KR20190129639A - Plant growing apparatus - Google Patents

Abstract

The present invention relates to a plant growth apparatus capable of cultivating a large number of plants in a limited space and area with a relatively simple configuration. The plant growth apparatus comprises: a first unit for absorbing water; and a second unit supporting the first unit, wherein a plant to be grown in the first unit where the water is absorbed is removably planted.

Description

Plant growth apparatus {PLANT GROWING APPARATUS}

The present invention relates to a plant growth apparatus, and more particularly, to a plant growth apparatus capable of cultivating a large number of plants in a limited space and area in a relatively simple configuration.

Irrespective of temperature and rainfall, harvesting has long been a dream for farmers, and this dream has been realized in part thanks to glass and vinyl greenhouses.

The future of agriculture will be closer to manufacturing due to dramatic changes, and the main cause of this change will be plant factories that produce crops like overcoming constraints such as sunlight, water, soil, and manpower.

Plant factories that combine IT with agriculture are also called smart farms.

Such plant factories can be divided into 'partial control', which partially automates sowing, water supply, and heating in existing greenhouses that use sunlight, and 'full control', where all the elements are automated instead of LEDs (light emitting diodes). have.

In view of the above, there may be mentioned, for example, "Independent plant factory using an internal combustion engine" (hereinafter, referred to in the prior art) of Patent No. 10-1509672.

The prior art can independently maintain and operate electricity by using the power of an internal combustion engine to independently maintain and operate the electricity, and stably supply light energy necessary for photosynthesis of plants through an artificial light source through a stable supply of electricity. By purifying the exhaust gas of the plant to the plant factory, it can supply carbon dioxide necessary for plant growth without being harmful, and it can be used to maintain the temperature inside the plant factory by recovering heat from the exhaust gas of the internal combustion engine. .

However, in the prior art, the use of fossil fuel is inevitable in that it uses an internal combustion engine, and there has been a problem in that an auxiliary facility such as a purification device for exhaust gas according to the operation of the internal combustion engine must be provided.

In particular, the prior art is focused on the operation of the internal combustion engine for the power supply of the artificial light source required for plant growth inside the plant factory and the purification of the exhaust gas, so that the plant as much as the space occupied by the internal combustion engine and the exhaust gas purification device described above. There was a problem that their production area is reduced.

Patent Registration No. 10-1509672

The present invention has been invented to improve the above problems, and to provide a plant growth apparatus capable of cultivating a large number of plants in a limited space and area in a relatively simple configuration.

In order to achieve the above object, the present invention comprises a first unit for absorbing water; And a second unit supporting the first unit, wherein the plant to be grown is detachably planted in the first unit in which water is absorbed.

Here, the first unit, has a predetermined length so that the plant is detachably planted, and includes a growth rope for absorbing water supplied from one direction or both directions, one end or both ends of the growth rope is the second unit It is characterized in that it is mounted on.

In this case, the first unit has a predetermined length so that the plant is detachably planted, a growth rope for absorbing water supplied from one direction or both directions, and the second unit is formed at one end or both ends of the growth rope. It characterized in that it comprises a fixed knot to be mounted on.

In addition, the second unit is characterized in that it comprises a water supply frame is fixed to the end of the first unit, and forms a space for receiving water therein.

The second unit may include a first water supply frame defining a space in which water is received, and a second water disposed in parallel with the first water supply frame and forming a space in which water is received. And a supply frame, and both ends of the first unit are fixed to communicate with internal spaces of the first water supply frame and the second water supply frame, respectively.

In addition, the plurality of second units may be stacked in a multi-stage stack up or down, or may be arranged in parallel from side to side, and the first unit may be coupled to the plurality of second units, respectively, and disposed in parallel.

The second unit may include a first water supply frame defining a space in which water is received, and a second water disposed in parallel with the first water supply frame and forming a space in which water is received. And a supply frame, and both ends of the first unit are fixed to communicate with internal spaces of the first water supply frame and the second water supply frame, respectively.

And blue light having a wavelength of 400 nm to 500 nm disposed on the outermost upper or lowermost second unit of the plurality of second units, or disposed on the outer side of the second unit of the left or right end, toward the plurality of first units. And a light emitting unit including at least one semiconductor optical device for emitting red light having a wavelength of 600 nm to 700 nm.

And blue light having a wavelength of 400 nm to 500 nm disposed on the outermost uppermost and lowermost second unit of the plurality of second units, or disposed outside the second unit of the left or right end, toward the plurality of first units. And a light emitting unit including at least one semiconductor optical device for emitting red light having a wavelength of 600 nm to 700 nm.

The first unit has a predetermined length so that the plant is detachably planted, and includes a plurality of growth ropes for absorbing water supplied from both directions, and the first water supply frame and the second water supply frame. The plurality of growth ropes fixed at both ends are arranged in parallel to each other.

