KR20230106950A - Eco-frienddly cultivation device - Google Patents

Abstract

A plant air cultivation apparatus according to the present invention relates to a plant air cultivation apparatus for cultivating plants by fixing them in the air, and includes a bottom frame having a circular opening formed in the center of the lower end, and vertically installed on the outer surface of the bottom frame. A frame unit including a vertical frame to be; At least one which is provided in a horizontal direction inside the frame unit, has a plurality of circular through-holes formed on an upper surface thereof, and has a plurality of insertion slits formed in a radial direction of the through-holes, through which the plant is inserted and fixed. more than one discharge unit; and a nutrient solution supply unit installed on the upper side of the discharge unit and supplying the nutrient solution to the discharge unit. According to the plant air cultivation apparatus of the present invention, plants can be easily fixed in the air using an insertion slit, and high-density plant cultivation per unit area is possible, thereby reducing labor and time. In addition, the structure fixed in the air and the through hole of the medium unit are implemented to facilitate the flow of air in contact with the plant, thereby reducing the propagation of bacteria and increasing the supply of oxygen and nitrogen necessary for growth. The structure as described above makes it easy to easily observe and manage the growth state of the root. In addition, by harvesting the plant fixed to the insertion slit through the through hole, damage to the plant is reduced, harvesting is facilitated, and plant cultivation is possible without using soil.

Description

Eco-friendly cultivation device {ECO-FRIENDDLY CULTIVATION DEVICE}

The present invention relates to an eco-friendly cultivation device.

In general, ginseng is vulnerable to diseases and pests, and is greatly affected by the surrounding environment such as soil quality, temperature, humidity, and amount of sunlight in cultivation. Ventilation and drainage are also important. When ginseng is usually grown in soil, it is harvested after cultivating for more than 5 years. Because cultivation is difficult for the reasons described above, it is difficult to maintain good environmental conditions for cultivation for a long time. Therefore, recently, hydroponic cultivation using water is used to grow ginseng more easily and increase the yield. In hydroponic cultivation, ginseng seedlings grown for about a year are transplanted and cultivated, and they are grown and harvested in 4 months.

Hydroponic ginseng has the advantage of eliminating damage from the soil and being able to be consumed immediately after harvest. In addition, it contains saponin similar to that of 5-year-old ginseng, and sprout ginseng contains 6-10 times more saponin than regular fresh ginseng. In addition, ginsenoside F5, which is extracted only from the leaves of hydroponically cultivated ginseng, suppresses the production of nitric oxide, one of the substances that cause inflammation, and suppresses the production of melanin, so it has an excellent whitening effect. In addition, sprout ginseng contains Rg, Rd, and Re components that white ginseng, fresh ginseng, and root ginseng do not contain, helping blood circulation. For this reason, various technologies for growing ginseng sprouts through hydroponic cultivation are being developed.

As a technology related to the above conventional hydroponic ginseng cultivation apparatus, Korean Patent Publication No. 10-2012-0103227 is disclosed. However, in the conventional ginseng cultivation apparatus as described above, it takes a lot of time and labor to plant ginseng in a planting hole, and ginseng may be damaged. In addition, since the planted part is blocked by ginseng in all directions, it is difficult to observe the state of the root part, and smooth air flow is hindered. Therefore, due to the failure to observe the root of ginseng and the state of the disease, it is impossible to take prompt measures, which can affect the growth of ginseng. In addition, in harvesting ginseng after cultivation, there is an inconvenience in that the urethane sponges must be separated and harvested one by one.

The present invention was created to solve the above problems, and it is possible to minimize damage to plants by fixing them in the air, to maintain smooth air flow, and to facilitate harvesting of plants after cultivation. Its purpose is to provide an air plant cultivation device.

