KR20230072976A - Microalgae bioenergy production window that can realize patterns using a variable culture chamber - Google Patents

Abstract

The present invention relates to a microalgae bioenergy production window that can realize patterns using a variable culture chamber, and more specifically, to a microalgae bioenergy production window that can realize patterns using a variable culture chamber, in which, by cultivating microalgae in the culture chamber inside the chamber-type window, air with an increased oxygen concentration can be discharged, aesthetics can be increased by moving the culture chamber laterally and changing an arrangement pattern of microalgae, and position where sunlight is blocked can be changed.

Description

Microalgae bioenergy production window that can realize patterns using a variable culture chamber}

The present invention relates to a microalgae bioenergy production window capable of implementing a pattern using a variable culture chamber, and more specifically, by culturing microalgae in a cylindrical culture chamber inside a chamber-type window and moving the culture chamber laterally. , By changing the arrangement pattern of the culture chamber, it is possible to increase the aesthetic sense, and to a microalgae bioenergy production window that can be patterned using a variable culture chamber that can change the position where sunlight is blocked.

In general, new and renewable energy is energy for producing and utilizing energy such as electricity and biomass based on natural energy such as sunlight, solar heat, geothermal heat, and wind power. There is an increasing trend in the market to install and apply solar power, solar panels, geothermal power generation systems, wind turbines, etc. to buildings.

In addition, people are more interested in eco-friendly elements to improve the quality of life, and humidifiers, air purifiers, moods, etc. are being grafted to eco-friendly elements.

Among them, windows using biomass can be cited as a product that can be used as a home interior instead of an air purifier.

Here, biomass was an energy source with various limitations such as social ethical standards and efficiency of raw material extraction, but with the development of bioenergy extraction technology based on the lipid decomposition of microalgae, which is a protist and belongs to microorganisms, it has been in the spotlight along with solar energy. It is classified as a type of next-generation new and renewable energy.

In addition, windows using microalgae, a third-generation biomass, function as microalgae culturing spaces in the interior space of windows and doors in eco-friendly buildings that were built using basic architectural elements such as lighting, ventilation, and insulation, which were conventionally used in the construction market. By doing so, it is a window that grants energy production function to the building and utilizes the carbon dioxide emitted from the building for cultivation.

However, the conventional windows and doors using microalgae have problems in that the culture chamber in which the microalgae is cultured is fixed, so that the microalgae cannot be efficiently cultivated, and the aesthetics of the interior are poor.

The present invention has been made to solve these problems, and an object of the present invention is to change the arrangement pattern of microalgae and change the light-shielding position by moving the culture chamber provided inside the window in the lateral direction. It is to provide a microalgal bioenergy production window capable of implementing a pattern using a variable culture chamber.

In addition, another object of the present invention is provided with a culture chamber inside the window, microalgae can be cultured to reduce the concentration of external carbon dioxide and increase the concentration of oxygen by using a variable culture chamber capable of implementing a pattern. It is intended to provide windows for algae bioenergy production.

The objects of the present invention are not limited to the objects mentioned above, and other objects not mentioned will be clearly understood by those skilled in the art from the description below.

In order to achieve the above object, the present invention is provided with a transparent material, a chamber type window provided in an open top and bottom form so that a predetermined space is formed inside, coupled to the upper part of the chamber type window, and a first motor is provided. window and door including an upper frame, a lower frame coupled to the lower portion of the chamber-type window and having a second motor, one frame coupled to one side of the chamber-type window, and the other frame coupled to the other side of the chamber-type window. , A first water supply passage in the shape of a pipe with both sides open, one side communicating with the central portion of the first water supply passage, and a second water supply passage formed integrally extending toward the lower direction orthogonal to the first water supply passage and the first water supply passage It includes a pair of accordion water supply pipes provided on one side and the other side of the water supply passage, and a plurality of water supply passages provided inside the upper frame so as to communicate with each other along the lateral direction, a pipe-shaped first drainage with both sides open One side of the passage is in communication with the central portion of the first drainage passage, and a second drainage passage formed integrally extending toward an upper direction orthogonal to the first drainage passage and a pair provided on one side and the other side of the first drainage passage, respectively A plurality of drain passages including an accordion drain pipe and communicating with each other along the lateral direction inside the lower frame are provided in the inner space of the chamber-type window in a tubular shape, and the upper end is the second water supply passage Is connected to the other side of, the lower end is connected to the other side of the second drainage passage, the inner side is connected to the culture chamber in which microalgae are cultured and the first water supply passage, by moving the water supply passage in a lateral direction, the culture Provided is a microalgae bioenergy production window capable of implementing a pattern using a variable culture chamber including an upper driving unit that allows the upper end of the chamber to move in a lateral direction.

In a preferred embodiment, it further includes a lower drive unit connected to the first drainage passage and moving the drainage passage part in a lateral direction so that the lower end of the culture chamber is moved in a lateral direction.

