KR102524411B1 - A Green alga culture medium - Google Patents

Abstract

The present invention relates to an algae incubator, which is configured to allow green algae, which inhabit water moving along a tube member, to photosynthesize through light emitted from an LED lamp, and to supply oxygen produced thereby to the room, thereby circulating water. The tube member connected from the inducing submersible motor surrounds the LED lamp and is coupled to the upper outlet hole of the inner cap, so that water falls from the top of the inner cap in a waterfall form and flows into the water tank, so that water circulation and oxygen, It is characterized by increasing carbon dioxide contact and efficiently purifying indoor air through a simple structure.

Description

Algae incubator {A Green alga culture medium}

The present invention relates to an algae incubator, and more particularly, to green algae living in water moving along a tube member that photosynthesizes through light emitted from an LED lamp, and is configured to supply oxygen produced thereby to the room. , The tube member connected from the underwater motor that induces the circulation of water surrounds the LED lamp and is coupled to the upper outlet hole of the inner cap, so that water falls from the top of the inner cap in a waterfall form and flows into the water tank. It is about an algae incubator that can efficiently purify indoor air through a simple structure by increasing circulation and contact with oxygen and carbon dioxide.

Carbon dioxide is a kind of greenhouse gas that causes global warming, and the amount of carbon dioxide in the atmosphere is increasing every year as the use of fossil fuels increases with the acceleration of industrialization in modern society. Recently, in order to reduce greenhouse gases, research on reducing and storing approximately carbon dioxide has been actively conducted in countries around the world. Among them, carbon dioxide fixation technology using vegetation such as plants or microalgae uses solar energy as a light source unlike other physical and chemical recovery methods, so investment and operation costs are low, and secondary treatment costs due to generation of environmentally harmful substances are low. It has the advantage that it does not require much space and can greatly contribute to the creation of the landscape.

Most of the conventional carbon dioxide fixing devices using microalgae are in the experimental stage for commercialization, so harvesting methods of microalgae are not considered, or the entire amount of microalgae cultured in the collection tank is harvested at once and then the culture water is used. A batch harvesting method was applied to replenish the microalgae by refilling. However, when the harvesting of the microalgae is performed in the batch harvesting method, not only does it take a lot of time to re-proliferate the microalgae, but there is a problem in that the carbon dioxide fixation efficiency using the microalgae is reduced.

Recently, as interest in green growth such as carbon dioxide reduction has increased, such trends are also occurring at home, and plants are placed in rooms to purify the air and pursue aesthetic elements. In general, in the case of plants, by absorbing carbon dioxide and releasing oxygen through photosynthesis, a more comfortable environment is provided by increasing the amount of oxygen and reducing the amount of carbon dioxide. Since it proliferates and has excellent photosynthetic efficiency compared to other plants, it is in the spotlight in the eco-friendly energy industry such as biomass and bio-oil, and various attempts are being made to effectively purify the air using these green algae.

The green algae incubator as described above is disclosed in Patent Publication No. 10-2016-0098864 (hereinafter referred to as 'Patent Document 1').

Referring to Patent Document 1, in the conventional green algae incubator, the case of the picture frame is configured as a fish tank (1-2) containing green algae, and a passage (1-3) is supplied to one side of the fish tank (1-2) to supply carbon dioxide. ) to supply carbon dioxide, and to effectively remove carbon dioxide inside the room, a filter that can let carbon dioxide into the air exchange place (1-4) is installed so that carbon dioxide can enter the fish tank from the room.

Patent Document 1 is configured to send carbon dioxide into the fish tank (1-2) for photosynthesis of green algae, while sending oxygen generated by photosynthesis to the air from the fish tank to create more comfortable indoor air, but only conceptual content. As the detailed structure for culturing green algae is not disclosed, there is a problem in that it is impossible to know through which structure an efficient air purification function is performed.

Patent Document 1: Korean Patent Publication No. 10-2016-0098864

The present invention has been made to solve the above problems, and an object of the present invention is that green algae living in water moving along a tube member perform photosynthesis through light emitted from an LED lamp, and oxygen produced thereby is stored indoors. It is configured to supply, but the tube member connected from the underwater motor that induces the circulation of water surrounds the LED lamp and is coupled to the upper outlet hole of the inner cap, so that water falls from the top of the inner cap in a waterfall form and flows into the water tank. Therefore, it is an object of the present invention to provide an algae incubator capable of efficiently purifying indoor air through a simple structure by increasing water circulation and oxygen and carbon dioxide contact.

