KR20100015260A - Hydroponic device - Google Patents

Abstract

PURPOSE: A hydroponic port assembly is provided to prevent the nutrient solutions which are supplied to an upper port from filtering with culture soil by forming a nutrient solution supplying path, and to efficiently broaden a planting space. CONSTITUTION: A hydroponic port assembly is alternatively laminated. The top of the hydroponic port assembly is opened. The hydroponic port assembly includes the following: a main body(21) including an elevated part(22); hydroponic ports(20,20') including bearing blades(23,23') contacted on the top of the main body; and a connection member(40) in which a nutrient solution supplying pipe(41) is formed and installed between the hydroponic ports.

Description

Nutrient cultivation port assembly

The present invention relates to a nutrient solution cultivation port unit, and more particularly, to a stacked nutrient solution cultivation port unit capable of supplying a nutrient solution of a substantially uniform component to each of the stacked ports and to increase the planting space of the plant.

Nutrient cultivation method refers to a method of cultivating a crop using an aqueous solution (hereinafter, "nutrient solution") in which the essential elements required for the growth of the crop are dissolved at an appropriate concentration according to the absorption ratio. Nutrient cultivation is a scientific farming technique that can optimize the growth conditions of crops by keeping the environment uniform because it can artificially and precisely control the medium conditions of nutrient solution and root part.

Nutrient cultivation is divided into plow cultivation, hydroponic cultivation and solid medium cultivation depending on the type of excretion. Among them, the most widely used solid media cultivation currently supports crops with solid media (hereafter referred to as "cultivation soils") made of sand, perlite, rock wool, gravel, rice husk, hultan, etc., instead of natural soils. Cultivation method to supply nutrient solution.

Conventional solid medium cultivation equipment is established by forming a nutrient solution port on the nutrient solution cultivation bed installed on the pit in the greenhouse, as described in the Republic of Korea Patent Application No. 1992-13535 The disadvantage is that excessive budget is required.

On the other hand, as another example of the prior art, Korean Patent Application No. 2000-20483 discloses a domestic nutrient cultivation device for raising crops by placing the inner container inside the styrofoam material outer container formed with a lattice-shaped water drain hole and holding soil instead of the culture soil Korean Utility Model Registration Application No. 2001-22173 discloses a technique for spraying nutrient solution with a nozzle installed at an upper portion of a port installed on a nutrient solution cultivation bed.

In addition, the conventional nutrient cultivation apparatus can not arbitrarily adjust the height of the nutrient solution cultivation port according to the characteristics of the crop in the facility house lacking space or space, and also does not uniformly adjust the amount of sunshine due to the ceiling in the facility house.

In view of this point, Patent No. 00499610 discloses a stacked nutrient solution cultivation port. The stacked nutrient solution cultivation port has a structure for supplying nutrient solution to the nutrient solution port located at the upper side to flow down to the nutrient solution port side of the lower side, so that the nutrients of the nutrient solution are filtered out to the solid medium stored in the nutrient solution port at the upper side. The culture soil of the nutrient solution port is located there is a problem that the nutrients for cultivating the plant is not sufficiently supplied.

 The present invention is to solve the above problems, the nutrient solution cultivation port assembly that can be supplied to each port of the nutrient solution supplied to the stacked port is not filtered by all the culture soil contained in the port located at the top The purpose is to provide.

Another object of the present invention is to provide a nutrient solution cultivation port assembly that can improve the efficiency of the supply and recovery of nutrient solution in a stacked port for growing plants.

It is another object of the present invention to provide a nutrient solution cultivation port assembly that can relatively widen the planting space of the plant.

Nutrient cultivation port assembly of the present invention for achieving the above object is to be laminated to each other, the upper portion is open, the main body including a ridge having a hollow and defining the storage height of the nutrient solution in the center, and a predetermined on the outer peripheral surface of the main body Nutrient cultivation ports including support wings which are installed at intervals and in contact with the upper portion of the main body of the nutrient solution port located at the bottom,

It is characterized in that it is provided between the nutrient solution cultivation ports provided with a connecting member for forming a passage for supplying nutrient solution to the nutrient solution supply and nutrient solution cultivation port.

