KR101226862B1 - Slope type bed for hydroponic culture device - Google Patents

Abstract

The present invention relates to a hydroponic cultivation apparatus using an inclined bed, the technical problem of the present invention is to provide an inclined bed hydroponic cultivation apparatus that can increase the space utilization of the conventional flat bed using the LED.
LED light emitting unit 10 for irradiating light to the room for this purpose; A port 20 disposed below the LED light emitting unit 10 and seating the seedlings 1; And a bed 30 in which a plurality of insertion holes 30d into which the port 20 is inserted are formed. It is formed to include, the bed 30 is at least a portion is bent to form a bent region (30c), the bent region (30c) is formed that the insertion hole (30d) is inserted into the port 20 Disclosed is a hydroponic cultivation apparatus using an inclined bed.

Description

Inclined Bed Hydroponic Device {SLOPE TYPE BED FOR HYDROPONIC CULTURE DEVICE}

The present invention relates to a hydroponic cultivation apparatus using an inclined bed, and more particularly, to an inclined bed hydroponic apparatus for promoting the development of leafy vegetables by irradiating light of the LED in the state of planting the plant in the bed.

In recent years, the abnormal climate caused by global warming has hampered the stable production of leafy vegetables, causing vegetable waves and Chinese cabbage waves, and increasing the interest in pollution-free organic foods by modern people seeking health and excessive electricity use of existing house facilities. It is causing problems such as.

As an alternative, a hydroponic cultivation system using LED is in the spotlight. Plant cultivation system using LED has the advantages of high efficiency, low heat generation, high life, LED plant factory, LED plant cultivator using the performance of the LED is actively discussed and various related products are on the market.

In this way, the hydroponic cultivation system is also a method of supplying nutrient solution to the plant with the light irradiation function in the LED, even in the plant cultivation apparatus using the LED, in this case to adopt any one of the following four methods as the supply method of nutrient solution .

First, the nutrient solution supply method is a method using a deep flow technique (DFT), a method of cultivating crops by filling a culture medium by adjusting the level of the cultivation tank of a certain size.

Secondly, the nutrient solution supply method is a method using a thin film hydroponic (Nutrient Film Technique, NFT), a gradient to the bed and flowing nutrient solution to circulate while soaking roots.

Thirdly, the nutrient solution supply method is a method using eroponics, which is cultivated by spraying nutrient solution directly to the root zone using the spray nozzle with the roots in the air.

Fourthly, the nutrient solution supply method is a method using rockwool culture, a method of growing crops using aseptic rock wool medium.

Among these various nutrient supply methods, Aeroponics method with high efficiencies of roots by spraying nutrients finely has high growth efficiency. As a result, it is evaluated as an advanced method than the immersion method or the thin film method.

By the way, despite the various feeding methods of the nutrient solution, the shape of the bed for transplanting and cultivating the plant is a flat bed, and the growth port is made between about 10 Cm to 20 Cm intervals between the cultivation ports to grow a certain plant at regular intervals and grow about 20 Cm. Irradiating LED light to a height of 30Cm is a general LED plant cultivation system.

However, these planar beds have the following limitations.

Firstly, the planar bed uses only two-dimensional surfaces and has an inefficient problem in terms of use of space utilization that excludes three-dimensional space utilization.

Secondly, only the LED light directly irradiated onto the plant is utilized for plant growth, and the light irradiated onto the flat bed where the plant is not planted is reflected upwards, thereby making it difficult to utilize the light source.

Third, the LED light that is directly injected into the plant is irradiated only to the upper part of the plant, so that the leaves of the lower part and the side part are blocked by the upper leaf so that the light is not received. have.

Fourth, the planar bed has limitations in simultaneously growing plants of various sizes. The reason is that when the height of the LED light is adjusted up and down, the shorter plants are farther away from the LED lights, and the taller plants are too close to the LED lights. There is a problem that does not grow uniformly.

Fifthly, when manufacturing the LED plant cultivator in the form of showcase-type home appliances, the product produced in the form of a flat bed has a problem in that the interior effect is reduced to form a flat plane in terms of design.