In order to solve the above problems, the green algae incubator according to a preferred embodiment of the present invention includes a water tank unit in which water is stored so that green algae can inhabit; an underwater motor for inducing circulation of the water stored in the water tank; A body portion that surrounds the water tank and has a plurality of lamp coupling holes formed thereon so that a plurality of LED lamps can be installed thereon; A plurality of LED lamps respectively coupled to the plurality of lamp coupling holes to emit light; a tube member positioned to surround the entire outer circumferential surface of the LED lamp in the longitudinal direction and connected to the underwater motor to form a passage through which water in which green algae live circulate; An inner cap that surrounds the LED lamp and the tube member and is coupled to the upper part of the body, and has an outflow hole formed at the upper end of the tube member so that the water moving through the tube member can flow out; And an outer cap surrounding the inner cap and coupled to an upper portion of the body portion, and having an oxygen discharge hole formed at the upper end thereof;

Green algae living in the water moving along the tube member perform photosynthesis through light emitted from the LED lamp, and thereby, oxygen produced is configured to move to the outside through the oxygen discharge hole. .

In addition, it is possible for the water flowing out through the outflow hole at the upper end of the body to flow along the upper surface of the inner cap and flow into the water tank in the process of falling in a waterfall form through the space between the inner cap and the outer cap. It is characterized in that a plurality of inlet holes are formed so as to.

In addition, a partition plate located inside the body portion to partition a space in which the tube member moves is further included, but the partition plate is formed on the inner circumferential surface of the coupling pipe protruding upward from the center of the bottom surface of the water tank. It is characterized in that it consists of a first sealing tube inserted in close contact, and a second sealing tube coupled to an extension portion extending downward while surrounding a plurality of lamp coupling holes formed in the body portion.

In addition, it is characterized in that it further comprises a pedestal coupled to the lower portion of the body in a state in which the space is separated from the water tank to form a space in which a battery for supplying power is stored.

In addition, the photosynthesis time zone is set in consideration of the general respiratory period in which the green algae take a break according to the natural cycle, consume oxygen and emit carbon dioxide, but the photosynthesis time zone of the green algae is at least 12 hours so that more oxygen is produced than carbon dioxide. It is characterized in that it is set to exceed.

As described above, according to the present invention, green algae living in water moving along a tube member perform photosynthesis through light emitted from an LED lamp, and oxygen produced thereby is supplied to the room, but the circulation of water is controlled. The tube member connected from the inducing submersible motor surrounds the LED lamp and is coupled to the upper outlet hole of the inner cap, so that water falls from the top of the inner cap in a waterfall form and flows into the water tank, so that water circulation and oxygen, It has the advantage of efficiently purifying indoor air through a simple structure by increasing carbon dioxide contact.

1 is an exploded perspective view showing the configuration of a green algae incubator according to a preferred embodiment of the present invention.
Figure 2 is a perspective view showing the configuration of the green algae incubator according to a preferred embodiment of the present invention.
Figure 3 is a combined cross-sectional view showing the configuration of the green algae incubator according to a preferred embodiment of the present invention.
4 is an operating state diagram of the green algae incubator according to a preferred embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings. Like reference numerals in each figure indicate like elements.

1 is an exploded perspective view showing the configuration of an green algae incubator according to a preferred embodiment of the present invention, FIG. 2 is a combined perspective view showing the configuration of an green algae incubator according to a preferred embodiment of the present invention, and FIG. 3 is a preferred embodiment of the present invention It is a cross-sectional view showing the configuration of the green algae incubator according to the example.

1 to 3, the green algae incubator according to a preferred embodiment of the present invention includes a water tank part 100, an underwater motor 200, a body part 300, an LED lamp 400, a tube member 500, It includes an inner cap 600 and an outer cap 700.

The water tank part 100 stores water so that the green algae 1 can inhabit it, and the water tank part 100 protrudes upward so that the first sealing pipe 810 of the leak-preventing member 800 is inserted into the central part of the bottom surface thereof. A coupling pipe 110 is provided.

The underwater motor 200 is installed on the bottom surface of the water tank part 100 to induce circulation of the water stored in the water tank part 100, and on one side is an inlet 210 through which the water stored in the water tank part 100 flows. ) Is provided, and the other side is provided with an outlet 220 for discharging water introduced through the inlet 210.

The underwater motor 200 is preferably installed with its lower end exposed to the bottom surface of the water tank 100 so that the cable C for power supply can be positioned out of the water.

The body part 300 surrounds the water tank part 100 and is located, and has a plurality of lamp coupling holes so that a plurality of LED lamps 400 emitting light for photosynthetic action of green algae can be installed at the top thereof. (310) are formed in a state spaced apart at regular intervals.