In a preferred embodiment, an inner flow path is formed inside in a shape that surrounds the first drain flow path from the outside, communicates with the inner flow path at a position in contact with the first drain flow path, and supplies air that is inserted into and installed in the first drain flow path. An air supply bracket equipped with pins, a pipe shape with both sides open, provided in the same direction as the first drainage passage, and an air supply passage communicating with the internal passage of the air supply bracket and provided on one side and the other side of the air supply passage, respectively. and an air supply passage part including a pair of accordion air supply pipes, wherein external air is supplied to the drainage passage part through the air supply passage part and supplied to the culture chamber.

In a preferred embodiment, an internal flow path is formed inside in a shape surrounding the first water supply path from the outside, communicates with the internal flow path at a position in contact with the first water supply path, and an exhaust pipe inserted into and installed in the first water supply path. Both sides of an exhaust bracket equipped with fins are open in a pipe shape, provided in the same direction as the first water supply passage, and an exhaust passage communicating with the internal passage of the exhaust bracket, and a pair provided on one side and the other side of the exhaust passage, respectively. and an exhaust passage portion including an accordion exhaust pipe, wherein the exhaust passage portion discharges air having an increased oxygen concentration in the culture chamber through the water supply passage portion to the outside through the exhaust passage portion.

In a preferred embodiment, the upper drive unit rotates the upper pinion gear by engaging with an upper rack gear provided outside the exhaust bracket, an upper pinion gear located on each upper rack gear, and each upper pinion gear. An upper drive control gear including an upper spur gear and an upper bearing, an upper chain connected to the upper spur gear, and an upper transmission for varying the height of the upper chain, wherein the upper spur gear is formed at different heights do.

In a preferred embodiment, the lower drive unit engages with the lower rack gears provided outside the air supply bracket, the lower pinion gears located on each lower rack gear, and each lower pinion gear to rotate the lower pinion gears. A lower driving control gear including a lower spur gear and a lower bearing, a lower chain connected to the lower spur gear, and a lower transmission for varying the height of the lower chain, wherein the lower spur gear is formed at different heights. do.

In a preferred embodiment, when the upper and lower ends of the culture chamber slide in opposite directions to each other, the culture chamber becomes obliquely elongated, and the upper and lower ends of the culture chamber slide in the same lateral direction. When moved, the culture chamber becomes densely packed in the lateral direction.

In a preferred embodiment, the mixed solution of nutrients is supplied to the culture chamber through the water supply passage, and the microalgae inside the culture chamber are cultured, and the mixed solution of microalgae generated after culturing is discharged to the outside through the drainage passage. .

In a preferred embodiment, the upper frame is connected to an upper window frame connected to an upper portion of the chamber-type window and an upper end of the upper window frame frame, and the water supply passage unit is provided therein to protect the water supply passage unit. A sub frame, an upper driving unit frame connected to an upper end of the upper flow path frame and protecting the upper driving unit, inserted in a downward direction from the top of the upper driving unit frame to protect the upper driving unit frame and the upper driving unit frame, It further includes an upper outer frame having a first motor and an upper motor frame connected to an upper end of the upper outer frame and protecting the first motor.

In a preferred embodiment, the lower frame comprises a lower window frame connected to the lower portion of the chamber-type window, a lower flow path frame connected to a lower end of the lower window frame and protecting the drain passage, and the lower flow passage frame. A lower drive unit frame connected to a lower end and protecting the lower drive unit, a lower outer frame inserted from the bottom of the lower drive unit upward to protect the lower flow channel frame and the lower drive unit frame, and having a second motor at the lower end. and a lower motor frame connected to an upper end of the lower outer frame and protecting the second motor.

In a preferred embodiment, the upper motor frame is provided with an insulating material in a space other than the space in which the first motor is provided, and the lower motor frame is provided with an insulator in a space other than the space in which the second motor is provided.

In a preferred embodiment, a rotational coupling groove is formed at the lower end of the second water supply passage and the upper end of the second drainage passage, and a rotational coupling recess is formed at the upper end and lower end of the culture chamber to be coupled with the rotational coupling groove. do.

The present invention has the following excellent effects.

According to the microalgae bioenergy production windows capable of implementing a pattern using the variable culture chamber of the present invention, the culture chamber provided inside the window is moved laterally to change the arrangement pattern of the microalgae, thereby improving the aesthetics of the window. It can increase the amount of sunlight through the movement of the culture chamber, and has the advantage of efficiently culturing microalgae by changing the position of the shading.

In addition, according to the microalgae bioenergy production window, which can be patterned using the variable culture chamber of the present invention, outside air is supplied to the culture chamber provided inside the window, and carbon dioxide in the air is released by the photosynthetic action of the microalgae. The concentration can be reduced, and there is an effect of supplying air with increased oxygen concentration to the outside.