The technical problem of the present invention is to provide an inclined bed hydroponic cultivation apparatus that can increase the space utilization of the conventional flat bed using the LED.

Another technical problem of the present invention is to provide an inclined bed-type hydroponic cultivation apparatus capable of cultivating different varieties of plants or the same varieties of different sizes in the same redistribution.

Another technical problem of the present invention is to provide an inclined bed-type hydroponic cultivation apparatus that can increase the cultivation efficiency by allowing light to be irradiated with a uniform light distribution to all the plants to be grown.

Slope type hydroponic apparatus of the present invention for achieving the above technical problem is the LED light emitting unit 10 for irradiating light downward; A port 20 disposed below the LED light emitting unit 10 and seating the seedlings 1; And a bed 30 in which a plurality of insertion holes 30d into which the port 20 is inserted are formed. It is formed to include, the bed 30 is at least a portion is bent to form a bent region (30c), the bent region (30c) is formed that the insertion hole (30d) is inserted into the port 20 It features.

In this case, the bed 30 includes a reflection plate 30a in which the bent region 30c and the insertion hole 30d are formed and reflect light; It may be formed to include.

In addition, the reflective plate 30a may be formed by coating any one material selected from gold, silver, aluminum, and stainless steel on one surface of the metal plate.

In addition, the bed 30 is formed with the bending region 30c and the insertion hole (30d), the support plate 30b is coupled to the lower portion of the reflecting plate (30a) for supporting the reflecting plate (30a); It may be formed to further include.

In this case, the bed 30 includes a first flat portion 31 whose shape is formed into a flat plate shape; A first inclined portion 32 extending from the first flat portion 31 at a predetermined angle; A lower plate portion 33 extending at a predetermined angle from the first inclined portion 32 and formed to be horizontal with the first flat portion 31; A second inclined portion 34 extending at a predetermined angle from the lower plate portion 33 and disposed to face the first inclined portion 32 with respect to the center of the lower plate portion 33; And a second flat plate portion 35 formed in a flat plate shape and extending from the second inclined portion 34. ≪ / RTI >

Here, the insertion hole 30d may be formed in each of the first flat plate part 31 and the second flat plate part 35. In addition, the insertion hole 30d may be formed in each of the first inclined portion 32, the lower plate portion 33, and the second inclined portion 34.

On the other hand, the angle between the first inclined portion 32 and the lower plate 33 is formed between 120 degrees and 150 degrees, the angle between the second inclined portion 34 and the lower plate 33 is 120 It may be formed between about 150 degrees.

On the other hand, the inclined bed hydroponic cultivation apparatus is disposed below the bed 30, the spray pipe 40 for spraying the nutrient solution; It may be formed to include a further, in this case, the bed 30 may be formed in a hydroponic type to be installed to float on the ground.

On the other hand, the inclined bed hydroponic cultivation apparatus is disposed in the bending area (30c), the light concentrator 50 for condensing light emitted from the LED light emitting unit 10 to the seedling (1); It may be formed to further include.

In this case, the light collecting bodies 50 may be formed in plural, and the light collecting bodies 50 may be formed at different angles so that light irradiation angles for condensing and reflecting light are different from each other.

The present invention can increase the production of seedlings per unit area and grow a variety of varieties by forming an insertion hole (30d) in the bending area (30c) in the bed 30, and irradiated downward from the LED light emitting unit 10 It is effective to promote the growth of seedlings by reflecting light having a strong straightness by the bending area 30c to enhance the amount of light irradiated to the leaves of seedlings that are hidden from each other.

In addition, the present invention by reflecting the light having a strong straightness irradiated downward from the LED light emitting unit 10 by the reflecting plate 30a together with the bent region 30c to enhance the amount of light to be irradiated to the leaves of the seedlings hidden between each other It has the effect of promoting the growth of seedlings.

In addition, the present invention by changing the position of the seedling port 20 is disposed around the bending area (30c) to receive a step by step the amount of light received from the LED light emitting unit 10, various varieties not limited to one variety It is possible to cultivate and change the amount of light received by the seedlings according to the maturity of the seedlings, there is an effect that can be continuously grown depending on the maturity and breeding of the seedlings.

