KR102186207B1 - Hydroponics apparatus - Google Patents

Abstract

Hydroponic cultivation apparatus according to an embodiment of the present invention, a support including an upper support having a mounting hole, spaced apart from the upper support, a gutter having an insertion groove, installed on the upper end of the upper support, and supplying a nutrient solution A nutrient solution supply unit having a supply nozzle, a cartridge unit having one end inserted into the insertion groove and the other end mounted in the mounting hole, and a lighting device spaced apart from the support unit and irradiating light toward the cartridge unit.

Description

Hydroponic cultivation device{HYDROPONICS APPARATUS}

The present invention relates to a hydroponic cultivation apparatus.

Hydroponic cultivation is not a method of receiving water and nutrients necessary for the growth of crops from the soil, but is one of the plant cultivation methods in which nutrients are supplied from a nutrient solution dissolved in an appropriate ratio.

Hydroponic cultivation can protect plants from various diseases and pests by supplying nutrient solutions diluted with various growth promoters and nutrients, and artificially promotes the growth rate of plants to obtain large yields within a short period of time without using pesticides harmful to the human body It has an advantage and is now widely used.

Due to these advantages, hydroponic cultivation has been attempted even in cities with a large population but a narrow cropland. Agricultural crops harvested through hydroponics in cities can be supplied to consumers at low prices through a short supply path between suppliers and consumers, each based in the city.

In the case of conventional hydroponic cultivation methods, place a lid on a bucket containing nutrient solution, place a plant pot on it, and then hang a string of cloth material from the soil into the nutrient solution in the bucket, and the nutrient solution slowly climbs the string and rises to the root. Systems designed to be supplied continuously have been widely used.

However, such a conventional hydroponic cultivation method has been implemented through the multi-stage hydroponic cultivation apparatus of Patent Publication No. 10-1009461. However, this hydroponic cultivation method is not suitable for large-scale hydroponic cultivation because it is not suitable for cultivation of plants that consume nutrient solution and water because the amount of nutrient solution and water is very high, so it can be used only for small plants or seedlings. Or, since the capacity of the pump used for circulation increases, there is a problem that a lot of equipment and maintenance costs are consumed. In addition, in the case of the conventional horizontal hydroponic cultivation method, due to the nature of the facility, water is accumulated, so if a filtration device is not properly installed or there is no management, the cleanliness is deteriorated, and a large installation space is required to install a horizontal facility. There was a problem that it was not easy to move. Furthermore, since the culture table is stacked to make the most of a small area, the cultivated plants in the lower layer cannot grow uniformly because the sunlight is covered by the upper culture table.

In addition, in the case of the conventional horizontal hydroponic cultivation method, despite the high investment cost and management cost, it was very difficult to have price competitiveness due to the same yield as in general agriculture. Was used. However, in order to harvest high steps, separate devices such as ladders, movable stairs, and cranes had to be installed, which incurs additional costs, and also significantly increases the risk of injury such as falls during work, which reduces production speed. there was.

An embodiment of the present invention is to provide a hydroponic cultivation apparatus capable of effectively delivering nutrient solution to the roots of plants even with a small amount of water and increasing economic efficiency and production efficiency.

According to an aspect of the present invention, a support portion including an upper support having a mounting hole, a gutter spaced apart from the upper support, an insertion groove formed, and a nutrient solution having a supply nozzle installed on the upper end of the upper support and supplying the nutrient solution It provides a hydroponic cultivation apparatus including a supply unit, a cartridge unit having one end inserted into the insertion groove, and a cartridge unit having the other end mounted in the mounting hole and spaced apart from the support unit, and irradiating light toward the cartridge unit.

The lighting device may include a pair of lighting supports spaced apart from the support and coupled to each of the lighting supports, irradiating the light toward the cartridge, and including a plurality of lighting members corresponding to the position of the slit. have.

A plurality of folding frames are intersected and connected between the lighting supports, and the crossing angle is set according to the separation distance of the lighting supports.

The lighting member may include at least one of a fluorescent lamp and an LED.