In addition, according to the microalgae bioenergy production window capable of implementing a pattern using the variable culture chamber of the present invention, a culture chamber is provided inside the window to increase the insulation of the window and door, and noise and vibration generated in the culture chamber has the effect of reducing

1 is for explaining the combined structure of a window, a water supply passage, a drainage passage, a culture chamber, and an upper driving part of a microalgae bioenergy production window that can be patterned using a variable culture chamber according to an embodiment of the present invention. it is a drawing
2 is a view for explaining a window of a microalgae bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.
3 is a view for explaining an upper frame of a microalgal bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.
4 is a view for explaining an upper passage frame and an upper drive frame of a microalgal bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.
5 is a view for explaining a lower frame of a microalgal bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.
6 is a view for explaining a water supply passage of a microalgae bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.
7 is a view for explaining a drain passage portion of a microalgae bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.
8 is a view for explaining a culture chamber of a microalgae bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.
9 is a view for explaining an upper driving part of a microalgal bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.
10 is a view for explaining a lower drive unit of a microalgal bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.
11 is a view for explaining an air supply passage of a microalgal bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.
12 is a view for explaining the exhaust passage of the microalgae bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.
13 is a view for explaining the flow of a mixed solution and the flow of air in a microalgae bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.
14 is a view for explaining the driving mechanism of the upper driving unit of the microalgal bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.
15 is a view for explaining the driving mechanism of the lower driving unit of the microalgal bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.
16 is a view for explaining an individual driving mechanism of an upper driving unit of a microalgal bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.
17 is a view for explaining the shape of the culture chamber according to the driving of the upper driving unit and the lower driving unit of the microalgae bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.

The terms used in the present invention have been selected from general terms that are currently widely used as much as possible, but in certain cases, there are terms arbitrarily selected by the applicant. Therefore, its meaning should be understood.

Hereinafter, the technical configuration of the present invention will be described in detail with reference to preferred embodiments shown in the accompanying drawings.

However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Like reference numbers indicate like elements throughout the specification.

1 shows a combined structure of a window, a water supply passage, a drainage passage, a culture chamber, an upper driving unit, and a lower driving unit of a microalgae bioenergy production window that can be patterned using a variable culture chamber according to an embodiment of the present invention. It is a drawing for explanation.

Referring to FIG. 1, the microalgae bioenergy production window, which can be patterned using a variable culture chamber according to an embodiment of the present invention, moves the culture chamber in which the microalgae are cultured laterally, thereby arranging the microalgae pattern. It is a microalgae bioenergy production window that can increase aesthetics through change and realize an arrangement pattern by using a variable culture chamber that can change the shade position according to sunlight. It includes a flow path part 130, a culture chamber 140 and an upper driving part 150.

2 is a view for explaining a window of a microalgae bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.

Referring to FIG. 2, the window 110 is a window for blocking the inside of the building from the outside, and includes a chamber type window 111, an upper frame 112, a lower frame 113, one frame 114 and the other side. It is made including a frame 115.

Here, the chamber-type window 111 is made of a transparent material and has an open top and bottom shape to form a predetermined space inside.

In addition, the upper frame 112 is coupled to the upper portion of the chamber type window 111, and a first motor M1 is provided.

3 is a view for explaining an upper frame of a microalgae bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention, and FIG. 4 is a variable culture according to an embodiment of the present invention. It is a drawing for explaining the upper passage frame and the upper drive frame of the microalgae bioenergy production window that can implement a pattern using a chamber.

3 or 4, the upper frame 112 includes an upper window frame frame 112a, an upper passage frame 112b, an upper driving unit frame 112c, an upper outer frame 112d, and an upper motor frame 112e. ), including

Here, the upper window frame 112a is connected to the upper part of the chamber type window 111 .

In addition, the upper flow passage frame 112b is connected to the upper end of the upper window frame frame 112a, and the water supply passage portion 120 is provided therein to protect the water supply passage portion 120.

In addition, the upper driving part frame 112c is connected to the upper end of the upper passage part frame 112b, and the upper driving part 150 is provided therein to protect the upper driving part 150.

In addition, the upper outer frame 112d is inserted from the top to the bottom of the upper flow path frame 112b and the upper driving unit frame 112c, so that the upper flow path frame 112b and the upper driving unit frame 112c and a first motor M1 is provided at the top.

In addition, the upper motor frame 112e is connected to an upper end of the upper outer frame 112d and protects the first motor M1.

Here, the motor frame 112e has an effect of increasing the heat insulating property of the window 110 by providing a heat insulating material in a space other than the space where the first motor M1 is provided.

In addition, the lower frame 113 is coupled to the lower portion of the chamber type window 111, and a second motor M2 is provided.

5 is a view for explaining a lower frame of a microalgal bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.