Plant air cultivation apparatus according to the present invention for achieving the above object relates to a plant air cultivation apparatus for cultivating plants by fixing them in the air, comprising: a bottom frame having a circular opening in the center of the lower end; A frame unit including a vertical frame installed vertically on an outer surface of the bottom frame; At least one which is provided in a horizontal direction inside the frame unit, has a plurality of circular through-holes formed on an upper surface thereof, and has a plurality of insertion slits formed in a radial direction of the through-holes, through which the plant is inserted and fixed. more than one discharge unit; and a nutrient solution supply unit installed on the upper side of the discharge unit and supplying the nutrient solution to the discharge unit.

According to the plant air cultivation apparatus according to the present invention, plants can be easily fixed in the air using an insertion slit, and high-density plant cultivation per unit area is possible, thereby reducing labor and time. In addition, the structure fixed in the air and the through hole of the medium unit are implemented to facilitate the flow of air in contact with the plant, thereby reducing the propagation of bacteria and increasing the supply of oxygen and nitrogen necessary for growth. The structure as described above makes it easy to easily observe and manage the growth state of the root.

In addition, by harvesting the plant fixed to the insertion slit through the through hole, damage to the plant is reduced, harvesting is facilitated, and plant cultivation is possible without using soil.

1 is a perspective view showing a plant air cultivation apparatus according to a first embodiment of the present invention;
Figure 2 is a side view of the plant air cultivation apparatus shown in Figure 1;
Figure 3 is a perspective view of the delivery unit of the plant air cultivation apparatus shown in Figure 1;
4 is a state diagram showing a state in which plants are fixed to the insertion slit of the discharge unit shown in FIG. 3;
5 is a perspective view of the delivery unit of the plant air cultivation apparatus according to the second embodiment of the present invention;
6 is a perspective view showing a method of mounting the delivery unit of the plant air cultivation apparatus according to a third embodiment of the present invention;
7 is a perspective view showing a method of mounting the delivery unit of the plant air cultivation apparatus according to a fourth embodiment of the present invention;
8 is a perspective view showing a method of mounting the delivery unit of the plant air cultivation apparatus according to a fifth embodiment of the present invention;
FIG. 9 is a perspective view showing a means for moving the delivery unit used when moving the delivery unit shown in FIG. 3 .

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. Prior to this, the terms or words used in this specification and claims should not be construed as being limited to the usual or dictionary meaning, and the inventor appropriately uses the concept of the term in order to explain his/her invention in the best way. Based on the principle that it can be defined, it should be interpreted as meaning and concept consistent with the technical spirit of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and do not represent all of the technical ideas of the present invention, so at the time of this application, they are equivalent alternatives that can be replaced. It should be understood that variations may exist.

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

1 is a perspective view showing a plant air cultivation apparatus according to a first embodiment of the present invention, FIG. 2 is a side view of the plant air cultivation apparatus shown in FIG. 1, and FIG. 3 is a discharge unit of the plant air cultivation apparatus shown in FIG. , and FIG. 4 is a state diagram showing a state in which plants are fixed to the insertion slit of the discharge unit shown in FIG. 3 .

1 to 4, the plant air cultivation apparatus 10 according to the present invention relates to a plant air cultivation apparatus 10 for cultivating plants P by fixing them in the air, and includes a frame part 100, a delivery part ( 200), and a nutrient solution supply unit 300. Here, the plant (P) is preferably sprouted ginseng, as shown in FIG. 4, but this is exemplary and can be applied to other plants that require air cultivation.

The frame part 100 forms a space inside, and the plant P is grown in the space inside the frame part 100 . To this end, the frame unit 100 includes a bottom frame 110 and a vertical frame 120 .

The bottom frame 110 has a circular opening 111 formed in the central portion. Air may be smoothly circulated through the opening 111 . In addition, the opening 111 can activate the flow of air to cause convection without using an additional power source. Therefore, air is constantly circulated into the frame unit 100 . In addition, the bottom frame 110 may be formed spaced apart from the ground, and preferably has a rectangular shape.