The cartridge part has an installation space part into which the nutrient solution moving part is inserted, a body having a slit connecting the outside and the inside formed therein, and a plant fixture that is fitted and fixed to the inside of the nutrient solution moving part and absorbs the nutrient solution It may include.

Hydroponic cultivation apparatus according to an embodiment of the present invention can prevent deficiency due to carelessness by providing sufficient nutrient solution and water to plants that consume a lot of nutrient solution and water by continuously providing nutrient solution, and large-scale hydroponic cultivation facility It can also be used.

The hydroponic cultivation apparatus according to an embodiment of the present invention may filter impurities contained in the nutrient solution through the porous nutrient solution moving part, while adsorbing organic compounds contained in the nutrient solution.

The hydroponic cultivation apparatus according to an embodiment of the present invention is cultivated in a porous nutrient solution moving part having a high oxygen permeability, so that sufficient oxygen is supplied to the roots of plants, it is possible to prevent root rot and maintain an optimum temperature.

The hydroponic cultivation apparatus according to an embodiment of the present invention can effectively deliver the nutrient solution and water to the roots of the plant even if a small amount of nutrient solution or water is supplied by absorbing nutrient solution or water by the plant fixture having high hydrophilicity.

1 is a perspective view showing a hydroponic cultivation apparatus according to an embodiment of the present invention.
2 is a side cross-sectional view of a hydroponic cultivation apparatus according to an embodiment of the present invention.
3 is a perspective view showing a cartridge unit according to an embodiment of the present invention.
4 is a perspective view showing a first embodiment of a gutter according to an embodiment of the present invention.
5 is a cross-sectional view of a cartridge unit according to an embodiment of the present invention.
6 is a cross-sectional view showing a nutrient solution moving part according to an embodiment of the present invention.
7 is a cross-sectional view showing a state in which plants of the cartridge unit are grown according to an embodiment of the present invention.
8 is a perspective view showing a lighting device according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art can easily implement the present invention. The present invention may be implemented in various different forms and is not limited to the embodiments described herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and the same reference numerals are assigned to the same or similar components throughout the specification.

In the present specification, terms such as "comprise" or "have" are intended to designate the presence of features, numbers, steps, actions, components, parts, or combinations thereof described in the specification, but one or more other features. It is to be understood that the possibility of addition or presence of elements or numbers, steps, actions, components, parts, or combinations thereof is not preliminarily excluded. In addition, when a part such as a layer, film, region, plate, etc. is said to be "on" another part, this includes not only the case where the other part is "directly above", but also the case where there is another part in the middle. Conversely, when a part such as a layer, film, region, plate, etc. is said to be "below" another part, this includes not only the case where the other part is "directly below", but also the case where there is another part in the middle.

1 is a perspective view showing a hydroponic cultivation apparatus according to an embodiment of the present invention, FIG. 2 is a side cross-sectional view of a hydroponic cultivation apparatus according to an embodiment of the present invention, and FIG. 3 is A perspective view showing a cartridge part, and FIG. 4 is a perspective view showing a first embodiment of a gutter according to an embodiment of the present invention.

In describing the hydroponic cultivation apparatus according to an embodiment of the present invention, as shown in FIG. 1, the nutrient solution supply unit 150 side is defined upward in the gutter (130), and the nutrient solution supply unit 150 Explain by defining the gutter (130) side downward.

1 to 3, the hydroponic cultivation apparatus 100 according to an embodiment of the present invention includes a support part 110, a gutter 130, a nutrient solution supply part 150, a cartridge part 170, and a blower 190. ) Can be included.

The support part 110 has a rectangular frame shape elongated upward and may include a lower support 111, an upper support 117, and a connection support 115.

The lower support 111 may be formed in a plate shape so that a gutter 130 can be seated at the lower end of the support 110. A flange 111a bent upward may be formed on the front side and the rear side of the lower support 111 in order to stably accommodate the gutter 130. Wheels 113 may be connected to the lower surface of the lower support 111. Accordingly, the support 110 can be moved more easily.