Referring to FIG. 5 , the lower frame 113 includes a lower window frame 113a, a lower passage frame 113b, a lower driving unit frame 113c, a lower outer frame 113d, and a lower motor frame 113e. It is done by

Here, the lower window frame 113a is connected to the lower part of the chamber type window 111 .

In addition, the lower flow passage frame 113b is connected to the lower end of the lower window frame frame 113a and has the drainage passage portion 130 therein to protect the drainage passage portion 130 .

In addition, the lower driving unit frame 113c is connected to the lower end of the lower passage frame 113b and has the lower driving unit 160 inside to protect the lower driving unit 160 .

In addition, the lower outer frame 113d is inserted into the lower flow path frame 113b and the lower drive frame 113c from the bottom to the top, thereby forming the lower flow path frame 113b and the drive frame 113c. and a second motor M2 is provided at the lower end.

Also, the lower motor frame 113e is connected to an upper end of the lower outer frame 113d and protects the second motor M2.

Here, in the motor frame 113e, a heat insulating material is provided in a space b other than the space a where the second motor M2 is provided, so that the heat insulating property of the window 110 can be increased.

In addition, the one side frame 114 is coupled to one side of the chamber type window 111 .

In addition, the other side frame 115 is coupled to the other side of the chamber type window 111 .

6 is a view for explaining a water supply passage of a microalgae bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.

Referring to FIG. 6, the water supply passage part 120 is provided in plurality so as to communicate with each other along the lateral direction inside the upper frame 112, the first water supply passage 121 and the second water supply passage 122 and an accordion water supply pipe 123.

Here, the first water supply passage 121 is provided in a pipe shape with both sides open.

In addition, one side of the second water supply passage 122 communicates with the central portion of the first water supply passage 121 and extends integrally toward the lower direction orthogonal to the first water supply passage 121 .

In addition, the accordion water supply pipe 123 is provided on one side and the other side of the first water supply passage 121, respectively, and is formed as a pair.

Here, the first water supply passage 121 and the accordion water supply pipe 123 may be coupled and separated.

7 is a view for explaining a drain passage portion of a microalgae bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.

Referring to FIG. 7 , the drainage passage part 130 is provided in plurality so as to communicate with each other along the lateral direction inside the lower frame 113, the first drainage passage 131 and the second drainage passage 132 and an accordion drain pipe 133.

Here, the first drain passage 131 is provided in a pipe shape with both sides open.

In addition, one side of the second drain passage 132 communicates with the central portion of the first drain passage 131 and integrally extends toward an upper direction orthogonal to the first drain passage 131 .

In addition, the accordion drain pipe 132 is provided on one side and the other side of the first drain passage 131, respectively, and is formed as a pair.

Here, the first drain passage 131 and the accordion drain pipe 133 may be coupled and separated.

8 is a view for explaining a culture chamber of a microalgae bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.

Referring to FIG. 8, the culture chamber 140 has a tubular shape, is provided in the inner space of the chamber-type window 111, has an upper end connected to the other side of the second water supply passage 122, and a lower end thereof. It is connected to the other side of the second drainage passage 132, and microalgae are cultured on the inside.

Here, the culture chamber may be provided with a stretchable flexible plastic material.

In addition, rotational coupling recesses (Y1) are formed at the upper and lower ends of the culture chamber 140, and the rotational defect grooves (Y2) are formed at the lower end of the second water supply passage 122 and the upper end of the second drain passage 132. ) Is formed, the upper end of the culture chamber 140 is coupled with the lower end of the second water supply passage 122 through the rotational coupling of the coupling recess (Y1) and the coupling groove (Y2), and the culture chamber ( 140) is coupled to the upper end of the second drain passage 132.

Here, it is preferable that the culture chamber 140 is coupled through rotation in the same direction when coupled.

The reason is to prevent separation of the culture chamber 140 from the second water supply passage 122 and the second drain passage 132 .

In addition, the culture chamber 140 is provided in the inner space of the chamber-type window 111 to increase the thermal insulation of the window 110, and the noise and vibration generated in the culture chamber 140 There is an effect that can be reduced through the culture chamber 140 and the chamber type window 111.

9 is a view for explaining an upper driving part of a microalgal bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.

Referring to FIG. 9, the upper driving unit 150 is connected to the first water supply passage 121 and moves the water supply passage part 120 in a lateral direction so that the upper end of the culture chamber 140 moves in a lateral direction. to be moved to

That is, the upper end of the culture chamber 140 is moved laterally, and the position of the upper end of the culture chamber 140 is changed inside the chamber-type window 111, thereby changing the arrangement pattern of the microalgae. It is possible to smoothly cultivate microalgae by increasing aesthetics and increasing the amount of sunlight according to the location of sunlight.

At this time, the upper end of the culture chamber 140 is movable in the lateral direction through the expansion and contraction of the flexible plastic material.

10 is a view for explaining the lower driving part of the microalgal bioenergy production window capable of implementing a pattern using a variable culture chamber according to the present invention.