The first unit may have a predetermined length so that the plant is detachably planted, and includes a plurality of growth ropes for absorbing water supplied from both directions, and the plurality of growth ropes each include the first water supply frame. And inclined with respect to the second water supply frame.

The first unit has a predetermined length so that the plant is detachably planted, a plurality of first growth ropes for absorbing water supplied from both directions, and a predetermined length so that the plant is detachably planted. And a plurality of second growth ropes for absorbing water supplied from both directions, wherein the plurality of first growth ropes are disposed to be inclined with respect to the first water supply frame and the second water supply frame, respectively. The two growth ropes are respectively inclined with respect to the first water supply frame and the second water supply frame, and each of the plurality of first growth ropes and the plurality of second growth ropes cross each other.

The first unit may be formed at a portion where each of the plurality of first growth ropes and each of the plurality of second growth ropes cross each other to interconnect a plurality of crossing points disposed in a straight line to interconnect the plurality of first growth ropes. It characterized in that it further comprises a support rope for maintaining the tension of each of the growth rope and each of the plurality of second growth rope.

The second unit may further include a hollow or solid connection frame connecting one end or both ends of each of the first water supply frame and the second water supply frame.

In addition, the first unit has a predetermined length so that the plant is detachably planted, and includes a growth rope for absorbing water supplied from one or two directions, and a coating assembly for receiving and wrapping the growth rope. do.

According to the present invention having the above configuration, the following effects can be achieved.

Firstly, the present invention provides a light absorbing apparatus comprising: a first unit absorbing water; And a second unit supporting the first unit, wherein a plant to be grown is detachably planted in the first unit where water is absorbed, so that the plant is very simple as compared to a facility installed in a conventional plant factory. Despite the structure, plant growth is possible.

In addition, the first unit according to the present invention has a predetermined length so that the plant is detachably planted, and includes a growth rope for absorbing water supplied from one direction or two directions, and one or both ends of the growth rope are second units. By mounting it in a relatively simple configuration, it will be possible to grow a large number of plants in a limited space and area.

In particular, the present invention minimizes the use of fossil fuels for overall plant growth compared to the prior art and existing plant plants, and gradually supplies moisture to the leaves and roots of the plant by using the capillary phenomenon of the first unit. This allows for very little time and money to maintain.

In addition, the first unit according to the present invention has a predetermined length so that the plant is detachably planted, a growth rope for absorbing water supplied from one direction or both directions, and a second unit formed at one end or both ends of the growth rope. By including a fixed knot mounted to the plural plants, it will be possible to provide a secure fixing structure of the first unit which will simultaneously supply the plural plants with water.

The second unit according to the present invention includes a water supply frame in which an end of the first unit is fixed and forms a space in which water is accommodated, and includes a first water in which a water is received. And a second water supply frame disposed in parallel with the first water supply frame and defining a space in which water is received, wherein both ends of the first unit are respectively the first water supply frame and the second water. By being fixed in communication with the internal space of the supply frame, the water supply to the first unit can be made gradually and uniformly.

In addition, the plurality of second units according to the present invention may be stacked in a multi-stage stack up or down, or may be arranged in parallel from side to side, and the first units may be coupled to the plurality of second units, respectively, and arranged in parallel, thereby providing a plurality of limited spaces and areas. It will also be possible to grow and harvest large quantities of plants.

In addition, the first unit according to the present invention has a predetermined length so that the plant is detachably planted, and includes a plurality of growth ropes for absorbing the water supplied from both directions, the first water supply frame and the second water supply frame. The plurality of growth ropes fixed at both ends may be arranged in parallel to each other, or the plurality of growth ropes may be disposed to be inclined with respect to the first water supply frame and the second water supply frame, respectively, thereby increasing plant yield per unit area. Will be.

In addition, the first unit according to the present invention has a predetermined length so that the plant is detachably planted, a plurality of first growth ropes for absorbing water supplied from both directions, and has a predetermined length so that the plant is detachably planted. And a plurality of second growth ropes for absorbing water supplied from both directions, wherein the plurality of first growth ropes are respectively inclined with respect to the first water supply frame and the second water supply frame, and the plurality of second growth ropes. Are respectively inclined with respect to the first water supply frame and the second water supply frame, and each of the plurality of first growth ropes and the plurality of second growth ropes cross each other to further increase plant yield per unit area. Will be.

In addition, the first unit according to the present invention may be formed at a portion where each of the plurality of first growth ropes and each of the plurality of second growth ropes cross each other, thereby interconnecting a plurality of intersections arranged in a straight line, and thus, the plurality of first growth ropes. By further providing a support rope for maintaining the tension of each of the growth ropes and each of the plurality of second growth ropes, it will be possible to maintain structural strength by fully supporting a plurality of plant growths and the load of the first unit itself.

In addition, the second unit according to the present invention is further provided with a hollow or solid connecting frame connecting one end or both ends of each of the first water supply frame and the second water supply frame, thereby maintaining the state of being spaced apart from each other. Or it will be possible to provide convenience during installation.