The upper support 117 may be formed in a plate shape on the upper end of the support part 110. The upper support 117 may have a plurality of mounting holes 117a spaced apart from each other at a predetermined interval to mount the cartridge unit 170. For example, the mounting holes 117a may be formed in two rows along the length direction of the upper support 117.

The connection support 115 has a bar shape and may be connected to both sides of the upper support 117 and the lower support 111 in a vertical direction, respectively.

The gutter (130) may be seated on the upper surface of the lower support (111). The gutter 130 may be formed in a rectangular shape, and a plurality of insertion grooves 130a may be formed along the length direction. For example, the insertion groove (130a) may be recessed from the surface of the gutter (Gutter, 130) toward the inside of the gutter (Gutter, 130). The cartridge unit 170 may be inserted and fixed in the insertion groove 130a. In addition, the nutrient solution dropped from the cartridge unit 170 can be accommodated in the gutter 130, so that the injected nutrient solution can be recovered.

A discharge hole 130b capable of discharging the nutrient solution accommodated in the insertion groove 130a may be located inside the gutter 130, which is connected to the lower surface of the insertion groove 130a. For example, the nutrient solution may flow downward along the cartridge part, pass through the insertion groove 130a, and be accommodated in the gutter 130. The received nutrient solution may be discharged to the outside along the discharge hole 130b formed under the gutter 130.

A transfer hose (not shown) for transferring the nutrient solution contained in the gutter 130 may be connected to the discharge hole 130b, and the nutrient solution contained in the gutter 130 may be circulated inside the gutter 130. A pump (not shown) may be installed. For example, when the pump (not shown) is operated, the nutrient solution accommodated in the gutter 130 may be transferred along a transfer hose (not shown) to be resupplied to the nutrient solution supply unit 150.

Gutter (Gutter, 130) may be arranged in two rows in front and rear of the lower support (111). For example, the gutter (Gutter) 130 may be positioned to protrude from the end of the upper support 117 is spaced apart from the connection support. That is, the center of the insertion groove (130a) formed in the gutter 130 from the center of the mounting hole (117a) formed in the upper support 117 may be different in position. Through this, the cartridge unit 170 may be mounted with its upper end inclined toward the center of the upper support 117 by its own weight.

As another example, referring to FIG. 4, the insertion groove 130a of the gutter 130 may have an inclined surface 130c so that the cartridge unit 170 to be inserted may be disposed in an inclined manner. The inclined surface 130c may be formed in the insertion groove 130a. For example, the inclined surface 130c may be formed in a direction toward the center of the lower support 111 within the insertion groove 130a. The inclined surface 130c may be formed to be inclined from the upper surface of the gutter 130 toward the lower surface of the insertion groove 130a. Through this, the cartridge unit 170 may be supported more stably inclined.

The nutrient solution supply unit 150 may be installed by being connected to the upper end of the support unit 110. The nutrient solution supply unit 150 may be located above the upper support 117. The nutrient solution supply unit 150 includes a plurality of supply nozzles 151 spaced at predetermined intervals in the longitudinal direction, and the nutrient solution supplied to the nutrient solution supply unit 150 may flow out by the supply nozzle 151 and fall downward.

Under the nutrient solution supply unit 150, the cartridge unit 170 mounted on the upper support 117 is positioned, and the nutrient solution falls into the inside of the cartridge unit 170, thereby supplying the nutrient solution to the plants of the cartridge unit 170. have. Accordingly, the hydroponic cultivation apparatus can prevent deficiency due to carelessness by providing sufficient nutrient solution and water to plants by continuously providing nutrient solution, and can be used in large-scale hydroponic cultivation facilities.

In addition, the hydroponic cultivation device is easy to install and can be moved easily compared to the conventional stacked and horizontal hydroponic cultivation devices, so it can be used in various indoor environments such as offices, apartment verandas, and indoors of ordinary homes.