Referring to FIG. 10, the microalgae bioenergy production window, which can be patterned using a variable culture chamber according to an embodiment of the present invention, further includes a lower driver 160 that moves the lower part of the culture chamber laterally. may be provided, including

Here, the lower driving part 160 is connected to the first drain passage 131 and moves the drain passage part 130 in a lateral direction so that the lower end of the culture chamber 140 moves in a lateral direction.

That is, the lower end of the culture chamber 140 is moved laterally, and the position of the lower end of the culture chamber 140 is changed inside the chamber-type window 111, thereby changing the arrangement pattern of the microalgae. It is possible to smoothly cultivate microalgae by increasing the aesthetic sense and increasing the amount of sunlight according to the position of the solar light.

Here, when the upper and lower ends of the culture chamber 140 slide in opposite directions to each other, the culture chamber 140 becomes obliquely stretched by the flexible plastic material, and the culture chamber 140 When the upper and lower ends of the 140 slide in the same lateral direction, the culture chamber 140 becomes densely packed in the lateral direction.

11 is a view for explaining an air supply passage of a microalgal bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.

Referring to FIG. 11, the microalgae bioenergy production window, which can be patterned using a variable culture chamber according to an embodiment of the present invention, further includes an air supply passage part 170 for supplying air to the drainage passage part 130. may be provided, including

Here, the air supply passage part 170 includes an air supply bracket 171, an air supply passage 172, and an accordion air supply pipe 173.

In addition, the air supply bracket 171 has a shape surrounding the first drainage passage 131 from the outside and is formed with an internal passage inside, communicates with the internal passage at a position in contact with the first drainage passage 131, and is in communication with the first drainage passage 131. 1 An air supply pin 171-1 inserted into and installed in the drain passage 131 is provided.

More specifically, the air supply bracket 171 is installed with the air supply pin 171-1 inserted into the air supply hole 171-2 formed on the outer surface of the first drain passage 131.

In addition, the air supply passage 172 has a pipe shape with both sides open, is provided in the same direction as the first drain passage 131, and communicates with the internal passage of the air supply bracket 171.

In addition, the accordion air supply pipe 173 is provided on one side and the other side of the air supply passage 172, respectively, and is formed as a pair.

That is, the air supply passage part 170 supplies external air, and the supplied external air is supplied to the culture chamber 140 via the drainage passage part 130 .

12 is a view for explaining the exhaust passage of the microalgae bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.

Referring to FIG. 12, the microalgae bioenergy production window, which can be patterned using a variable culture chamber according to an embodiment of the present invention, further includes an exhaust passage part 180 for discharging air with increased oxygen concentration, may be provided.

Here, the exhaust passage part 180 includes an exhaust bracket 181, an exhaust passage 182, and an accordion exhaust pipe 183.

In addition, the exhaust bracket 181 is shaped to surround the first water supply passage 121 from the outside, and has an internal passage formed therein, and communicates with the internal passage at a position in contact with the first water supply passage 121, An exhaust fin 181-1 inserted into and installed in the first water supply passage 121 is provided.

More specifically, the exhaust bracket 181 may be installed with the exhaust pin 181-1 inserted into the exhaust hole 181-2 formed on the outer surface of the first water supply passage 121.

In addition, the exhaust passage 182 has a pipe shape with both sides open, is provided in the same direction as the first water supply passage 121, and communicates with the internal passage of the exhaust bracket 181.

In addition, the accordion exhaust pipe 183 is provided on one side and the other side of the exhaust passage 182, respectively, and is formed as a pair.

That is, the exhaust passage part 180 serves to exhaust the air supplied from the water supply passage part 120 to the outside.

Here, the air supplied to the water supply passage part 120 is air having an increased oxygen concentration in the culture chamber 140 .

13 is a view for explaining the flow of a mixed solution and the flow of air in a microalgae bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.

Referring to FIG. 13, the nutrient mixture (a') containing the microalgae culture medium flows in a lateral direction through the first water supply passage 121 and the accordion water supply pipe 123, and passes through the second water supply passage 122. It is supplied to each culture chamber 140 through.

Here, the culture chamber 140 cultures microalgae through the supplied nutrient mixture solution (a), and the microalgae mixture solution (b') containing the cultured microalgae passes through the second drainage passage 132. and discharged to the outside through the first drain passage 131 and the accordion drain pipe 133.

In addition, the outside air (a) is introduced in the lateral direction through the air supply passage 172 and the accordion air supply pipe 173, and passes through the air supply bracket 171 and the drainage passage part 130 to the culture chamber ( 140) is supplied.

Here, the external air supplied to the culture chamber 140 becomes air (b) in which the oxygen concentration is increased through the cultivation of microalgae, and the air (b) in which the oxygen concentration is increased is the water supply passage part 120 and the exhaust bracket 181, and is exhausted to the outside through the exhaust passage 182 and the accordion exhaust pipe 183.