In addition, the first unit according to the present invention has a certain length so that the plant is detachably planted, and includes a growth rope for absorbing the water supplied from one direction or two directions, and a coating assembly for receiving and wrapping the growth rope, The algae of the algae are protected by the coating assembly and the first unit that absorbs moisture does not receive light directly from the light source, so that green algae occur along the length of the first unit in accordance with the growth of the plant and absorption of moisture. You will be able to block it fundamentally.

1 is a front conceptual view showing the overall structure of the plant growth apparatus according to an embodiment of the present invention
2 and 3 is a front conceptual view showing the overall structure of the plant growth apparatus according to various embodiments of the present invention
FIG. 4 is an enlarged view of part IV of FIG. 3, and is a conceptual diagram sequentially illustrating a process for planting a plant in a first unit which is a main part of a plant growth apparatus according to another exemplary embodiment of the present invention;
5 to 8 is a front conceptual view showing the actual installation state of the plant growth apparatus according to various embodiments of the present invention
FIG. 9 is a plan view illustrating a state in which a first unit is installed in a second unit that is a main part of a plant growth apparatus according to various embodiments of the present disclosure, as viewed from the point IX of FIG. 1.
FIG. 10 is a plan view illustrating modifications of a second unit provided with a first unit, which is a main part of a plant growth apparatus, as viewed from the point X of FIG. 2.
FIG. 11 is a view illustrating a process for planting plants in a first unit which is a main part of a plant growing apparatus according to another embodiment of the present invention, as viewed from the point XI of FIG. 3.

Advantages and features of the present invention, and methods for achieving them will be apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms.

In this specification, the embodiments are provided so that the disclosure of the present invention may be completed and the scope of the present invention may be completely provided to those skilled in the art.

And the present invention is only defined by the scope of the claims.

Thus, in some embodiments, well known components, well known operations and well known techniques are not described in detail in order to avoid obscuring the present invention.

In addition, the same reference numerals throughout the specification refer to the same components, and the terminology (discussed) used herein is for the purpose of describing the embodiments are not intended to limit the invention.

As used herein, the singular forms "a", "an" and "the" include plural unless the context clearly dictates otherwise, and the elements and acts referred to as 'comprises' or 'do' not exclude the presence or addition of one or more other components and acts. .

Unless otherwise defined, all terms (including technical and scientific terms) used in the present specification may be used in a sense that can be commonly understood by those skilled in the art.

In addition, the terms defined in the commonly used dictionary are not ideally or excessively interpreted unless they are defined.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

First, Figure 1 is a front conceptual view showing the overall structure of the plant growth apparatus according to an embodiment of the present invention.

2 and 3 are front conceptual views showing the overall structure of the plant growth apparatus according to various embodiments of the present invention.

4 is an enlarged view of part IV of FIG. 3 and sequentially illustrates a process for planting the plant 300 in the first unit 100 which is a main part of the plant growth apparatus according to another exemplary embodiment of the present invention. Conceptual diagram.

5 to 8 are front conceptual diagrams showing an actual installation state of the plant growth apparatus according to various embodiments of the present disclosure.

9 is a plan view illustrating the state in which the first unit 100 is installed in the second unit 200 which is the main part of the plant growth apparatus according to various embodiments of the present disclosure. .

In addition, FIG. 10 is a plan view illustrating modified examples of the second unit 200, in which the first unit 100, which is a main part of the plant growth apparatus, is installed, as viewed from the point X of FIG. 2. to be.

In addition, FIG. 11 is a view from the point XI of FIG. 3, and sequentially illustrates a process for planting the plant 300 in the first unit 100 which is a main part of the plant growth apparatus according to another embodiment of the present invention. Conceptual diagram.

First, the present invention includes a first unit 100 for absorbing water and a second unit 200 for supporting the first unit 100, as shown in FIGS. It can be seen that the plant 300 to grow on (100) is a structure that is detachably planted.

The present invention can be applied to the above embodiments, and of course, the following various embodiments are also applicable.

First, the second unit 200 has a height lower than that of the second unit 200 on one side so that water can be absorbed and moved along the longitudinal direction of the first unit 100 in the gravity direction. By differently arranged, water is naturally absorbed along the first unit 100 from the second unit 200 located in the high direction in the direction of gravity without the need for a separate power source and moved to the second unit 200 located in the lower place. It would also be possible to design for placement.

In addition, as shown in FIG. 2, the second unit 200 may be connected to the water supply 400 to supply water to the first unit 100, and the water supply 400 may be connected to the second unit ( 200 may include a water tank 410 connected to the pipe 415.

In addition, the water supply source 400 is mounted on a pipe 415 connecting the second unit 200 and the water tank 410 to further supply a pump 420 for supplying water in the water tank 410 in one direction. It may include.