The cartridge part 170 may have an installation space part 171a formed therein, and a slit 171b may be formed on one surface thereof. For example, the cartridge unit 170 may have a shape such as a pipe extending in the vertical direction as a whole. The slit 171b of the cartridge part may be formed in parallel along the length direction of the cartridge part 170. As another example, the slit 171b may be formed along the length direction of the cartridge unit 170 and may be curved. The slit 171b may be cut to about 10 to 20 mm. Accordingly, the slit 171b can minimize the exposure of the installation space part 171a to light. In addition, unlike the slit in the horizontal direction, the slit 171b formed in the vertical direction can minimize the escaping of the nutrient solution to the outside through the slit even if the nutrient solution is excessively supplied.

The cartridge unit 170 is inserted in the lower end into the insertion groove (130a) of the gutter (Gutter, 130) and the upper end is mounted in the mounting hole (117a) of the upper support (117), to be installed in the vertical direction on the support (110). I can. Accordingly, compared with the conventional horizontal hydroponic cultivation method, air circulation is smooth, so that the occurrence of diseases such as mold can be minimized, and heat dissipation is easy. In addition, the plants cultivated in the cartridge unit 170 are arranged in the vertical direction, so that the management and cultivation of the plants may be facilitated.

The cartridge unit 170 is located below the supply nozzle 151 of the nutrient solution supply unit 150, and the nutrient solution flowing out of the supply nozzle 151 and falling down may be supplied to the cartridge unit 170.

The blower 190 may be installed on one side of the support unit to dissipate heat from the cartridge unit 170. For example, the blower 190 is connected to one surface of the lower support 111 and may be operated to circulate air and heat between the cartridge units 170 located on both sides.

Figure 5 is a cross-sectional view showing a cartridge unit according to an embodiment of the present invention, Figure 6 is a cross-sectional view showing a nutrient solution moving unit according to an embodiment of the present invention, Figure 7 is a cartridge according to an embodiment of the present invention It is a cross-sectional view showing a state in which negative plants are grown.

5 to 7, in an embodiment of the present invention, the cartridge unit 170 may include a body 171, a nutrient solution moving unit 173, and a plant fixture 180.

The body 171 has a bar shape that extends in the vertical direction, and an installation space part 171a is formed on the inside, and a slit 171b that is cut in the longitudinal direction of the body 171 on one side is formed to connect the outside and the inside. Can be. For example, the body 171 may be a pipe made of PCV material.

The nutrient solution moving part 173 may be inserted and positioned in the installation space part 171a. The nutrient solution moving part 173 may have a cut-out surface 175 and a connection surface 175a. For example, a cut surface is formed in the longitudinal direction of the nutrient solution moving part 173, and the connection surface 175a may be formed at an end of the nutrient solution moving part. The cut-off surface may be formed in the center of the nutrient solution moving part 173. The cut-off surface 175 may be formed from one surface of the nutrient solution moving part 173 to the connection surface 175a toward the inside of the nutrient solution moving part. Accordingly, the nutrient solution moving part 173 has a cut surface 175 therein, but the nutrient solution moving part 173 divided by the cut surface 175 is connected.

A plant fixture 180 for absorbing nutrient solution and moisture may be inserted and fixed to the cut surface 175 of the nutrient solution moving part 173. For example, the plant fixture 180 may be formed along the longitudinal direction of the nutrient solution moving part 173. That is, it is formed in a rectangular shape, and may be in full contact with the cut-out surface of the nutrient solution moving part 173. Accordingly, it can be more stably seated inside the nutrient solution moving part 173. The plant seed (S) may be fixed to the inside of the rock wool (181). The rock wool 181 is attached to one side of the plant fixture 180 and is stably fixed to be inserted and fixed into the porous nutrient solution moving part 173.

The nutrient solution moving part 173 may be a porous material of 10 ppi (Pore per inch). For example, the nutrient solution moving part 173 may be a Nonwoven Fiber Substrate. The nutrient solution moving part 173 may minimize the propagation of green algae due to light by using a black material.