In the present invention, a plurality of inlet holes 320 are provided at the upper end of the body portion 300 to allow water flowing out through the outlet hole 610 of the inner cap 600 to flow into the water tank portion 100. Characterized in that it is formed, the inlet hole 320 surrounds the coupling groove 350 on the outside of the coupling groove 350 to which the lower end of the inner cap 600 is coupled and is formed in a plurality spaced apart at regular intervals, A process in which the water flowing out through the outflow hole 610 of the inner cap 600 moves along the upper surface of the inner cap 600 and falls through the space between the inner cap 600 and the outer cap 700 in a waterfall form. By forming a space moving from to the water tank unit 100, natural circulation of water is possible.

In addition, the outer circumferential surface of the body portion 300 is provided with a control panel 330 equipped with a control button 331 including a power button and a display unit 332 for displaying each screen according to the manipulation of the control button 331. it is desirable to be

Meanwhile, on the inner upper side of the body part 300, the extension part 340 surrounding the plurality of lamp coupling holes 310 is downward so that the second sealing tube 820 of the leak prevention member 800 is coupled thereto. extension is formed.

In addition, at the lower part of the body part 300, a battery (B) coupled with the water tank part 100 and space separated to supply power to the device, and a power cable (C) connected to the underwater motor 200 And a pedestal 900 forming a space in which a control board or the like is stored is coupled.

On the other hand, it is characterized in that a partition plate 800 is provided inside the body part 300 to partition a space in which the tube member 500 moves, and the partition plate 800 is the bottom of the water tank part 100. A first sealing tube 810 inserted in close contact with the inner circumferential surface of the coupling tube 110 protruding upward from the center of the surface and a plurality of lamp coupling holes 310 formed in the body portion 300 It is composed of a second sealing tube 820 coupled in a state of close contact with the inner circumferential surface of the extension part 340 extending downward and surrounding it, through the first sealing tube 810 and the second sealing tube 820. By blocking the movement of water stored in the water tank unit 100 to the inner cap 600 or the pedestal 900, the power cable connected to the power cable of the LED lamp 400, the battery B, and the underwater motor 200 (C) and the control board can be prevented from coming into contact with water.

The LED lamps 400 emit light by being coupled to the plurality of lamp coupling holes 310, and photosynthetic action of the green algae 1 located inside the tube member 500 surrounding the LED lamps 400. It is preferably made of a long rod shape so that it is possible to widen the surface area to be formed.

The LED lamp 400 is preferably configured to have a light wavelength capable of efficient photosynthetic action of the green algae 1.

The tube member 500 is connected to the submersible motor 200 to form a passage through which water in which the green algae 1 live resides, and one side thereof is coupled to the water outlet 220 of the submersible motor 200, The other side is configured to be coupled to the outflow hole 610 of the inner cap 600. In the present invention, the tube member 500 surrounds the entire outer circumferential longitudinal direction of the LED lamp 400 made of a long rod shape and is positioned It is characterized by being configured to

The tube member 500 is made of a transparent material so that the green algae 1 inhabiting the water moving through the inside of the tube member 500 can perform photosynthesis through the light emitted from the LED lamp 400. However, as the LED lamp 400 is configured to wrap around the entire lengthwise direction of the outer circumferential surface of the LED lamp 400, the surface area where the photosynthetic action takes place is widened, enabling the active photosynthetic action of the green algae 1.

The inner cap 600 surrounds the LED lamp 400 and the tube member 500 and is coupled to the coupling groove 350 of the body portion 300, and the water moving through the tube member 500 An outflow hole 610 to which the end of the tube member 500 is coupled is formed at the top so that the outflow is possible.

The outer cap 700 surrounds the inner cap 600 and is coupled to the upper portion of the body portion 300, and the upper end of the cap 700 enables oxygen generated through the photosynthetic action of the green algae 1 to be discharged to the outside. An oxygen discharge hole 710 is formed in the outer cap 700 to prevent water flowing out through the outlet hole 610 from flowing out to the outside through the outer cap 700. It is preferable to be formed in a state spaced apart at regular intervals along the upper circumference.

The oxygen discharge hole 710 functions as a passage for supplying carbon dioxide necessary for photosynthesis of green algae 1 together with the function of an oxygen discharge passage. In order to smoothly supply carbon dioxide to the water tank unit 100 , It is also possible that a separate means such as a suction pump for inhaling carbon dioxide is provided.

Hereinafter, with reference to FIG. 4, the operation process of the green algae incubator according to a preferred embodiment of the present invention will be described. 4 is an operating state diagram of the green algae incubator according to a preferred embodiment of the present invention.

Referring to FIG. 4 , when the submersible motor 200 is driven, water stored in the water tank unit 100 flows into the inlet 210 of the submersible motor 200 and flows out through the outlet 220. At this time, the outlet 220 ) The water flowing out is moved along the inside of the tube member 500 coupled to the outlet 220 and flows out to the upper surface of the inner cap 600 through the outlet hole 610 of the inner cap 600. .