In addition, at least one semiconductor optical device 501 irradiating blue light having a wavelength of 400 nm to 500 nm or red light having a wavelength of 600 nm to 700 nm toward the plant 300 planted in the first unit 100 as shown in FIG. 3. ) May further include a light emitting unit 500.

Here, the semiconductor optical device 501 may use a low power high efficiency LED chip.

According to the present invention, in addition to the semiconductor optical device 501 including the LED chip as a light source, a general light source using power, for example, a fluorescent lamp, a mercury lamp, a halogen lamp or an incandescent lamp may be used.

In this case, the present invention may further include an optical cover 600 which is spaced apart from the light emitting unit 500 and scatters blue or red light emitted from the semiconductor optical device 501 toward the first unit 100. .

The optical cover 600 may have an arc-shaped cross section, but is not necessarily limited to this structure, and any shape may be used as long as it helps the light diffusion.

On the other hand, the first unit 100 has a predetermined length so that the plant 300 is removably planted, and includes a growth rope 110 for absorbing the water supplied from one direction or both directions, the growth of the growth rope 110 One end or both ends can be seen that is mounted to the second unit 200 to be described later.

In addition, the first unit 100 may further include a fixing knot 120 formed at one end or both ends of the growth rope 110 and mounted to the second unit 200.

Here, the fixed knot 120 is made of the same or different material as the growth rope 110, the water movement passage in which the water contained in the second unit 200 is absorbed and transported along the longitudinal direction of the growth rope 110 Simultaneously with the starting point of the role, the growth rope 110 also serves as a fixed end fixed to the second unit (200).

The growth rope 110 may be formed by twisting a plurality of unit yarns (101a, 101b) made of a natural fiber or synthetic fiber material, as shown in Figures 1 to 4, although not specifically illustrated, a piece of cloth such as a nonwoven fabric It may be manufactured to form a long to form a fine water absorption structure.

That is, the growth rope 110 is not only the twisted structure of the unit yarns (101a, 101b) as shown in Figures 1 to 4, but also is produced in the shape of an amorphous fiber structure of a fine porous structure such as a non-woven fabric to induce capillary phenomenon It is of course also possible to design applications and variants that make it possible.

On the other hand, the present invention is spaced apart along the longitudinal direction of the growth rope 110, as shown in Figure 4, the plurality of unit yarns (101a, 101b) is detachably coupled to the twisted portion, plant 300 It may be further provided with a support ring member 700 of both ends penetrating the connection portion of the leaf 310 and the root 320 of the.

The support ring member 700, as the growth rope 110 absorbs water as time passes, increases its own load, and grows according to the growth of the plants 300 planted along the longitudinal direction of the growth rope 110. Due to the increased load, excessive pressure is applied between the leaves 310 and the roots 320 of the plant 300 fixed to the growth rope 110 to prevent a problem in which growth may be impaired.

That is, the support ring member 700 serves to insulate pressure and impact so that the plant 300 does not directly receive the pressure of the growth rope 110, and the plant 300 grows to a certain extent to harvest. It may be used to have an inner diameter (d, see Fig. 4 (a) below) corresponding to the connection between the root 320 and the leaf 310 as much as possible.

The support ring member 700 is provided with a first locking flange 710 at the upper end of the support cylinder 730 and a second locking flange 720 at the lower end of the coupling sleeve 740.

The support cylinder 730 is a member of both ends through which the plurality of unit yarns 101a and 101b are coupled through a mounting space slot 102 formed by loosely unwinding the twisted portion (see FIG. 4A).

The first locking flange 710 extends from one end edge of the supporting cylinder 730 to be fixed to one side edge of the growth rope 110.

Coupling sleeve 740 is a ring-shaped member having one end detachably coupled to the other end edge of the support cylinder 730.

The second locking flange 720 extends from the other end edge of the coupling sleeve 740 and is fixed to the other edge of the growth rope 110.

Here, the support ring member 700, and the first coupling step 731 is formed stepped along the outer peripheral surface of the other end of the support cylinder 730, for mutual engagement of the support cylinder 730 and the coupling sleeve 740 and The second coupling step 741 may be further provided along the inner circumferential surface of one end of the coupling sleeve 740 to engage with the first coupling step 731.

In this case, the first coupling step 731 and the second coupling step 741 may be maintained in a coupled state such as to be fitted or bonded by an interference fit method.

In addition, the support ring member 700 is a ring-shaped first roundly formed at a portion connected to the one end edge of the support cylinder 730, the inner circumferential surface of the support cylinder 730, and the connection portion of the first locking flange 710. A ring-shaped second through-guiding surface 752 rounded at a portion connected to the through-guiding curved surface 751, the other end edge of the coupling sleeve 740, the inner circumferential surface of the loosening sleeve, and the connection portion of the second locking flange 720. ) May be further provided.