In the present invention, the connecting member is coupled to the hollow of the ridge formed on the lower surface of the nutrient solution cultivation port located in the upper portion of the nutrient solution supply pipe is located in the upper portion of the ridge, and the cover formed in the radial direction at the lower end of the nutrient solution supply pipe Equipped.

And a support penetrating the hollow formed in the ridges of the stacked nutrient cultivation ports and the connecting member positioned at the yarns of the nutrient cultivation ports.

An end of the raised portion is coupled to the lower end of the connecting member and its outer circumferential surface is formed with a medicinal inlet formed with a groove in the nutrient solution longitudinal direction.

Alternatively nutrient solution cultivation port assembly of the present invention to achieve the above object

It is stacked on top of each other, the upper part is open, the storage height of the nutrient solution in the central portion, the upper and lower strait body including a ridge having a hollow, and the nutrient solution cultivation is installed at a predetermined interval on the outer peripheral surface of the main body Nutrient cultivation ports including support wings supported on the body of the pot,

A connecting member having a nutrient solution supply pipe positioned between the stacked nutrient solution cultivation ports and having an upper end coupled to a hollow of the nutrient solution cultivation port located above, and a cover formed radially at an end of the nutrient solution supply pipe;

It is combined with the ridge of the nutrient solution cultivation port located at the bottom and corresponding to the lower end of the nutrient solution supply pipe to combine the nutrient solution supply pipe and the ridge, the first groove is formed on the outer peripheral surface to form the inflow passage of the nutrient solution, the inner peripheral surface It characterized in that it is provided with a packing member formed with a second groove for forming the discharge passage of the nutrient solution in the longitudinal direction.

The nutrient solution cultivation port assembly configured as described above can supply the same nutrient solution that is not filtered while passing through all the culture soils contained in each nutrient solution cultivation port, so that the plants growing in the culture soil can prevent growth disorders due to nutrient supply unevenness of the nutrient solution. have. In addition, since the stacked nutrient solution cultivation port has a structure that is coupled to the nutrient solution cultivation port located at the bottom by a plurality of support wings formed on the outer circumferential surface, the planting space of the nutrient solution cultivation port is all formed at the opening edge of the nutrient solution cultivation port Reduced labor for harvesting

The nutrient solution cultivation port assembly according to the present invention is installed in the cultivation site nutrient solution cultivation ports are vertically stacked or the nutrient solution cultivation ports are stacked and transferred by the moving means of the nutrient solution.

1 shows that the nutrient solution cultivation port assembly 10 is installed in the moving means 30 of the nutrient solution cultivation device in one embodiment.

Referring to the drawings, the moving means 30 for transporting the nutrient solution cultivation port assembly 10 is constituted by a chain conveyor system. The chain conveyor system is wound around two chain wheels 31 and 31 '(drive side chain wheel and driven side chain wheel) installed at both ends and the teeth (not shown) of the chain wheels 31 and 31'. And a power transmission means including a motor 32 for supplying power to the chain 33 and the drive side chain wheel 31. In the present specification, only a chain conveyor is described as a moving means of the nutrient solution cultivation port assembly 10, but a rope transmission means or a belt transmission means may be used in addition to the chain transmission means. In addition, although the motor 32 is configured to transmit power only to the drive side chain wheel 31 in the present embodiment, when the length of the chain conveyor is considerably long, the drive side chain wheel 31 and the driven side for smooth driving. It is also possible to supply power to the chain wheel 31 'at the same time. The two chain wheels 31 and 31 'are interconnected by a cross support 37 on which a motor 32 is mounted, and two C-shaped pipes 34 extending substantially parallel to the cross support 37. It will be described later) is configured to guide the movement of the chain (33). In addition, the two C-shaped pipes 34 are connected to each other by a plurality of vertical supports 35 arranged at predetermined intervals. The chain wheels 31, 31 ′ and the vertical support 35 are fixed to the lower support 38 installed under the chain conveyor system by a plurality of vertical supports 36 arranged at predetermined intervals. The lower support 38 is provided with a conveyor gap adjusting means as described later.