1 is a perspective view of an inclined bed hydroponic cultivation apparatus according to an embodiment of the present invention.
2 is a cross-sectional view of the inclined bed hydroponic cultivation apparatus shown in FIG.
3 is a cross-sectional view according to a driving state of the inclined bed hydroponic cultivation apparatus shown in FIG.
4 is a partial cross-sectional view of the inclined bed hydroponic cultivation apparatus according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms or words used in this specification should not be construed as being limited to the common or dictionary meanings, and the inventors can properly define the concept of terms in order to explain their invention in the best possible way. It should be interpreted as meanings and concepts corresponding to the technical spirit of the present invention.

Hereinafter, the components constituting the inclined bed hydroponic apparatus according to an embodiment of the present invention, the coupling relationship between the components, and the role of the components will be described.

1 is a perspective view of an inclined bed hydroponic cultivation apparatus according to an embodiment of the present invention. 2 is a cross-sectional view of the inclined bed hydroponic cultivation apparatus shown in FIG.

As shown in Figure 1 and 2, the inclined bed hydroponic cultivation apparatus according to an embodiment of the present invention is formed including the LED light emitting unit 10, the port 20, and the bed 30, spraying It is formed further comprising a pipe (40).

The LED light emitting unit 10 irradiates light downward. In the present exemplary embodiment, the LED light emitting unit 10 may be formed in a bar type or a flat plate type in which a plurality of LEDs are arranged. However, the shape of the LED light emitting unit 10 is not limited in the present invention.

The port 20 is disposed below the LED light emitting unit 10 and seats the seedlings 1. The port 20 is formed in a cup shape with openings up and down, and a sponge is seated inside. In this case, the pot 20 can be developed by mounting the seedlings 1 on the sponge.

The bed 30 is formed with a plurality of insertion holes (30d), the port 20 is inserted into the insertion hole (30d) is seated.

In this case, at least a portion of the bed 30 is bent to form the bent region 30c. In this case, an insertion hole 30d into which the port 20 is inserted is formed in the bending region 30c. Here, the bending region 30c forms an insertion hole 30d through which the port 20 can be inserted, thereby improving productivity so as to increase the cultivation capacity of the seedling 1 per unit area than the flat plate shape. In addition, the curved area 30c reflects the light in the curved area when the light is irradiated downwardly from the LED light emitting unit 10, and the leaves of the seedlings 1 seated on the port 20 are covered with light. The light is reflected and supplied to the part not receiving.

Here, the bed 30 may be formed of one material, but in the present embodiment, the bed 30 is formed by including a reflecting plate 30a and a supporting plate 30b.

The reflecting plate 30a is formed with a bent region 30c and an insertion hole 30d and serves to reflect light. The reflector 30a serves to reflect the light emitted from the LED light emitting unit 10 so that light is supplied to the leaves of the seedling 1, which may be shaded, and the reflector 30a may have a curved area ( 30c) serves to further increase the amount of light supplied to the leaves of seedlings 1 by reflecting light with specular and diffuse reflection.

Here, the reflective plate 30a may be formed of a metal plate having a reflective function as described above, and the reflective plate 30a may be formed of any one material selected from gold, silver, aluminum, and stainless steel on one surface of the metal plate. It can be formed by coating. In this case, the metal plate is formed by coating only the upper surface of the reflective layer with the above-described material in a state in which the reflective plate 30a is structurally supported so that the reflective plate 30a is not deformed due to impact, and thus the structural strength is high. A reflecting plate 30a having a reflecting function can be formed.

The support plate 30b is coupled to the lower portion of the reflector plate 30a to support the reflector plate 30a. In this case, the support plate 30b may have a bent region 30c and an insertion hole 30d. . Here, the support plate 30b supports the reflecting plate 30a so that the reflecting plate 30a is not bent, and forms a sufficient space in which the insertion hole 30d is formed so that the position of the port 20 is not misaligned. ) Will be fixed in position. The support plate 30b may be formed of a resin material such as styrofoam or injection molding, and may be attached to the lower portion of the reflector plate 30a by bonding or the like.