In addition, the support ring member 700 is a ring-shaped first roundly formed at a portion connected to the one end edge of the support cylinder 730, the outer peripheral surface of the support cylinder 730 and the connection portion of the first locking flange 710 A ring-shaped second hooking guide surface 762 rounded at a portion connected to the hooking guide surface 761, the other end edge of the coupling sleeve 740, the outer circumferential surface of the binding sleeve, and the connection portion of the second locking flange 720. ) May be further provided.

Here, the first through guide curved surface 751 and the second through guide curved surface 752 are provided to be inserted so as to penetrate the root 320 of the plant 300 so as to be planted smoothly.

At this time, the first locking guide curved surface 761 and the second locking guide curved surface 762 are formed in a curved surface corresponding to the outer peripheral surface of each of the plurality of unit yarns (101a, 101b), thereby supporting the support ring member ( 700) is provided to be securely seated.

On the other hand, the second unit 200, the end of the first unit 100 is fixed, and includes a water supply frame (210, 220) to form a space for receiving water therein, the water is received therein A structure including a first water supply frame 210 forming a space and a second water supply frame 220 disposed in parallel with the first water supply frame 210 and forming a space in which water is received. An embodiment of may be applicable.

Here, the first unit 100, that is, both ends of the growth rope 110 through the fixing knot 120 in communication with the internal space of the first water supply frame 210 and the second water supply frame 220, respectively Fixed is as described above.

In this case, the plurality of second units 200 may be stacked in a multi-stage stack as shown in FIG. 5, or arranged in parallel to the left and right as shown in FIG. 6, and the first unit 100 is coupled to the plurality of second units 200, respectively. Of course, it is also possible to apply an embodiment of the structure arranged in parallel.

6 and 8, the first unit 100 extends from an end of the first unit 100 fixed to the second water supply frame 220 and is received in the second water supply frame 220. It may be further provided with an absorbent wick 130 connected to.

Here, when a plurality of second units 200 including the first water supply frame 210 and the second water supply frame 220 are arranged in parallel in a plurality of left and right directions, the second water supply frame 220 may supply the first water supply. Of course, it can be arranged under the frame 210.

5 and 6, the present invention is disposed outside the second unit 200 at the top or bottom of the plurality of second units 200, or outside the second unit 200 at the left or right end. The light emitting unit 500 further includes at least one semiconductor optical device 501 disposed at the first unit 100 to emit blue light having a wavelength of 400 nm to 500 nm or red light having a wavelength of 600 nm to 700 nm. It may be provided.

7 and 8, the present invention may be disposed outside the second unit 200 at the top and bottom of the plurality of second units 200, or may be outside the second unit 200 at the left or right end. The light emitting unit 500 further includes at least one semiconductor optical device 501 disposed at the first unit 100 to emit blue light having a wavelength of 400 nm to 500 nm or red light having a wavelength of 600 nm to 700 nm. Of course, it can also be provided.

In this case, the optical cover 600 may be further spaced apart from the light emitting unit 500 to scatter blue or red light emitted from the semiconductor optical device 501 toward the first unit 100. As shown.

Particularly, in the present invention, as shown in FIGS. 7 and 8, some plants 300 of the plurality of plants 300 planted in the first unit 100 may have one light emitting unit 500 of the light emitting units 500 disposed on both sides. It may be arranged so that the leaf 310 is directed to the side.

In addition, in the present invention, as shown, some of the plants 300 of the plurality of plants 300 planted in the first unit 100 are moved toward the other light emitting unit 500 from among the light emitting units 500 disposed on both sides. The leaf 310 may be disposed to face.

Arranging the leaves 310 and the roots 320 of the plant 300 in a staggered direction as described above controls the degree to which light is irradiated depending on the type of the plant 300 to grow such as leafy vegetables or root vegetables. To provide a suitable environment to the plant 300.

Thus, for example, the operation time of the light emitting unit 500 on one side and the light emitting unit 500 on the other side of the light emitting units 500 disposed on both sides are staggered, simultaneously operated, or on one side of the light emitting unit 500. And various kinds of plants 300 such as leafy vegetables and root vegetables in various ways, such as different operating times of the light emitting unit 500 and the other side, between the first water supply frame 210 and the second water supply frame 220. It will also be possible to simultaneously grow on a plurality of growth ropes 110 arranged in the space.

Meanwhile, in the present invention, as shown in FIG. 9 (a), the plurality of growth ropes 110 having both ends fixed to the first water supply frame 210 and the second water supply frame 220 may be disposed in parallel to each other, or FIG. As shown in 9 (b), the plurality of growth ropes 110 are disposed to be inclined with respect to the first water supply frame 210 and the second water supply frame 220, respectively, so that the plant 300 is planted and produced per unit area. Will be able to increase.

