressure control gas outlet (11) formed in the upper lid of the incubator.

In addition, the incubator 10 has a floor and a height of a predetermined area, and has a gas outlet 11 through which gas can be discharged and a spray device 40 for cleaning the incubator. The supporting frame 12 can be installed under the incubator so that the incubator 10 can be lifted from the ground to facilitate the formation of the discharge pipe 30 formed at the lower end of the incubator 10 and the light irradiated from the light source 50 can be supplied to the incubator 10) It plays a role to support from top to bottom so that it can be irradiated uniformly.

The incubator support frame 12 may be a three-legged or a four-legged leg, or a hexahedron frame having a hole at the center, or may be integrally formed with the incubator 10, or may be installed separately.

In order to cultivate microalgae using the photoreactive microalgae culturing apparatus provided in the present invention, the microalgae to be cultured and the microalgae to be cultured are first supplied to the incubator 10 cleaned thoroughly through the feed pipe 20. The culture liquid is supplied to the culture medium together with the microalgae for cultivation through the supply tube 20 formed at one side of the incubator 10. Photoreaction microalgae culture apparatus of the present invention flagella birds (Isocrysis sp . ), Diatoms ( Chaetoceros sp. ), Or green algae ( Tetraselmia sp . ), And the culture medium can be prepared by using seawater, nordic acid, or fresh water depending on the kind of microalgae to be cultured, and adding necessary nutrients to the culture. FIG. 2 is a photograph showing a process of injecting carbon dioxide or oxygen air by inoculating a microalgae to be cultivated in a photoreactive microalgae culture apparatus.

A gas supply nozzle 22 is connected to one side of the supply pipe 20 for supplying the culture liquid and is mixed with the gas while the culture liquid is supplied to the incubator 10. Fig. 3 shows a perspective view of the gas injection nozzle 22. Fig. One end of the nozzle 22 is sealed, and a high pressure gas is injected from one side and a through hole is formed so that the gas can be discharged perpendicularly to the gas injection direction. The gas injection nozzle 22 having the through hole is horizontally inserted into the center of the culture liquid supply pipe and supplies air or carbon dioxide as a gas to be injected at a high pressure to supply a high pressure gas upward. The high-pressure air can be connected to a compressed air or carbon dioxide tank to control the pressure injected using a pressure regulating valve. At this time, a cone presser may be connected to supply injected gas at a constant pressure. 3 is a photograph showing a gas supply pipe connected to one side of a supply pipe and a nozzle for gas injection.

The gas mixed and supplied to the culture medium is mixed with the culture solution supplied to the supply pipe 20 and injected into the incubator 10 through the injection port 21 formed in the incubator 10 so that the rate at which the gas- The pressure of the injected gas is adjusted. The injected gas mixed culture liquid forms a vortex in the incubator 10 so that the culture solution is stirred to prevent the culture solution from staying in one place in the incubator 10 and microscopic algae adhere to the inner wall of the incubator 10 to transmit light Can be prevented. And also serves to uniformly supply the nutrients and carbon dioxide of the culture medium to the microalgae. The microalgae in the incubator 10 can be uniformly irradiated from the light source 50 by stirring the culture solution.

The injection angle of the injection port formed in the incubator is adjustable at an angle of the injection port 21 between 0 ° parallel to the horizontal and 90 ° parallel to the vertical depending on the velocity of the vortex to be formed and the condition of the incubator 10. When the angle of the jetting port 21 is set to 0 DEG parallel to the horizontal direction, it is possible to prevent the culture liquid from staying in a part of the bottom surface of the incubator 10 to generate a vortex in the entire culture liquid in the incubator 10, The velocity of the vortex of the body decreases. In addition, when the angle of the injection port 21 is increased in the direction of 90 degrees in the horizontal direction, the strength and velocity of the vortex in the injection port 21 are easy to be transferred to the upper part of the culture liquid. There may be a problem of staying.

Therefore, in the present invention, it is effective to set the angle of the jetting port 21 to 0 ° to 90 °, preferably 0 ° to 60 °, in order to sufficiently stir the culture liquid and prevent the culture solution from staying.