The vertical frame 120 is vertically installed along the outer edge of the bottom frame 110 . That is, a plurality of vertical frames 120 may be vertically installed along the rectangular edges of the bottom frame 110 . In addition, the vertical frame 120 is preferably to use a pipe made of stainless steel (stainless steel) material that is less corrosive and resistant to impact, but is not limited thereto, and the material and type may be various.

Meanwhile, the frame unit 100 may further include a moving unit 130, a transparent material 140, and a supporting unit 150. The moving unit 130 is coupled to the lower portion of the frame unit 100 to enable movement. As the moving means 130, it is preferable that one or more wheels are used. Plants (P) can be grown by moving the plant air cultivation device 10 to an appropriate position using the wheels. The moving means 130 is suitably provided at the lower end of the vertical frame 120, but is not limited thereto and may be installed at the lower end of the bottom frame 110.

The transparent material 140 is fixed along the outside of the vertical frame 120 . That is, it is preferable to form the inside of the frame part 100 through the transparent material 140 . The transparent material 140 is a transparent material and allows the inside of the frame part 100 to be seen, and the transparent material 140 is a growth process of the plant P grown inside the frame part 100 to be able to watch Through the transparent material 140, it is possible to prevent the nutrient solution sprayed from the nutrient solution supply unit 300, which will be described later, from leaking out of the plant air cultivation device 10. The transparent material 140 is preferably one of vinyl, acrylic and acetate materials, but is not limited thereto and may be of various types. In addition, the front and rear surfaces of the transparent material 140 are preferably colorless and transparent, and the left and right surfaces may be light green. In addition, as shown in the drawing, it is preferable that the ends of the transparent material 140 constituting the front surface of the frame part 100 are hinged so that the inside of the frame part 100 can be opened and closed. However, the configuration in which the transparent material 140 is coupled by a hinge is exemplary, and the transparent material 140 constituting the front surface of the frame unit 100 may have a structure that can be slid, and using a curtain to It may also be applied to open and close the inside of the frame unit 100 .

The supporting part 150 is installed at a lower side of the dispensing part 200 and spaced apart from the dispensing part 200 . In addition, the receiving part 150 is formed as an inclined surface inclined in one direction so that the nutrient solution to be dropped is moved along the inclined surface. That is, when the nutrient solution supplied through the nutrient solution supply unit 300 to be described later is dropped to the lower end, the nutrient solution moves along the inclined surface of the support part 150 and finally moves to the opening 111.

The dispensing unit 200 is provided in the horizontal direction inside the frame unit 100 and is a device for fixing the plant P in the air. As shown in FIG. 2, the discharge unit 200 is formed with one or a plurality of through holes 210 and an insertion slit 220.

One or more through holes 210 are formed on the upper surface of the discharge unit 200 and have a circular shape. However, the through hole 210 preferably has a circular shape, but is not limited thereto and may be formed in a different shape according to the shape of a plant.

One or more insertion slits 220 are formed radially of the through hole 210, and as shown in FIG. 4, the plant P is inserted into and fixed to the insertion slit 220. This allows a plurality of plants P to be fixed to one through hole 210, enabling high-density cultivation per unit area. Therefore, it is possible to reduce labor and time required for cultivation. In addition, by placing the plant (P) in the air, it is possible to constantly observe and take action on the growth conditions and abnormal signs of the roots, stems and leaves. The structure in which the plant (P) is located in the air prevents the propagation of aquatic bacteria that occurs when the plant (P) is submerged in water and the propagation of bacteria or bacteria in the soil that occurs when it is cultivated in soil. do. This can minimize the possibility of disease infection of the plant (P). In addition, pesticide-free and eco-friendly cultivation is possible by blocking the access or propagation of pests at the source.