In addition, the present invention has a predetermined length so that the plant 300 is detachably planted as shown in Figure 9 (c) and a plurality of first growth rope 111 for absorbing the water supplied from both directions, and the plant 300 From an embodiment of the structure including a plurality of second growth ropes 112 having a predetermined length to be detachably planted and absorbing water supplied from both directions, the amount of the plants 300 per unit area can be further increased. Could be.

Here, the plurality of first growth ropes 111 are disposed to be inclined with respect to the first water supply frame 210 and the second water supply frame 220, respectively, the plurality of second growth ropes 112 are each of the first water It is disposed to be inclined with respect to the supply frame 210 and the second water supply frame 220, each of the plurality of first growth ropes 111 and each of the plurality of second growth ropes 112 cross each other.

At this time, the first unit 100 is formed in a position where each of the plurality of first growth ropes 111 and each of the plurality of second growth ropes 112 cross each other, as shown in FIG. It may be further provided with a support rope 114 to maintain the tension of each of the plurality of first growth ropes 111 and each of the plurality of second growth ropes 112 by interconnecting a plurality of intersections (113).

9 (c) and 9 (d) may be an example of a space arrangement in which a larger amount of plants 300 can be grown in a limited space.

Meanwhile, the second unit 200 includes a hollow or solid connection frame 230 connecting one end or both ends of each of the first water supply frame 210 and the second water supply frame 220 as shown in FIG. 10. It may be further provided.

That is, the first water supply frame 210 and the second water supply frame 220 are separately arranged in parallel as shown in FIGS. 2 by supplying water to each of the water supply frame 220 to be connected to the water source 400 separately, or by adding a hollow connection frame 230 as shown in Figure 10 (c) and 10 (d) first The water of the water supply frame 210 and the second water supply frame 220 may be circulated.

In addition, although not specifically illustrated, the connecting frame 230 is made of a solid body, and only the first water supply frame 210 and the second water supply frame 220 are connected to each other to be stacked up and down in multiple stages as shown in FIG. 5 or 7. 6 or 8 may be provided when loading or installing a shelf or a tray when the left and right parallel arrangement as shown in FIG.

On the other hand, the present invention can be applied to the embodiment of the structure further provided with a covering assembly 800 surrounding the first unit 100, that is, growth rope 110 as shown in FIG.

The coating assembly 800 is a hollow cladding tube 810 of both ends through which the growth rope 110 can be longitudinally received as shown, and along the longitudinal direction of the cladding tube 810, FIGS. An embodiment of the structure in which the first planting hole 812 is formed through a predetermined interval as shown in 11 (b) can be applied.

The cladding tube 810 is a flexible member made of a translucent or opaque material so that the light of the light source is not directly transmitted to the root 320 of the plant 300, and the light of the light source is directly transmitted to the growth rope 110. In accordance with it is provided to fundamentally block the growth of green alga that may occur on the surface of the growth rope 110 after a certain time.

Therefore, the worker preferentially penetrates the first planting hole 812 on the surface of the covering tube 810, or inserts one end of the growth rope 110 into the covering tube 810, and then passes the first planting hole 812 in the covering tube 810. After the planting hole 812 is formed, the twisted portion of the growth rope 110 may be loosened, and the root 320 of the plant 300 may be fixed and seated as shown in FIG.

In addition, the cladding tube 810 of the cladding assembly 800 may be connected to the second unit 200, that is, the first and second water supply frames 210 and 220, or simply to receive and wrap only the growth rope 110. Of course, embodiments of the structure may be applied.

In addition, the cladding assembly 800 is fixed to the outer ring surface of the cladding tube 810 through the mounting space slot 102 of the growth rope 110, the above-described support ring member 700, Figure 11 (c) and As shown in FIG. 11D, an embodiment of the structure including the second planting hole 814 penetrating the outer circumferential surface of the cladding tube 810 orthogonally may be applied.

Accordingly, the operator preferentially penetrates the second planting hole 814 on the surface of the covering tube 810, or inserts one end of the growth rope 110 into the covering tube 810, and then penetrates the first covering tube 810. After the planting hole 814 is formed, the twisted portion of the growth rope 110 is loosened to fit the support ring member 700 to the mounting space slot 102 as shown in FIG. The root 320 may be fixedly seated through the support ring member 700 as shown in FIG. 11 (d) to promote growth.

Hereinafter, the operation and effects of the plant growth apparatus according to the preferred embodiment of the present invention will be described as follows.

Firstly, the present invention provides a method for absorbing water, comprising: a first unit 100 for absorbing water; And a second unit 200 supporting the first unit 100, wherein the plant 300 to be grown is detachably planted in the first unit 100 in which water is absorbed. Compared to the equipment installed in the plant of the plant is a very simple structure, but the growth of the plant 300 is possible.

In addition, the first unit 100 according to the present invention has a predetermined length so that the plant 300 is detachably planted, and includes a growth rope 110 for absorbing water supplied from one direction or two directions, and the growth rope. One end or both ends of the 110 will be mounted to the second unit 200, whereby a large number of plants 300 will be grown in a limited space and area in a relatively simple configuration.