That is, by culturing microalgae through the nutrient mixture (a′) and external air (a), the oxygen concentration of the external air is increased, and the air (b) having an increased oxygen concentration is exhausted to the outside.

In addition, the microalgae mixture (b') inside the culture chamber 140 is discharged at regular intervals.

14 is a view for explaining the driving mechanism of the upper driving unit of the microalgal bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.

Referring to FIG. 14, the upper driving unit 150 moves the water supply passage unit 120 laterally, and the upper rack gear 151, the upper pinion gear 152, the upper driving control gear 153, the upper It consists of a chain 154 and an upper derailleur 155.

Here, the upper rack gear 151 is provided on the outside of the air supply bracket 171, respectively.

In addition, the upper pinion gear 152 is located on each upper rack gear 151.

In addition, the upper drive control gear 153 includes an upper spur gear part 153-1 and an upper bearing part 153-2 that engage with each of the upper pinion gears 152 to rotate the upper pinion gear 152. It is done by

In addition, the upper chain 154 is connected to and provided with the upper spur gear unit 153-1.

Also, the upper transmission 155 varies the height of the upper chain 154.

Here, the upper spur gear unit 153-1 is formed at different heights.

15 is a view for explaining the driving mechanism of the lower driving unit of the microalgal bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.

Referring to FIG. 15, the lower drive unit 160 moves the drain passage unit 130 in a lateral direction, and includes a lower rack gear 161, a lower pinion gear 162, a lower drive control gear 163, and a lower gear. It consists of a chain 164 and a lower transmission 165.

Here, the lower rack gear 161 is provided on the outside of the exhaust bracket 181, respectively.

In addition, the lower pinion gear 162 is located on each lower rack gear 161.

In addition, the lower drive control gear 163 includes a lower spur gear part 163-1 and a lower bearing part 163-2 that engage with each of the lower pinion gears 162 to rotate the lower pinion gear 162. It is done by

In addition, the lower chain 164 is connected to the lower spur gear unit 163-1.

Also, the lower transmission 165 varies the height of the lower chain 164 .

Here, the lower spur gears 163-1 are formed at different heights.

16 is a view for explaining an individual driving mechanism of an upper driving unit of a microalgal bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.

Referring to FIG. 16, first, the first motor M1 rotates the upper motor barbell gear 158 to rotate the cassette sprocket-shaped upper chain gear 157.

Next, the upper chain gear 157 transmits power to the upper chain 154 to rotate the upper spur gear 153-1 connected to the upper chain 154.

Then, the upper spur gear part 153-1 rotates the upper barbell gear 156, thereby rotating the upper pinion gear 152.

Next, rotation of the upper pinion gear 152 causes the upper rack gear 151 to slide in a lateral direction, thereby moving the water supply passage part 120 .

Referring to (a) of FIG. 16 , the upper first spur gear part 153-1a provided above the first water supply passage part 120a is connected to the upper chain 154 and is driven.

On the other hand, the upper second spur gear part 153-1b provided on the upper part of the second water supply passage part 120b is provided at a higher position than the upper first spur gear part 153-1a, so that the upper chain 154 ) is connected to the upper second bearing part 153-2b, so that the second water supply passage part 120b does not move in the lateral direction.

In addition, the upper third spur gear part 153-1c provided above the third water supply passage part 120c is provided at a higher position than the upper second spur gear part 153-1b.

In addition, the upper fourth spur gear part 153-1d provided above the fourth water supply passage part 120d is provided at a higher position than the upper third spur gear part 153-1c.

Referring to (b) of FIG. 16, in the upper chain 154, the upper fourth spur gear part 153-1d provided on the upper part of the fourth water supply passage part 120d and the upper chain 154 are connected. Thus, only the fourth water supply passage part 120d is moved in the lateral direction.

That is, as the height of the upper chain 154 is varied by the upper transmission 155, the first water supply passage part 120a, the second water supply passage part 120b, and the third water supply passage part ( 120c) and the fourth water supply passage part 120d are driven individually.

In addition, since the driving mechanism of the lower driving unit 160 is the same as that of the upper driving unit 150, a detailed description thereof will be omitted.

17 is a view for explaining the shape of the culture chamber according to the driving of the upper driving unit and the lower driving unit of the microalgae bioenergy production window capable of implementing a pattern using a variable culture chamber according to an embodiment of the present invention.

Referring to FIG. 17, eight culture chambers 140 are installed in the inner space of the chamber-type window 111, and each of the culture chambers 140 is a, b, c, d, e, f, g , expressed as h.