In other words, the through hole 210 allows the flow of air contacting the plant P to occur actively. That is, the insertion slit 220 has a structure connected to the through hole 210, and air can be delivered to the plant P fixed to the insertion slit 220. Through this, it is possible to facilitate the respiration of the plant (P) and increase the supply of oxygen and nitrogen necessary for growth. In addition, the insertion slit 220 provides a sufficient movement space when the plant P is planted, and through this, the discharge unit 200 is prevented from sagging downward. In addition, by pushing the cultivated plant P from the insertion slit 220 toward the through hole 210 and harvesting, harvesting is efficient and prevents damage to the plant P.

The discharge unit 200 is preferably composed of foam paper formed by foaming polyethylene. The foam paper can elastically fix the plant (P), so that the plant (P) can be fixed in the air without damage. In addition, it is preferable that a plurality of the discharge unit 200 are stacked vertically apart from each other inside the frame unit 100 . By stacking a plurality of the discharge unit 200, high-density cultivation per unit area is possible. In addition, in order to mount the delivery unit 200 inside the frame unit 100, at least one frame rod 141 provided in a horizontal direction may be provided inside the vertical frame 120. That is, the delivery unit 200 may be seated and supported on the upper portion of the frame rod 141 .

The nutrient solution supply unit 300 is installed above the delivery unit 200 and is spaced apart from the delivery unit 200, and supplies nutrient solution to the plant P fixed to the insertion slit 220. Here, the nutrient solution is preferably a mixture of a culture solution containing water and nutrients. To this end, the nutrient solution supply unit 300 includes a nutrient solution supply pump 310, a water supply pipe 320, and a spraying device 330.

The nutrient solution supply pump 310 provides pressure for moving the nutrient solution toward the discharge unit 200. To this end, the nutrient solution supply pump 310 may be provided in a water storage tank 340 to be described later, as shown. However, this is an example, and the nutrient solution supply pump 310 may use an external type installed outside the water tank if necessary.

The water supply pipe 320 receives the pressure of the nutrient solution supply pump 310 in the water storage tank at the lower end and functions to deliver the supplied nutrient solution. Here, the water supply pipe 320 may be formed in a dual structure to deliver water and culture medium, respectively.

The injection/spraying device 330 is installed in the water supply pipe 320 and can spray the nutrient solution toward the delivery unit 200. It is preferable that a plurality of spraying/spraying devices 330 are installed corresponding to the size and location of the dispensing unit 200 . In addition, the spray spraying device 330 preferably has a spraying strength suitable for the growth of the plant P, depending on the plant P, wherein nano energy wave number is used as the water included in the nutrient solution. desirable. The nanoenergy wave water is decomposed to a size of 1/20,000 of a normal water molecule to promote the growth of the plant (P), and can wash and discharge pesticide components remaining in the root. Accordingly, the injection spraying device 330 may further include a wave counter (not shown). Water that has passed through the wave generator emits wave energy of about 1200 Hz. This can promote the growth of the plant (P) and improve the health of the living body. Absorption of the nutrient solution can be maximized by spraying a mixture of nanoparticled water and nutrient solution to the plant (P). In addition, the mixture can promote the growth of the plant (P) by increasing the permeability of the cell wall of the root and produce a healthy harvest. Here, as an example, the nano-wave water device may generate microbubbles by installing an air pump and an air stone in a reservoir 340 to be described later in which the wave water is stored.

Here, the nutrient solution supply unit 300 may further include a water storage tank 340. The water storage tank 340 is installed at the lower end of the opening 111 . The water supplied to the plant P falls into the water storage tank 340 through the opening 111 and is dripped. Here, the water storage tank 340 is a water tank to be filled with water from the outside and supplied to the water supply pipe 320 .

In addition, the plant air cultivation device 10 may further include a spray control device (not shown). The spray control device is connected to the spray spray device 330 and the nutrient solution supply pump 310, and automatically sprays the nutrient solution supplied to the discharge unit 200 according to a set cycle. That is, the spraying time of the nutrient solution is automatically adjusted to maintain the humidity in the frame part 100, and induce proper water supply to the plant P. It is possible to reduce the amount of water and nutrient solution used appropriately through the injection control device. In addition, the spray control device enables spraying or spraying automatically according to a cycle suitable for growth according to the plant (P).