In the present embodiment, the bed 30 formed by stacking the reflecting plate 30a and the supporting plate 30b has the first flat plate portion 31, the first inclined portion 32, and the lower plate to form the bent region 30c. The part 33, the 2nd inclination part 34, and the 2nd flat part 35 are provided.

The first flat plate portion 31 is formed in a flat plate shape, and an insertion hole 30d is formed.

The first inclined portion 32 extends at a predetermined angle from the first flat portion 31, an insertion hole 30d is formed, and an insertion hole 30d is formed.

The lower plate portion 33 extends at a predetermined angle from the first inclined portion 32, is formed to be horizontal to the first flat portion 31, and an insertion hole 30d is formed.

The second inclined portion 34 extends at a predetermined angle from the lower plate portion 33, and is disposed to face the first inclined portion 32 based on the center of the lower plate portion 33, and the insertion hole 30d. ) Is formed.

The second flat plate portion 35 is formed in a flat plate shape, extends from the second inclined portion 34, and an insertion hole 30d is formed.

Here, the first inclined portion 32, the lower plate portion 33, the second inclined portion 34 by forming a bent region (30c) inside to reflect the light irradiated downward from the LED light emitting portion 10, Light is irradiated to the leaves of seedlings 1 that are hidden from each other.

In this case, an insertion hole 30d is formed in each of the first flat plate portion 31, the first slope portion 32, the lower plate portion 33, the second slope portion 34, and the second flat plate portion 35. In this case, each of the insertion hole 30d is inserted into the port 20 so that the seedlings 1 can be placed. When the growth of the seedlings 1 starts, the port 20 emits LEDs. In the insertion hole 30d of the 1st flat part 31 and the 2nd flat part 35 which are closest to (10), and when the seedling 1 grows to some extent, the 1st inclined part 32 and The insertion hole 30d of the second inclined portion 34 is disposed, and finally, the port 20 of the mature seedling 1 may be moved to the insertion hole 30d of the lower plate portion 33. That is, the bed 30 can adjust the amount of light received from the LED light emitting unit 10 by moving the position of the port 20 according to the maturity of the seedling (1).

In addition, the bed 30 may adjust the amount of light received from the LED light emitting unit 10 by varying the arrangement position of the port 20 according to varieties of seedlings 1 having different sizes as described above.

In this case, the first inclined portion 32, the lower plate portion 33, and the second inclined portion 34 form the bent area 30c to adjust the degree of reflection and at the same time according to the maturity of the seedling 1. The first inclined portion 32 and the lower plate portion 33 are formed so that the port 20 is fixed without moving while the port 20 is moved and the space utilization can be increased to maximize the number of crops. The angle is formed between 120 degrees and 150 degrees, and the angle formed by the second inclined portion 34 and the lower plate portion 33 is preferably formed between 120 degrees and 150 degrees. That is, the first inclined portion 32 is formed between 30 degrees and 60 degrees with respect to the horizontal line, and the second inclined portion 34 is formed between 30 degrees and 60 degrees with respect to the horizontal line, among which the optimum angle is 45 degrees. It is preferable. Outside the angular range, the reflected light reflected through the reflector 30a to be described later does not evenly reach the leaves of the crop on the lower plate 33, so that plant growth is not maximized.

On the other hand, the bed 30 is formed to extend at a predetermined angle from the second flat plate portion 35 and is formed extending from the third inclined portion 36, the third inclined portion 36 is horizontal to the lower plate portion 33 A fourth inclined portion extending from the second lower plate portion 37 and the second lower plate portion 37 so as to face the first inclined portion 32 with respect to the center of the second lower plate portion 37. The portion 38 and a third flat portion 39 extending from the fourth inclined portion 38 and horizontally formed with the second flat portion 35 may be formed.