Here, (a) is the shape of the culture chamber 140 when the upper drive unit 150 and the lower drive unit 160 are not driven, and (b) is the culture chamber 140 of b, c, and d is moved to the other side, and the culture chambers 140 of e, f and g are moved to one side, (c) the culture chambers 140 of a, c, e and g are moved to the other side, b, The culture chambers 140 of d, f, and h are moved to one side, and (d) the top of the culture chambers 140 of a, c, e, and g are moved to the other side, and b, d, f, and h The lower end of the culture chamber 140 is moved to one side, (e) is the upper end of the culture chamber 140 of a, b, c, d, e, , f, g, h is moved to one side, a, b, c, d, e, f, g, h of the lower end of the culture chamber 140 is moved to the other side, (f) is a, b, c, d of the lower end of the culture chamber 140 is one side , and the bottom of the culture chamber 140 of e, f, g, and h is moved to the other side.

Here, the culture chamber 140 is driven individually, so that aesthetics can be increased in terms of interior, and the light blocking position can be changed according to sunlight.

As described above, according to the microalgae bioenergy production window capable of implementing a pattern using the variable culture chamber according to the present invention, it is possible to change the arrangement pattern of microalgae through individual movement of the culture chamber, thereby increasing aesthetics. , it has the advantage that the position of shading can be changed according to sunlight.

In addition, it is possible to exhaust air with increased oxygen concentration to the outside by culturing microalgae, to increase the insulation of windows and doors through the culture chamber and chamber-type windows, and to reduce noise and vibration generated in the culture chamber. has the advantage of

As described above, the present invention has been shown and described with preferred embodiments, but is not limited to the above embodiments, and to those skilled in the art within the scope of not departing from the spirit of the present invention Various changes and modifications will be possible.

Window: 110 Chamber type window: 111
Upper frame: 112 Upper window frame: 112a
Upper passage frame: 112b Upper drive frame: 112c
Upper outer frame: 112d Upper motor frame: 112e
Lower Frame: 113 Lower Sash Frame: 113a
Lower passage frame: 113b Lower drive frame: 113c
Lower outer frame: 113d Lower motor frame: 113e
One frame: 114 The other frame: 115
Water supply passage: 120 First water supply passage: 121
2nd water supply path: 122 Accordion water supply pipe: 123
Drainage passage: 130 First drainage passage: 131
2nd drainage channel: 132 Accordion drainage pipe: 133
Culture chamber: 140 Upper driving unit: 150
Upper rack gear: 151 Upper pinion gear: 152
Upper drive control gear: 153 Upper chain: 154
Upper Transmission: 155 Upper Barbell Gear: 156
Upper chain gear: 157 Upper motor barbell gear: 158
Lower drive unit: 160 Lower rack gear: 161
Lower pinion gear: 162 Lower drive control gear: 163
Lower Chain: 164 Lower Derailleur: 165
Lower barbell gear: 166 Lower chain gear: 167
Lower motor barbell gear: 168 Air supply passage: 170
Air supply bracket : 171 Air supply path : 172
Accordion air supply pipe: 173 Exhaust passage: 180
Exhaust bracket: 181 Exhaust passage: 182
Accordion Exhaust Pipe: 183 1st Motor: M1
2nd Motor: M2 Rotation Joint: Y1
Rotary coupling groove: Y2

Claims (12)