Meanwhile, the plant air cultivation device 10 may further include an irradiation unit 400 for irradiating light to the plant P.

The irradiation unit 400 is installed spaced apart from the upper side of the discharge unit, and is preferably provided with at least one LED (Light Emitting Diode) lamp. The LED light emits light toward the medium portion 200 into which the plant P is inserted, and this provides a light source suitable for photosynthesis and growth to the plant P to be planted. Therefore, it is preferable that the irradiation unit 400 is a combination of a blue LED, a red LED, and a white LED light emitting light of a wavelength specialized for cultivation of the plant P. In addition, it is preferable that at least one irradiation unit 400 is provided above the discharge unit 200 . That is, at least one irradiation unit 400 may be suitably provided according to the amount or size of the plant P planted in the medium unit 200 . Here, the irradiation unit 400 is preferably an LED lamp that emits light, but is not limited thereto and may be a fluorescent lamp manufactured for plant cultivation.

In addition, a holding plate 145 is provided inside the frame part 100 so that the irradiation part 400 and the water supply pipe 320 can be easily installed. The holding plate 145 is installed at both ends of the frame part 100, and preferably has a "b" shape. In addition, the irradiation unit 400 and the water supply pipe 320 are mounted to the lower end of the holder plate 145 . That is, the holding plate 145 supports both ends of the irradiation unit 400 and the water supply pipe 320 . Here, it is preferable to mount the irradiation unit 400 and the water supply pipe 320 on the lower end of the holder plate 145, but the irradiation unit 400 and the water supply pipe 320 may be mounted on the upper surface of the "B" shape. there is.

Here, the plant air cultivation device 10 may further include an irradiation control device (not shown). Such an irradiation control device may be supported by the dispensing unit 200 being seated thereon.

The nutrient solution supply unit 300 is installed above the delivery unit 200 and is spaced apart from the delivery unit 200, and supplies nutrient solution to the plant P fixed to the insertion slit 220. Here, the nutrient solution is preferably a mixture of a culture solution containing water and nutrients. To this end, the nutrient solution supply unit 300 includes a nutrient solution supply pump 310, a water supply pipe 320, and a spraying device 330.

The nutrient solution supply pump 310 provides pressure for moving the nutrient solution toward the discharge unit 200. To this end, the nutrient solution supply pump 310 may be provided in a water storage tank 340 to be described later, as shown. However, this is an example, and the nutrient solution supply pump 310 may use an external type installed outside the water tank if necessary.

The water supply pipe 320 receives the pressure of the nutrient solution supply pump 310 in the water storage tank at the lower end and functions to deliver the supplied nutrient solution. Here, the water supply pipe 320 may be formed in a dual structure to deliver water and culture medium, respectively.

The injection/spraying device 330 is installed in the water supply pipe 320 and can spray the nutrient solution toward the delivery unit 200. It is preferable that a plurality of spraying/spraying devices 330 are installed corresponding to the size and location of the dispensing unit 200 . In addition, the spray spraying device 330 preferably has a spraying strength suitable for the growth of the plant P, depending on the plant P, wherein nano energy wave number is used as the water included in the nutrient solution. desirable. The nanoenergy wave water is decomposed to a size of 1/20,000 of a normal water molecule to promote the growth of the plant (P), and can wash and discharge pesticide components remaining in the root. Accordingly, the injection spraying device 330 may further include a wave counter (not shown). Water that has passed through the wave generator emits wave energy of about 1200 Hz. This can promote the growth of the plant (P) and improve the health of the living body. Absorption of the nutrient solution can be maximized by spraying a mixture of nanoparticled water and nutrient solution to the plant (P). In addition, the mixture can promote the growth of the plant (P) by increasing the permeability of the cell wall of the root and produce a healthy harvest. Here, as an example, the nano-wave water device may generate microbubbles by installing an air pump and an air stone in a reservoir 340 to be described later in which the wave water is stored.