As described above, when water flows out through the outflow hole 610 of the inner cap 600, the outflow water moves along the upper surface of the inner cap 600 to form a gap between the inner cap 600 and the outer cap 700. It falls through the space in the form of a waterfall. In this process, water moves through a plurality of inlet holes 320 formed at the upper end of the body portion 300 and flows into the water tank unit 100, and thereby, the water tank unit ( The natural circulation of the water stored in 100) is achieved.

As described above, in the process of circulating water along the inside of the tube member 500, the green algae 1 inhabiting the water moving through the inside of the tube member 500 through the light emitted from the LED lamp 400 Photosynthesis proceeds, and as a result, generated oxygen is discharged to the outside through the oxygen discharge hole 710 of the outer cap 700 to purify indoor air.

On the other hand, the present invention is configured to set a photosynthesis time zone in consideration of a general respiratory period in which green algae (1) take a break according to a natural cycle, consume oxygen, and emit carbon dioxide. It is preferable to set at least more than 12 hours so that more than carbon dioxide is produced.

As described above, in the present invention, the green algae (1) inhabiting the water moving inside the tube member 500 perform photosynthesis through the light emitted from the LED lamp 400, and the oxygen produced thereby is stored indoors. It is configured to supply, but the tube member 500 connected from the underwater motor 200 that induces the circulation of water surrounds the LED lamp 400 and is coupled to the upper outlet hole 610 of the inner cap 600, Since water falls from the top of the cap 600 in a waterfall form and flows into the water tank unit 100, it is possible to increase circulation of water and contact with oxygen and carbon dioxide, thereby efficiently purifying indoor air through a simple structure. .

Optimal embodiments have been disclosed in the drawings and specifications. Although specific terms have been used herein, they are only used for the purpose of describing the present invention and are not used to limit the scope of the present invention described in the claims or defining the meaning. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical scope of protection of the present invention should be determined by the technical spirit of the appended claims.

100: water tank 110: coupling pipe
200: underwater motor 210: inlet
220: outlet 300: body
310: lamp coupling hole 320: inlet hole
330: operation panel 331: operation button
332: display unit 340: extension unit
350: coupling groove 400: LED lamp
500: tube member 600: inner cap
610: outflow hole 700: outer cap
710: oxygen discharge hole 800: leak prevention member
810: first sealing pipe 820: second sealing pipe
900: pedestal

Claims (5)

a water tank in which water is stored so that green algae can inhabit;
an underwater motor for inducing circulation of the water stored in the water tank;
A body portion that surrounds the water tank and has a plurality of lamp coupling holes formed thereon so that a plurality of LED lamps can be installed thereon;
A plurality of LED lamps respectively coupled to the plurality of lamp coupling holes to emit light;
a tube member positioned to surround the entire outer circumferential surface of the LED lamp in the longitudinal direction and connected to the underwater motor to form a passage through which water in which green algae live circulate;
An inner cap that surrounds the LED lamp and the tube member and is coupled to the upper part of the body, and has an outflow hole formed at the upper end of the tube member so that the water moving through the tube member can flow out; and
An outer cap surrounding the inner cap and coupled to an upper portion of the body portion, and having an oxygen discharge hole formed thereon;
Green algae inhabiting the water moving along the tube member perform photosynthesis through light emitted from the LED lamp, and thereby, produced oxygen moves to the outside through the oxygen discharge hole,
At the upper end of the body, a plurality of water flowing out through the outflow hole moves along the upper surface of the inner cap and flows into the water tank in the process of falling in a waterfall form through the space between the inner cap and the outer cap. An incubator for green algae, characterized in that the inlet hole is formed.
delete The method of claim 1,
Further comprising a partition plate located inside the body and partitioning a space in which the tube member moves,
The partition plate surrounds the first sealing tube inserted in close contact with the inner circumferential surface of the coupling tube protruding upward from the center of the bottom surface of the water tank, and a plurality of lamp coupling holes formed in the body portion, and surrounds the lower part. An green algae incubator characterized in that it is composed of a second sealing tube coupled to an extension formed to extend into.
The method of claim 3,
The green algae incubator further comprises a pedestal coupled to the lower part of the body in a state in which the space is separated from the water tank to form a space in which a battery for supplying power is stored.
The method of claim 1,
The photosynthesis time zone is set in consideration of the general respiratory period in which the green algae take a break according to the natural cycle, consume oxygen and emit carbon dioxide, but the photosynthesis time zone of the green algae exceeds at least 12 hours so that more oxygen is produced than carbon dioxide An algae incubator, characterized in that set.

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