The gas mixed with the culture medium and injected into the incubator 10 causes stirring of the culture medium and increases the pressure inside the incubator 10 to discharge the culture medium through the discharge pipe 30 formed at the bottom middle or one side of the incubator 10 . At this time, oxygen released from a part of the gas leaving the upper layer of the culture liquid and the microalgae is discharged through the gas outlet 11 formed at the upper end of the incubator 10, and the pressure inside the incubator 10 is adjusted.

The lower end surface of the incubator 10 having the discharge tube 30 formed therein is rounded down to prevent deposition and stagnation of microalgae and facilitates the discharge of the culture liquid to the discharge tube 30.

When culturing in a single incubator, the discharge tube is connected to the supply tube, and the culture liquid discharged through the discharge tube is injected into the incubator again and circulated. At this time, a valve may be formed in the discharge pipe to control the discharge and recovery of the culture liquid. 4 is a photograph showing a configuration in which a discharge tube is connected to a supply tube of another incubator and the culture solution is circulated to the inside of another incubator through a discharge tube.

The cleaning spraying device 40 formed on one side of the incubator 10 is used to clean the inside of the incubator 10 after recovering microalgae cultured in the incubator 10. After the microalgae are recovered and sprayed with dilute hydrochloric acid, alcohol, or detergent solution through the cleaning spraying device 40 in sequence, the microalgae attached to the inner wall of the incubator 10 can be removed. The spray device is formed by forming a cleaning liquid injection hole made of fine balls in the pipe outer circumferential direction, and a high pressure pump can be connected so that the cleaning liquid can be injected at a high pressure.

FIG. 5 is a perspective view illustrating a connection between incubators of a photoreactive microalgae culture apparatus according to the present invention. FIG. The culture liquid discharged through the discharge pipe 30 formed at the lower end of the incubator 10 may be connected to the supply pipe 20 'of another incubator to connect a plurality of incubators. At this time, a plurality of incubators are disposed at equal distances from the light sources 50 around the light sources 50 provided outside the incubator, and the light is irradiated in the same manner.

A vortex is formed in the incubator 10 by the gas injected from the injection port 21 of the incubator 10 and the culture liquid to stir the culture liquid in the incubator 10 as shown in FIG. At this time, the culture liquid is discharged through the discharge pipe 30 at the lower end of the incubator 10 by the pressure in the incubator 10, and is supplied into the incubator 10 'through the supply pipe 20' of the incubator 10 '. A gas injecting nozzle 22 'is connected to one side of the supply pipe 20' of the incubator 10 'so that the gas and the culture liquid are injected into the incubator 10' at a constant speed to form a vortex in the incubator 10 ' As the microalgae are stirred with the culture solution, the microalgae are proliferated while being constantly exposed to light irradiated from a light source provided outside the incubator.

FIG. 6 is a top plan view showing a plurality of incubators of a photoreactive microalgae culture apparatus according to the present invention. 2, the plurality of incubators may be arranged at equal distances around the light source 50. In this case, the number of the incubators connected may depend on the efficiency of utilization of the light source 50 and the economical efficiency such as the yield of microalgae Can be adjusted accordingly. In an embodiment of the present invention, three to six incubators may be connected in consideration of the light irradiation amount of the microalgae and the efficient utilization of the culture space.

The outlet of the last connected incubator is connected to the feed line (20) of the first incubator to form an annular closed incubator circuit. The supply pipe connected to the discharge pipe of the incubator needs to be formed with a diameter smaller than the diameter of the discharge pipe to increase the pressure of the supply pipe. In other words, according to Bernoulli's theorem, it is expected that the injection pressure will be increased by moving the fluid from the wide tube to the small tube.

When a plurality of incubators are connected and the gas injecting nozzle is connected at only one point, the pressure of the gas injected from the gas injecting nozzle of the incubator as a starting point decreases as the distance from the starting point increases. Therefore, the number of connectable incubators is possible until the pressure reaching the last connected incubator reaches zero.