Here, the nutrient solution supply unit 300 may further include a water storage tank 340. The water storage tank 340 is installed at the lower end of the opening 111 . The water supplied to the plant P falls into the water storage tank 340 through the opening 111 and is dripped. Here, the water storage tank 340 is a water tank to be filled with water from the outside and supplied to the water supply pipe 320 .

In addition, the plant air cultivation device 10 may further include a spray control device (not shown). The spray control device is connected to the spray spray device 330 and the nutrient solution supply pump 310, and automatically sprays the nutrient solution supplied to the discharge unit 200 according to a set cycle. That is, the spraying time of the nutrient solution is automatically adjusted to maintain the humidity in the frame part 100, and induce proper water supply to the plant P. It is possible to reduce the amount of water and nutrient solution used appropriately through the injection control device. In addition, the spray control device enables spraying or spraying automatically according to a cycle suitable for growth according to the plant (P).

Meanwhile, the plant air cultivation device 10 may further include an irradiation unit 400 for irradiating light to the plant P.

The irradiation unit 400 is installed spaced apart from the upper side of the discharge unit, and is preferably provided with at least one LED (Light Emitting Diode) lamp. The LED light emits light toward the medium portion 200 into which the plant P is inserted, and this provides a light source suitable for photosynthesis and growth to the plant P to be planted. Therefore, it is preferable that the irradiation unit 400 is a combination of a blue LED, a red LED, and a white LED light emitting light of a wavelength specialized for cultivation of the plant P. In addition, it is preferable that at least one irradiation unit 400 is provided above the discharge unit 200 . That is, at least one irradiation unit 400 may be suitably provided according to the amount or size of the plant P planted in the medium unit 200 . Here, the irradiation unit 400 is preferably an LED lamp that emits light, but is not limited thereto and may be a fluorescent lamp manufactured for plant cultivation.

In addition, a holding plate 145 is provided inside the frame part 100 so that the irradiation part 400 and the water supply pipe 320 can be easily installed. The holding plate 145 is installed at both ends of the frame part 100, and preferably has a "b" shape. In addition, the irradiation unit 400 and the water supply pipe 320 are mounted to the lower end of the holder plate 145 . That is, the holding plate 145 supports both ends of the irradiation unit 400 and the water supply pipe 320 . Here, it is preferable to mount the irradiation unit 400 and the water supply pipe 320 on the lower end of the holder plate 145, but the irradiation unit 400 and the water supply pipe 320 may be mounted on the upper surface of the "B" shape. there is.

Here, the plant air cultivation device 10 may further include an irradiation control device (not shown). This irradiation control device makes the upper portion 400 more firmly provided inside the frame portion 100 . In addition, the seating part 146b is configured inside the upper end of the fixing part 146a, and the discharge unit 200 can be seated and supported on the upper surface of the seating part 146a. This makes it possible to seat the delivery unit 200 more stably inside the frame unit 100 .

It is preferable that the magnets 143a and 143b are respectively provided on side surfaces where the vertical frame 120 and the delivery support 240 come into contact with each other. That is, the magnet 143b is provided on the side of the vertical frame 120, and the magnet 143a is provided on the corner of the delivery support 240, so that the magnets 143a and 143b correspond to each other so that contact is possible, , Through this, the discharge unit 200 can be fixed to the inside of the frame unit 100 . In addition, the magnet 143b may be provided on an inner upper end of the fixing part 146a. That is, the magnet 143b provided in the fixing part 146a is provided at a position opposite to the magnet 143a provided in the delivery part support 240, and corresponds to the magnet 143a, through which the delivery part ( 200) is fixed. Also, the magnets 143a may be provided at both ends of the seating portion 146b. The magnet 143a provided on the seating portion 146b corresponds to the magnet 143b provided inside the fixing portion 146a, so that the seating portion 146b is fixed to the fixing portion 146. do. Here, the length of the vertical frame 120 and the magnet 143b provided inside the upper end of the fixing part 146a is preferably configured to be longer than the height of the dispensing part 200 . Through this, the position at which the delivery unit 200 is placed can be varied within a certain range, and it can be moved and installed usefully according to the developmental state of the plant (P). In addition, the vertical frame 120 and the length of the magnet 143b provided inside the upper end of the fixing part 146a are arranged vertically at regular intervals, and the height at which the dispensing part 200 is mounted is variable. You can do it.