In particular, the present invention minimizes the use of fossil fuels for the overall growth of the plant 300 compared to the prior art and existing plant plants, and uses the capillary phenomenon of the first unit 100 to provide the leaves of the plant 300 ( 310 and the roots 320 can be continuously supplied to the water steadily, so that much time and money is little in maintenance.

In addition, the first unit 100 according to the present invention has a predetermined length so that the plant 300 is detachably planted, a growth rope 110 for absorbing water supplied from one direction or two directions, and a growth rope 110. And a fixed knot portion 120 formed at one end or both ends of the c) to be mounted to the second unit 200, so that the plurality of plants 300 are planted and at the same time supply water to the plurality of plants 300. It will be possible to provide a secure fixing structure of the first unit 100 to be.

In addition, the growth rope 110 according to the present invention, the plurality of unit yarns (101a, 101b) made of a natural fiber or synthetic fiber material is formed by twisting, the plant 300 can be maintained in a fixed planting state reliably In addition, it will be possible to provide a continuous supply of water due to the capillary phenomenon.

And, the second unit 200 according to the present invention, the end of the first unit 100 is fixed, and includes a water supply frame (210, 220) to form a space for receiving water therein, The first water supply frame 210 to form a space for receiving water, and the second water supply frame 220 disposed in parallel with the first water supply frame 210, forming a space in which water is received And both ends of the first unit 100 are fixed to communicate with internal spaces of the first water supply frame 210 and the second water supply frame 220, respectively, thereby providing moisture to the first unit 100. The feed will be made slowly and consistently.

In addition, the plurality of second units 200 according to the present invention may be stacked in a multi-stage stack, or may be arranged in parallel from side to side, and the first unit 100 may be coupled to the plurality of second units 200 and arranged in parallel. By doing so, it will also be possible to grow and harvest a large number of plants 300 in a limited space and area.

In addition, the first unit 100 according to the present invention has a predetermined length such that the plant 300 is detachably planted, and includes a plurality of growth ropes 110 for absorbing water supplied from both directions. The plurality of growth ropes 110 having both ends fixed to the water supply frame 210 and the second water supply frame 220 may be disposed in parallel with each other, or the plurality of growth ropes 110 may each have a first water supply frame ( By being inclined with respect to the 210 and the second water supply frame 220, it will be possible to increase the yield of the plant 300 per unit area.

The first unit 100 has a predetermined length such that the plant 300 is detachably planted, and the plurality of first growth ropes 111 for absorbing water supplied from both directions, and the plant 300 are detachable. It has a predetermined length so as to be planted, and includes a plurality of second growth ropes 112 for absorbing water supplied from both directions, each of the plurality of first growth ropes 111 and the first water supply frame 210 and It is disposed to be inclined with respect to the second water supply frame 220, the plurality of second growth ropes 112 are disposed to be inclined with respect to the first water supply frame 210 and the second water supply frame 220, respectively, Each of the first growth ropes 111 and the plurality of second growth ropes 112 cross each other, thereby further increasing the yield of the plant 300 per unit area.

In addition, the first unit 100 according to the present invention includes a plurality of first growth ropes 111 and a plurality of second growth ropes 112 each formed at a portion crossing each other and arranged in a straight line. By further providing a support rope 114 for interconnecting the intersections 113 to maintain the tension of each of the plurality of first growth ropes 111 and each of the plurality of second growth ropes 112, the plurality of plants 300 By supporting the growth and the load of the first unit 100 as a whole will be able to maintain the structural strength.

In addition, the second unit 200 according to the present invention, the connection frame 230 of the hollow or solid connecting one end or both ends of each of the first water supply frame 210 and the second water supply frame 220. By further having it, it will be possible to provide convenience during loading or installation by maintaining the spaced apart state.

In addition, the first unit 100 according to the present invention has a predetermined length so that the plant 300 is detachably planted, a growth rope 110 for absorbing water supplied from one direction or two directions, and a growth rope 110. ), The first unit 100 that absorbs moisture while allowing the root 320 of the plant 300 to be protected by the coating assembly 800 by receiving and covering the coating assembly 800. By not receiving the light will be able to fundamentally block the green algae generated in the longitudinal direction of the first unit 100 in accordance with the growth of the plant 300 and the absorption of moisture.

As described above, it can be seen that the present invention has a basic technical idea to provide a plant growth apparatus capable of cultivating a large number of plants in a limited space and area in a relatively simple configuration.

In addition, many modifications and applications are also possible to those skilled in the art within the scope of the basic technical idea of the present invention.