However, when the gas is injected through the nozzle for injecting gas only in the incubator as a starting point, the agitation of the culture liquid through the injection port may not be smoothly performed in each incubator, and only the culture liquid may be transferred from the incubator to the incubator. Therefore, when a plurality of incubators are connected to each other, gas is injected through each of the incubator gas injection nozzles, which has a smooth effect of culturing microalgae.

The microalgae are sequentially moved through the incubator 10 and are exposed to a certain light intensity and nutrients. The incubator 10 is made of tempered glass, polycarbonate, transparent acrylic, or transparent PC having excellent transparency and mechanical strength, And the operator can observe the culture condition of the cultured microalgae and the state of the culture liquid such as turbidity and viscosity.

The light source 50 used in the present invention is installed outside the incubator 10 and can be selected depending on the kind and economical efficiency of the microalgae to be cultivated. It is possible to selectively use one or more of fluorescent lights, LEDs, incandescent lamps and the like. In particular, since LEDs can selectively irradiate a narrow range of wavelengths, it is possible to irradiate only the optimal culture wavelength according to the objective microalgae, The efficiency of photosynthesis of algae can be increased to shorten the incubation period and increase the yield. 7 is a photograph showing microalgae cultured evenly from the microalgae incubator of the present invention.

Photoreaction microalgae culture apparatus of the present invention flagella birds (Isocrysis sp . ), Diatoms ( Chaetoceros sp . ), Or green algae ( Tetraselmia sp . ), And the wavelength of the light source can be controlled in consideration of the ecology of the microalgae. In one embodiment, green algae ( Tetraselmia sp . ), The wavelength of blue violet light (430 to 460 nm) and red light (630 to 680 nm) can be selectively or mixedly irradiated, or mixed white light can be irradiated.

The present invention relates to a method for producing a microorganism, which comprises injecting a culture solution in which a gas mixture is mixed into a culture vessel, stirring the culture solution in the culture vessel, connecting a discharge port formed at one side of the lower portion of the culture vessel and a supply tube of another culture vessel, It is possible to prevent the microbial growth from being inhibited by other bacteria due to the decay of the culture solution and to transmit the light evenly to the microalgae, thereby increasing the culture efficiency. In addition, a plurality of incubators are arranged in a circle around one light source (50), and the productivity increase effect can be obtained, so that there is a possibility of expanding the algae culture base and industrial use in the fisheries field.

10: incubator 11: gas outlet
12: support frame 20: supply pipe
21: nozzle 22: gas injection nozzle
30: Exhaust pipe 40: Spray device for cleaning
50: Light source

Claims (5)

1. An incubator comprising an outer wall having a floor and a height of a predetermined area and accommodating microalgae and a culture medium,
A supply pipe connected to one side of the incubator and supplying a culture medium in which a gas is mixed, and a gas injection nozzle connected to one side of the supply pipe,
An injection port formed at one end of the supply pipe for injecting a culture liquid in which a gas is mixed into the incubator and a discharge pipe for discharging the culture liquid to the lower center or one side of the incubator;
And a pneumatic pressure regulating gas outlet formed in the upper lid of the incubator.
[2] The apparatus according to claim 1, wherein the gas injection nozzle has a cylindrical body having one end closed and a high pressure gas to the other end, and a cylindrical hole is formed in the cylindrical body,
Wherein the injection angle of the injection port is adjustable from 0 ° to 90 ° with respect to the horizontal.
[3] The culture system according to claim 1, wherein the culture tube is connected to a supply pipe of another incubator adjacent to the incubator, and a plurality of incubators are arranged at equal distances around the light source to form an incubator loop-
[4] The method according to claim 3, wherein the connection from one of the incubator discharge pipes to the supply pipe of the other incubator is formed such that the diameter of the guide hole gradually decreases, and a spray device for washing is formed on the upper part of the incubator .
a) preparing a microalgae culture apparatus according to any one of claims 1 to 4;
b) feeding the culture medium to the microalgae culture apparatus and inoculating microalgae;
c) culturing a microalgae by injecting a gas through a gas injection nozzle of a culture apparatus to form a vortex in the incubator while supplying gas;
and d) harvesting the microalgae after culturing the microalgae for a predetermined time. The microalgae culture method using the photoreactive microalgae culture apparatus

Images