Hereinafter, a plant air cultivation apparatus 10 according to a fifth embodiment of the present invention will be described with reference to FIG. 8 . 8 is a perspective view showing a method of mounting the delivery unit 200 of the plant air cultivation apparatus 10 according to the fifth embodiment of the present invention. Here, since the same reference numerals shown in FIGS. 1 to 7 are the same members having the same configuration and operation, repetitive description will be omitted.

The plant air cultivation device 10 may further include a channel 144, a holder 144a, and a screw 144b. The channel 144 may be provided on one side of the vertical frame 120 corresponding to a position where the delivery unit 200 is to be seated. It is preferable that a plurality of holes 144h are formed in the channel 144 in a vertical direction. Here, the screw 144b may be inserted into the hole 144h. In addition, the cradle 144a has an “A” shape and is positioned between the vertical frame 120 and the other vertical frame 120 . Therefore, the screw 144b is inserted into the hole 144h, and the holder 144a is seated and supported on the outer surface of the screw 144b protruding through the hole 144h. That is, when the holder 144a is fixed to the outer surface of the screw 144b, the delivery unit 200 or the delivery unit support 240 is seated and supported on the “a” shaped upper surface of the holder 144a. In addition, by selectively inserting the screws 144b into the plurality of holes 144h of the channel 144, the position where the discharge unit 200 is seated can be changed. Through this, the height of the medium unit 200 can be adjusted and moved according to the developmental state of the plant P. Here, the cradle 144a and the screw 144b are exemplary, and protrusions are formed at both ends of the cradle 144a, and the protrusions may be fixed by inserting them into the holes 144h. can also be applied. In addition, the shape of the cradle 144a is not limited to "a", and it can be applied to "ㅡ" shaped flat iron or other shapes. In addition, an intermediate support 146 having a “B” shape may be further provided at the inner center of the frame unit 100 . The intermediate support 146 supports the delivery unit 200 inside the frame unit 100 . To this end, the intermediate support 146 may be composed of a fixing part 146a and a seating part 146b. The fixing part 146a has a “U” shape, and the water supply pipe 320 and the upper side of the irradiation part 400 may be fixed to a lower end thereof. This allows the water supply pipe 320 and the irradiation part 400 to be more firmly provided inside the frame part 100 . In addition, the seating portion 146b constitutes an inner side of the upper end of the fixing portion 146a, and the discharge unit 200 may be seated and supported on the upper surface of the seating portion 146a. Therefore, the delivery unit 200 can be seated more stably inside the frame unit 100 . Here, it is preferable that a plurality of holes 144h are formed in the vertical direction at both ends of the "U" shape of the fixing part 146a. Accordingly, the screw 144b can be inserted into the hole 144h, and the mounting portion 146b is supported on the upper surface of the screw 144b. That is, by selectively inserting the screws 144b into the plurality of holes 144h of the fixing part 146a, the position where the seating part 146b is seated can be changed. This can change the height of the dispensing unit 200 seated on the upper surface of the seating unit 146b. Meanwhile, as a method of fixing the seating portion 146b to the fixing portion 146a, a magnet or a channel using a groove may be applied to the fixing portion 146a.