The nutrient solution moving part 173 may be coated with a coating material. For example, the coating material may coat the sidewalls of the pores 177a serving as water channels. The coating layer 177 is formed inside and outside the pores coated by the coating material, and the pores 177a by the coating layer 177 may function as a channel through which nutrient solutions and water pass. The coating layer 177 may prevent impurities such as dead leaves and dust that may be included in the nutrient solution and toxicity that may be included in the nonwoven fiber material from penetrating toward the plant P fixed to the nutrient solution moving part 173. The coating material may be silica (Si). As another example, the nutrient solution moving part 173 may be entirely coated with a coating material. Accordingly, the strength of the nutrient solution moving part 173 is increased, so that it is possible to withstand plant fixation and plant weight.

The plant fixture 180 may be made of at least one of paper, nonwoven fabric, and synthetic resin. The plant stationary body 180 has high hydrophilicity and can effectively absorb nutrient solution and moisture provided from the supply nozzle 151.

A rock wool 181 may be attached to one side of the plant fixture 180. The rock wool 181 may include a fibrous material composed of raw materials such as basalt, andesite, serpentine, and gwangje. For example, the rock wool 181 may have a block shape in which a space is formed by being recessed from one side toward the inside. Accordingly, the rock wool 181 may be fixed by inserting a seed (S) inside. The rock wool 181 has high hygroscopicity and can absorb nutrient solutions and moisture, and seeds (S) and roots (R) of plants can be fixed. Accordingly, the absorbed nutrient solution and moisture can be provided to the seed (S) of the plant, and the seed (S) of the plant that has been supplied with nutrients is germinated and the plant is grown, and as the plant grows, the root on the nutrient solution moving part 173 (R) can survive.

The root (R) of the plant (P) can be grown in the opposite direction of the plant fixture 180 by the plant fixture 180 that is fitted and fixed to the cut surface 175 of the nutrient solution moving part 173. That is, the root (R) of the plant (P) can be guided in one direction of the nutrient solution moving part (173). After the root (R) of the plant (P) is grown for a certain period of time, the plant fixture 180 may be removed.

8 is a perspective view showing a lighting device according to an embodiment of the present invention.

The hydroponic cultivation apparatus according to an embodiment of the present invention may further include a lighting device that is spaced apart from the support and irradiates light toward the cartridge.

Referring to FIG. 8, the lighting device 200 may include a lighting support 210, a folding frame 230, and a lighting member 250. A pair of lighting supports 210 are installed spaced apart from each other, and a folding frame 230 is mounted between each of the lighting supports 210 so that the distance between the lighting supports 210 can be adjusted by the folding frame 230. .

The lighting support 210 has a rectangular frame shape, and the rails 211 are formed in the vertical direction on the inner surface, so that both ends of the folding frame 230 can move along the rail 211.

The folding frame 230 is formed at both ends of the fixing member 233 and each adjustment member 231 mounted at the intersection of the pair of adjustment members 231 and the adjustment member 231, the rail of the lighting support 210 It may include a moving member (not shown) fitted to the (211).

The adjustment member 231 is in a bar shape, and the pair of adjustment members 231 crosses in an X-shape, and in a state in which the pair of adjustment members 231 are fastened through the fixing member 233 mounted at the intersection. Folding can be done. At this time, a moving member (not shown) mounted on both ends of each adjusting member 231 is rotatably mounted on the rail 211 of the lighting support 210, so that when the adjusting member 231 is folded, a moving member (not shown) City) can also move along the rail 211.

On the other hand, the lighting support 210 is formed by extending the lighting member 250 for emitting light in the vertical direction, the lighting member 250 may be installed a plurality of spaced apart a predetermined distance. A plurality of lights 251 that emit light may be installed on one surface of the lighting member 250 at a predetermined distance apart in the longitudinal direction. The lighting 251 includes at least one of a fluorescent lamp and an LED, and has a wavelength band that promotes plant growth. In addition, the illumination 251 emits light toward the outside of the illumination support 210, and the emitted light is supplied to the cartridge unit 170 of the hydroponic cultivation apparatus 100 to help plant growth.

That is, both sides of the pair of lighting support 210 may be provided with a pair of adjustment members 231, respectively, and when the adjustment member 231 is folded, each of the lighting support 210 and the lighting support 210 As the distance between) gets closer or farther away, you can adjust the intensity of the light irradiated toward the plant.