In this case, the third inclined portion 36, the second lower plate portion 37, the fourth inclined portion 38, and the third flat portion 39 are formed of the first flat portion 31 and the first inclined portion 32. ), The lower plate portion 33, the second inclined portion 34, and the second flat plate portion 35 form a bent region 30c inside, and an insertion hole 30d is formed on one surface of each flat plate. Can be formed. That is, the bed 30 of the present embodiment is formed in a 'W' shape in which two bent regions 30c are formed. However, the shape of the bed 30 is not limited to the 'W' shape shown in the drawing may extend to form more curved regions 30c, or may form one curved region 30c. .

The spray pipe 40 is disposed below the bed 30 and sprays the nutrient solution. The spray pipe 40 sprays a fine nutrient solution near the root of the seedling 1 seated on the pot 20, thereby promoting the growth of the seedling 1.

In this case, the bed 30 is a hydroponic type that is suspended from the ground by the installation or suspended in the air. Hydroponic type cultivation method is fine spraying the nutrient solution near the root of the seedlings (1), the seedlings (1) have high growth efficiency, water use is low, the nutrient solution tank capacity can be reduced, the roots of the seedlings (1) Because it is exposed to the air, the amount of oxygen supplied to the roots is high, temperature control and disinfection of nutrient solution are easy, and it is possible to grow several kinds of crops at the same time, and has a high planting density to grow many crops in a small area, and to clean and manage There is an advantage of easy cleaning.

Next, a cultivation method using an inclined bed hydroponic cultivation apparatus according to an embodiment of the present invention will be described.

As shown in FIG. 3, a cultivation method using an inclined bed hydroponic cultivation apparatus according to an embodiment of the present invention first includes an insertion hole 30d of each bed 30 in which a plurality of insertion holes 30d are formed. After seating the port 20, the LED light emitting unit 10 installed above the port 20 is driven to irradiate light downward. At this time, the spray pipe 40 is installed in the lower portion of the bed 30 to finely spray the nutrient solution to supply the nutrient solution in the form of bubbles near the root of the seedling (1).

Here, the bed 30 is the first flat portion 31, the first slope portion 32, the lower plate portion 33, the second slope portion 34, the second plate portion 35, the third slope portion ( 36, the second lower plate portion 37, the fourth inclined portion 38, and the third flat plate portion 39 form two bent regions 30c, based on one bent region 30c. In this regard, the insertion hole 30d of each of the first flat plate portion 31, the first slope portion 32, the lower plate portion 33, the second slope portion 34, and the second flat plate portion 35 is provided. In each of them a port 20 is seated.

In this case, the bent region 30c formed by the first flat plate portion 31, the first slope portion 32, the lower plate portion 33, the second slope portion 34, and the second flat plate portion 35. Is formed by the inclined surfaces and the reflective surface that can reflect the strong light emitted from the LED light emitting unit 10 so that even if the leaves of the seedlings (1) are covered with each other so that the seedlings (1) Will improve the growth rate.

In addition, the bed 30 forming the bent area 30c forms an inclined surface to arrange the ports 20, thereby increasing the cultivation area per unit area in the flat form than the conventional cultivation plate, and thus 30% to 40%. It will be possible to increase the amount of cultivation.

In addition, the bed 30 is further formed with a reflecting plate 30a to improve the reflectance of the light, thereby further increasing the amount of light supplied to the seedling 1 to further improve the growth rate of the seedling 1.

Meanwhile, the seedlings 1 planted in the ports 20 of the first flat portion 31 and the second flat portion 35 arrange the ports 20 of the young seedlings 1 in the state where the embryo is just starting. The first inclined part 32 and the second inclined part 34 may be arranged with a pot 20 of the seedling 1 grown to some extent, and the mature plated part 1 may be disposed in the lower plate part 33. have.

That is, the cultivation efficiency can be increased by moving the position of the port 20 to receive different amounts of light depending on the growth state of the seedlings 1.

In addition, since the position of the pot 20 of the seedling 1 is adjusted to adjust the amount of light received by the seedling 1, the pot of the seedling 1 to be adapted to each variety at the time of cultivation of various varieties having different sizes ( 20) By appropriately placing the position around the bending area 30c, it is possible to grow leafy vegetables of various varieties without being limited to one variety.