The plant air cultivation device 10 may further include a delivery unit moving unit 20 . 9 is a perspective view showing the delivery unit moving means 20 used when moving the delivery unit 200 shown in FIG. 3. Referring to FIG. 9, the delivery unit moving means 20 is a moving means support 21, A means frame 22 and a moving means handle 23 may be included. The delivery unit moving unit 20 may be used to move the delivery unit 200 to the frame unit 100 or move the delivery unit 200 to the outside to harvest the planted plants P. .

The dispensing unit moving means 20 is composed of a moving means frame 22 provided vertically. In addition, a moving means support 21 is provided inside the moving means frame 22, and the moving means handle 23 may be installed on one side of the moving means frame 22. The moving means support 21 has a "b" shape, and both ends are fixed to the moving means frame 22. In addition, the delivery unit 200 or the delivery unit support 240 may be seated on the upper surface of the moving means support 21 in a “b” shape. That is, the dispensing unit 200 can be slid and seated inward along the "b" shaped upper surface of the support 142 . In addition, the dispensing unit moving means 20 is provided with wheels at the lower end so that it is easy to move toward the frame part 100, and the dispensing unit moving means 20 is easily moved by gripping the moving means handle 23. This can be usefully utilized when cultivating plants P on a large scale. To this end, it is preferable that a plurality of moving means supports 21 are vertically spaced apart inside the moving means frame 22 and stacked. This can seat the plurality of delivery units 200 and simultaneously move the plurality of delivery units 200 . This can save time and labor and increase production efficiency in plant (P) cultivation.

On the other hand, the plant air cultivation device 10 as described above can be repeatedly arranged or connected. Here, when a plurality of the plant air cultivation devices 10 are repeatedly arranged or connected, the water storage tank 340 may be integrated into one installation. In this installation method, planting, transportation, and management of the plant P can be treated by division of labor. In addition, mass planting and harvesting are possible, enabling mass cultivation in the form of a plant factory.

As described above, according to the plant air cultivation apparatus 10 of the present invention, the plant P can be easily fixed in the air using the insertion slit 220, and high-density plant P cultivation per unit area is possible. This can save labor and time accordingly.

In addition, the structure fixed in the air and the through hole 210 of the delivery unit 200 are implemented so that the flow of air in contact with the plant P is smooth, not only reducing the propagation of bacteria, but also supplying oxygen and nitrogen necessary for growth. promote The structure as described above makes it easy to easily observe and manage the growth state of the root.

In addition, by harvesting the plant P fixed to the insertion slit 220 through the through hole 210, damage to the plant P is reduced, harvesting is easy, and the plant P can be grown without using soil. do.

In addition, the distribution unit 200 installed horizontally inside the plant air cultivation device 10 is spaced vertically and reduces the amount of water and nutrient solution used in inverse proportion to the number of layers.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is only exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

10: Plant air cultivation device 20: Delivery unit moving means
21: vehicle support 22: vehicle frame
23: means of transportation handle 100: frame part
110: floor frame 111: opening
120: vertical frame 130: means of movement
140: transparent material 141: frame rod
142: support 143a, 143b: magnet
144: Channel 144h: Hall
144a: cradle 144b: screw
145: mounting plate 146: intermediate support
146a: fixing part 146b: seating part
150: support part 200: delivery part
210: through hole 220: insertion slit
230: handle 240: delivery support
300: nutrient solution supply unit 310: nutrient solution supply pump
320: water supply pipe 330: spray spraying device
340: water tank 400: investigation unit
P: plant

Claims (1)

It relates to a plant air cultivation device for cultivating plants by fixing them in the air,
A frame unit including a bottom frame having a circular opening formed in a central portion of a lower end and a vertical frame vertically installed at a corner of the bottom frame;
At least one which is provided in a horizontal direction inside the frame unit, has a plurality of circular through-holes formed on an upper surface thereof, and has a plurality of insertion slits formed in a radial direction of the through-holes, through which the plant is inserted and fixed. more than one discharge unit; and
A plant air cultivation apparatus including a nutrient solution supply unit installed on the upper side of the discharge unit and supplying nutrient solution to the discharge unit.

Images