Hydroponic cultivation apparatus 100 according to an embodiment includes a hydroponic cultivation apparatus 100 and a lighting apparatus 200, the hydroponic cultivation apparatus 100 and the lighting apparatus 200 are installed in a plurality of spaced apart, hydroponic cultivation apparatus The slit 171b of 100 and the lighting member 250 of the lighting device 200 may be disposed to face each other. Accordingly, the light emitted from the lighting member 250 of the lighting device is supplied to the cartridge unit 170 of the hydroponic cultivation device to help plant growth.

Although an embodiment of the present invention has been described above, the spirit of the present invention is not limited to the embodiment presented in the present specification, and those skilled in the art who understand the spirit of the present invention can add components within the scope of the same idea. It will be possible to easily propose other embodiments by changing, deleting, adding, etc., but it will be said that this is also within the scope of the present invention.

100: hydroponic cultivation device 110: support
111: lower support 111a: flange
113: wheel 115: connection support
117: upper support 117a: mounting hole
130: gutter 130a: insertion groove
130b: discharge hole 130c: slope
150: nutrient solution supply unit 151: supply nozzle
170: cartridge part 171: body
171a: installation space part 171b: slit
173: nutrient solution moving part 175: cut surface
175a: connecting surface 177: coating layer
177a: pore 180: plant immobilization
181: rock wool 190: blower
200: lighting device 210: lighting support
211: rail 230: folding frame
231: adjustment member 233: fixing member
250: lighting member 251: lighting
P: Plant S: Seed
R: root

Claims (5)

A plate-shaped upper support extending in a long horizontal direction, a plurality of mounting holes formed through the upper support and spaced apart at predetermined intervals along the longitudinal direction of the upper support, and located below the upper support Thus, a support portion including a plate-shaped lower support extending in parallel with the upper support, and a connection support extending in a vertical direction to connect the upper support and the lower support;
A gutter seated on the lower support and extending in a lengthwise direction of the lower support, and having a plurality of insertion grooves spaced apart from each other at predetermined intervals along the longitudinal direction of the lower support to correspond to each of the mounting holes;
A nutrient solution supply unit installed on the upper end of the upper support and having a supply nozzle for supplying the nutrient solution;
A plurality of cartridge portions having a lower end inserted into the insertion groove, an upper end inserted into the mounting hole corresponding to the insertion groove, and each having a slit formed on one side thereof to communicate the inside with the outside; And
Includes; a lighting device that is spaced apart from the support and irradiates light toward the plurality of cartridge parts,
The cartridge part is provided with a nutrient solution moving part inserted through the slit and having a cut-off surface formed therein so that a plant can be seated therein, and a plant fixture provided on the cut-off surface and absorbing nutrient solution and moisture to supply to the plant,
The lower support is provided with a pair of flanges formed by bending upward from both sides connecting both ends to prevent separation of the gutter,
The insertion groove is further spaced apart from the connection support than the mounting hole corresponding to the insertion groove so that the cartridge part is inclined downward in a direction away from the connection support,
The nutrient solution moving part is made of a porous material having pores through which nutrient solution and moisture move,
The pores are coated on the inner wall to prevent toxicity contained in the porous material from penetrating into the plant,
The lighting device,
A pair of lighting supports each formed in a rectangular shape and provided with rails formed in the vertical direction on the inner surface;
A pair of adjustment members moving along the rail and the pair of adjustment members are rotated so that the mutual separation distance of the pair of lighting supports is adjusted according to the crossing angle. A folding frame including a fixing member for possible cross-connection; And
Includes; a lighting member coupled to each of the pair of lighting support so as to irradiate the light outwardly from the pair of lighting support,
The folding frame is a hydroponic cultivation apparatus provided on both sides of the pair of lighting supports to form a pair. delete delete The method of claim 1,
The lighting member,
Hydroponic cultivation apparatus comprising at least one of a fluorescent lamp and LED.
delete

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