Meanwhile, referring to FIG. 4, FIG. 4 illustrates an inclined bed hydroponic cultivation apparatus according to another embodiment of the present invention.

The inclined bed hydroponic cultivation apparatus shown in FIG. 4 further includes a light collecting member 50, including an LED light emitting unit 10, a port 20, a bed 30, and a spray pipe 40. Can be.

Here, the LED light emitting unit 10, the port 20, the bed 30, and the spray pipe 40 performs the same or similar functions as the above-described embodiment will not be redundant description, in this embodiment The condenser 50 will be mainly described.

The light concentrator 50 is disposed in the bending region 30c and condenses the light emitted from the LED light emitting unit 10 into the seedling 1. Here, the light collector 50 may be further formed with the above-described reflector (not shown). The light collector 50 is coupled to one surface of the bed 30, and is formed with an arc-shaped or elliptical curved surface to collect light emitted from the LED light emitting unit 10. Here, the light focused on the light collector 50 is concentrated and irradiated on the leaves of the seedling 1, thereby increasing the photosynthetic efficiency of the seedling 1 to further promote the growth of the seedling 1.

In this case, the light concentrator 50 is composed of a plurality of light concentrators, and the light concentrators 50 are arranged at different reflecting angles so that the light irradiation angle for condensing and reflecting light is evenly distributed across the leaves of all the seedlings. Can be formed. The light concentrators 50 arranged at different angles can adjust the amount of light received by the seedlings 1 by adjusting the arrangement angle so as to focus the reflected light evenly according to the size and variety of the seedlings 1 and the positions of all leaves. By doing so, it is possible to grow a variety of seedlings (1) regardless of the size and variety of seedlings (1).

The embodiments of the present invention described above may be modified in many different forms, and the claims of the present invention are not limited to the above-described embodiments.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

One ; Seedlings
10; LED light emitting part
20; port
30; Bed
40; Spray pipe

Claims (11)

delete delete delete delete LED light emitting unit 10 for irradiating light downward;
A port 20 disposed below the LED light emitting unit 10 and seating the seedlings 1; And
A bed 30 in which a plurality of insertion holes 30d into which the port 20 is inserted are formed; It is formed to include,
At least a portion of the bed 30 is bent to form a bending area 30c, and the insertion area 30d into which the port 20 is inserted is formed in the bending area 30c.
The bed 30
A first flat plate portion 31 formed in a flat plate shape;
A first inclined portion 32 extending from the first flat portion 31 at a predetermined angle;
A lower plate portion 33 extending at a predetermined angle from the first inclined portion 32 and formed to be horizontal with the first flat portion 31;
A second inclined portion 34 extending at a predetermined angle from the lower plate portion 33 and disposed to face the first inclined portion 32 with respect to the center of the lower plate portion 33; And
A second flat plate portion 35 formed in a flat plate shape and extending from the second inclined portion 34; Sloped bed hydroponic cultivation device, characterized in that consisting of.
The method of claim 5,
Inclined bed hydroponic cultivation device, characterized in that the insertion hole (30d) is formed in each of the first flat plate (31) and the second flat plate (35).
The method of claim 5,
Inclined bed hydroponic cultivation device, characterized in that the insertion hole (30d) is formed in each of the first inclined portion (32), the lower plate portion (33) and the second inclined portion (34).
The method of claim 5,
The angle between the first inclined portion 32 and the lower plate portion 33 is formed between 120 degrees and 150 degrees,
Sloped bed hydroponic cultivation apparatus, characterized in that the angle formed by the second inclined portion 34 and the lower plate portion 33 is formed between 120 degrees to 150 degrees.
delete 9. The method according to any one of claims 5 to 8,
A condenser 50 disposed in the bend region 30c and condensing the light emitted from the LED light emitting unit 10 to the seedling 1; Sloped bed hydroponic cultivation apparatus characterized in that it is formed further comprising.
The method of claim 10,
The condenser 50 is composed of a plurality of inclined bed, characterized in that the plurality of condenser 50 is disposed at different angles so that the light irradiation angle for reflecting the light after condensing is formed different from each other Hydroponic cultivation device.

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