100 ... 1st unit
101a, 101b ...
102 ... mounting space slot
110 ... Growth Rope
111.First Growth Rope
112.2nd growth rope
113 ... Intersection
114.Support Rope
120.Fixed Knot
130 ... absorbent wick
200 ... 2nd Unit
210.First water supply frame
220 ... second water supply frame
230 ... connection frame
300 plants
310 ... leaf
320 ... root
400 ... water source
410 ... water tank
415. Piping
420 ... pump
500 ... light emitting unit
501 Semiconductor Semiconductor
600 ... optical cover
700 ... support ring member
710 ... First engaging flange
720 ... 2nd engagement flange
730 ... support
731 ... the first coupling step
740 ... Mating Sleeve
741.2nd engagement step
751 ... First through guide surface
752 ... 2nd penetration guide surface
761 ... First Jammed Surface
762 ... Secondary Jam Guide Surface
810 ... sheath
812 ... First Planting Hall
814.Second Plant Hall

Claims (15)

A first unit for absorbing water; And
A second unit supporting the first unit,
A plant growth apparatus, characterized in that the plant to be grown is detachably planted in the first unit where water is absorbed.
The method according to claim 1,
The first unit,
It has a certain length so that the plant is detachably planted, and includes a growth rope for absorbing the water supplied from one direction or both directions,
One end or both ends of the growth rope is mounted to the second unit plant growth apparatus.
The method according to claim 1,
The first unit,
A growth rope having a predetermined length so that the plant is detachably planted and absorbing water supplied from one or two directions;
Plant growth apparatus characterized in that it comprises a fixed knot formed on one end or both ends of the growth rope to be mounted to the second unit.
The method according to claim 1,
The second unit,
An end of the first unit is fixed, the plant growth apparatus characterized in that it comprises a water supply frame to form a space for receiving water therein.
The method according to claim 1,
The second unit,
A first water supply frame forming a space in which water is received;
A second water supply frame disposed in parallel with the first water supply frame and forming a space in which water is received;
Both ends of the first unit is plant growth apparatus, characterized in that fixed to communicate with the inner space of the first water supply frame and the second water supply frame, respectively.
The method according to claim 1,
The plurality of second units are arranged in a multi-stacked stack up and down, or arranged in parallel from side to side, the first unit is coupled to the plurality of second units, respectively, plant growth apparatus, characterized in that arranged.
The method according to claim 6,
The second unit,
A first water supply frame forming a space in which water is received;
A second water supply frame disposed in parallel with the first water supply frame and forming a space in which water is received;
Both ends of the first unit is plant growth apparatus, characterized in that fixed to communicate with the inner space of the first water supply frame and the second water supply frame, respectively.
The method according to claim 6,
Blue light having a wavelength of 400 nm to 500 nm, or 600 nm to 500, disposed on the outermost upper or lowermost second unit of the plurality of second units, or disposed on the outer side of the second unit on the left or right end. And a light emitting unit including at least one semiconductor optical element for emitting red light having a wavelength of 700 nm.
The method according to claim 6,
Blue light having a wavelength of 400 nm to 500 nm, or 600 nm to 500, disposed on the outermost uppermost and lowermost second unit of the plurality of second units or disposed on the outer side of the second unit of the left or right end. And a light emitting unit including at least one semiconductor optical element for emitting red light having a wavelength of 700 nm.
The method according to claim 5,
The first unit,
It has a certain length so that the plant is detachably planted, and includes a plurality of growth rope for absorbing water supplied from both directions,
Plant growth apparatus, characterized in that the plurality of growth ropes having both ends fixed to the first water supply frame and the second water supply frame are arranged in parallel to each other.
The method according to claim 5,
The first unit,
It has a certain length so that the plant is detachably planted, and includes a plurality of growth rope for absorbing water supplied from both directions,
The plurality of growth ropes are plant growth apparatus, characterized in that arranged inclined with respect to the first water supply frame and the second water supply frame, respectively.
The method according to claim 5,
The first unit,
A plurality of first growing ropes having a predetermined length so that the plant is detachably planted and absorbing water supplied from both directions;
It has a length so that the plant is detachably planted, and includes a plurality of second growth rope for absorbing water supplied from both directions,
The plurality of first growth ropes are respectively inclined with respect to the first water supply frame and the second water supply frame,
The plurality of second growth ropes are respectively inclined with respect to the first water supply frame and the second water supply frame,
And each of the plurality of first growth ropes and each of the plurality of second growth ropes cross each other.
The method according to claim 12,
The first unit,
Each of the plurality of first growth ropes and each of the plurality of first growth ropes are formed at a portion where each of the plurality of first growth ropes and the plurality of second growth ropes cross each other and are connected to each other. 2 Growth rope Plant growth apparatus further comprises a support rope for maintaining the tension of each.
The method according to claim 5,
The second unit,
And a hollow or solid connection frame connecting one end or both ends of each of the first water supply frame and the second water supply frame.
The method according to claim 1,
The first unit,
A growth rope having a predetermined length so that the plant is detachably planted and absorbing water supplied from one or two directions;
And a sheath assembly for receiving and wrapping said growth rope.

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