A chamber-type window made of a transparent material and provided in an open top and bottom form so that a predetermined space is formed inside; an upper frame coupled to an upper portion of the chamber-type window and equipped with a first motor; a lower frame coupled to a lower portion of the chamber-type window and equipped with a second motor; One side frame coupled to one side of the chamber type window; windows and doors including; the other frame coupled to the other side of the chamber-type window;
A first water supply passage having a pipe shape with both sides open; One side communicates with the central portion of the first water supply passage, the second water supply passage integrally extending toward the lower direction orthogonal to the first water supply passage; and a pair of accordion water supply pipes provided on one side and the other side of the first water supply passage, respectively, and a plurality of water supply passage units provided inside the upper frame to communicate with each other along a lateral direction;
A first drainage passage having a pipe shape with both sides open; a second drainage passage integrally extending toward an upper direction orthogonal to the first drainage passage and communicating with a central portion of the first drainage passage; and a pair of accordion drain pipes respectively provided on one side and the other side of the first drain passage, and a plurality of drain passage portions provided inside the lower frame to communicate with each other along a lateral direction;
Tubular shape, provided in the inner space of the chamber-type window, an upper end connected to the other side of the second water supply passage, a lower end connected to the other side of the second drainage passage, and a culture chamber in which microalgae are cultured. ; and
An upper driving unit connected to the first water supply passage and moving the water supply passage part in a lateral direction so that the upper end of the culture chamber is moved in a lateral direction; microalgae bioenergy capable of implementing a pattern using a variable culture chamber including production windows.
According to claim 1,
A microalgae bio-pattern capable of being realized using a variable culture chamber further comprising a lower drive unit connected to the first drainage passage and moving the drainage passage part in a lateral direction so that the lower end of the culture chamber is moved in a lateral direction. energy production windows.
According to claim 2,
An air supply bracket having an inner flow path formed inside in a shape surrounding the first drain flow path from the outside, communicating with the inner flow path at a position in contact with the first drain flow path, and having an air supply pin inserted into and installed in the first drain flow path.
An air supply passage having a pipe shape with both sides open and provided in the same direction as the first drainage passage and communicating with the internal passage of the air supply bracket; and
An air supply passage unit including a pair of accordion air supply pipes provided on one side and the other side of the air supply passage,
Microalgae bioenergy production windows that can realize patterns using a variable culture chamber, characterized in that external air is supplied through the air supply passage part and supplied to the culture chamber through the drain passage part.
According to claim 1,
An exhaust bracket having an internal flow path formed inside in a shape surrounding the first water supply path from the outside, communicating with the internal flow path at a position in contact with the first water supply path, and having an exhaust fin inserted into and installed in the first water supply path.
An exhaust passage having a pipe shape with both sides open and provided in the same direction as the first water supply passage and communicating with the internal passage of the exhaust bracket; and
An exhaust passage unit including a pair of accordion exhaust pipes provided on one side and the other side of the exhaust passage, respectively;
Microalgae bioenergy production windows capable of implementing a pattern using a variable culture chamber, characterized in that the air of the culture chamber is discharged to the outside through the water supply passage portion and the exhaust passage portion.
According to claim 4,
The upper driving part
Upper rack gears provided on the outside of the exhaust bracket, respectively;
an upper pinion gear positioned on each of the upper rack gears;
an upper drive control gear including an upper spur gear part and an upper bearing part that engage with each of the upper pinion gears to rotate the upper pinion gear;
an upper chain connected to the upper spur gear unit;
An upper transmission for varying the height of the upper chain; includes,
The upper spur gear portion is a microalgae bioenergy production window that can be patterned using a variable culture chamber, characterized in that formed at different heights.
According to claim 3,
the lower driving unit
Lower rack gears provided on the outside of the air supply bracket, respectively;
a lower pinion gear positioned on each of the lower rack gears;
a lower driving control gear including a lower spur gear portion and a lower bearing portion engaged with each of the lower pinion gears to rotate the lower pinion gears;
a lower chain connected to the lower spur gear unit;
A lower transmission for varying the height of the lower chain; includes,
The lower spur gear portion is a microalgae bioenergy production window that can be patterned using a variable culture chamber, characterized in that formed at different heights.
According to claim 1 or 2,
When the upper and lower ends of the culture chamber are slid in opposite directions to each other, the culture chamber is elongated in an oblique shape,
When the top and bottom of the culture chamber are slid in the same lateral direction, the culture chamber is a microalgae bioenergy production window that can be patterned using a variable culture chamber, characterized in that the form is dense in the lateral direction.
According to claim 1,
The nutrient mixture solution is supplied to the culture chamber through the water supply passage part, and the microalgae inside the culture chamber are cultured, and the microalgae mixture solution generated after culture is discharged to the outside through the drain passage part. A microalgae bioenergy production window that can be patterned using a chamber.
According to claim 1,
the upper frame
an upper window frame connected to an upper portion of the chamber-type window;
an upper flow channel portion frame connected to an upper end of the upper window frame frame and provided inside the water supply passage portion to protect the water supply passage portion;
an upper driving part frame connected to an upper end of the upper passage part frame and protecting the upper driving part;
an upper outer frame inserted from the top of the upper drive frame in a downward direction to protect the upper flow path frame and the upper drive frame, and having a first motor at an upper end; and
A microalgae bioenergy production window that is capable of pattern implementation using a variable culture chamber that further includes: an upper motor frame connected to an upper end of the upper outer frame and protecting the first motor.
According to claim 2,
the lower frame
a lower window frame connected to a lower portion of the chamber-type window;
a lower passage portion frame connected to a lower end of the lower window frame frame and protecting the drainage passage portion;
a lower driving part frame connected to a lower end of the lower passage part frame and protecting the lower driving part;
a lower outer frame fitted from the bottom of the lower driving unit frame upward to protect the lower passage frame and the lower driving unit frame, and having a second motor at a lower end thereof; and
Connected to the top of the lower outer frame, the lower motor frame for protecting the second motor; microalgae bioenergy production window that can be patterned using a variable culture chamber, characterized in that it further comprises.
According to claim 9 or 10,
The upper motor frame is provided with a heat insulating material in a space other than the space in which the first motor is provided,
The lower motor frame is a microalgae bioenergy production window that can implement a pattern using a variable culture chamber, characterized in that the insulating material is provided in a space other than the space provided with the second motor.
According to claim 1,
A variable type characterized in that a rotational coupling groove is formed at the bottom of the second water supply passage and the top of the second drainage passage, and a rotational coupling recess that is rotationally engaged with the rotational coupling groove is formed at the top and bottom of the culture chamber. A microalgae bioenergy production window that can be patterned using a culture chamber.

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