The upper side of the nutrient solution cultivation port assembly 10 to be transported by the conveying means is provided with a spray nozzle 39 for supplying nutrient solution and a nutrient solution recovery channel (not shown) for recovering the nutrient solution discharged from the nutrient solution cultivation port assembly 10 Equipped. The nutrient solution recovery channel is a component that is supplied to the nutrient solution cultivation port 10 to recover the nutrient solution used by the crop and discharged to the bottom thereof for preventing and reusing environmental pollution.

As shown in FIGS. 1 and 2, the nutrient solution cultivation port assembly 10 suspended and conveyed by the moving means 30 is inserted into and stacked on the support 11 supported by the upper end of the hoist chain 33. The upper part is opened and the main body 21 having a storage space in which the culture soil 200 is stored on the lower surface thereof is raised upwards on the bottom surface of the main body to limit the storage level of the nutrient solution and has a hollow portion 22a. And a plurality of support wings 23 for supporting the main body 21 with respect to the nutrient solution cultivation port 20 'formed at predetermined intervals on the outer circumferential surface of the main body 21. The nutrient solution cultivation port 20 and the support 11 of the nutrient solution cultivation port 20, 20 'is formed to form a passage for supplying the nutrient solution to each nutrient solution cultivation port (20, 20') A connecting member 40 is provided.

The ridge 22 extends upward from the central portion of the main body 21 to limit the storage level of nutrient solution as described above, and the nutrient solution flows into the outer circumferential surface of the upper end side of the ridge 22 having the hollow 22a formed therein. The part 22c is formed. The nutrient solution inlet 22c may be formed by forming a groove in the longitudinal direction on the outer circumferential surface of the ridge 22c.

Here, the cross-sectional area of the groove portion through which the nutrient solution can be introduced is preferably made relatively wider than the cross-sectional area of the hollow portion through which the support is inserted so that the nutrient solution can flow downwardly through the ridge. On the other hand, in the case where the pillars are not laminated and the nutrient solution material ports 20 and 20 'are stacked, it is preferable that the inlet of the hollow portion formed on the upper portion of the ridge is smaller than the cross-sectional area of the groove.

And the lower portion of the hollow (22a) of the ridge 22 is provided with a connecting member coupling portion (22b) so that the upper end of the connecting member 40 can be smoothly coupled. The connection member coupling portion 22b may be formed as a part of the hollow 22a. To this end, the hollow portion 22a may have a stepped configuration.

The connecting member 40, the cover 42 is located on the lower end side of the nutrient solution supply pipe 41 and the nutrient solution supply pipe 41, the upper end of which is connected to the coupling portion coupling portion 22b of the nutrient solution cultivation port located in the upper portion 42 ). A plurality of slits may be formed in the cover 42.

And the lower surface of the support wing 23 formed on the outer circumferential surface of the main body 21 is formed with an inlet groove (23a) is inserted into the upper edge of the main body 21 'of the nutrient solution cultivation port (20') located below. A coupling groove 23b may be formed at an upper side of the main body 21 'and 21 corresponding to the inlet groove 23a formed in the wing portion.

 3 to 5 show another embodiment of the nutrient solution cultivation port assembly according to the present invention. In this embodiment, the same reference numerals refer to the same components.

Referring to the drawings, the ridge 22 and the pipe 41 of the connecting member 40 are connected by a packing member 50, the packing member 50 is the inflow passage of the nutrient solution in the longitudinal direction on the outer peripheral surface The first groove 51 is formed to form a second groove 52 is formed on the inner peripheral surface for the discharge of the nutrient solution in the longitudinal direction. Here, the lower side of the packing member 50 is preferably expanded to the outside so that it can be introduced into the nutrient solution cultivation port introduced through the first groove (51). The nutrient solution cultivation port, the connecting member, and the packing may be penetrated by the support to maintain a stacked state.

On the other hand, in the above-described embodiments, a plurality of through holes 21a are formed in the main body so as to improve air permeability on the outer circumferential surface of the main body relatively higher than the height of the ridge 22.

Reference numeral 60 is a nutrient solution reservoir for storing the nutrient solution supplied from the nozzle.

Referring to the operation of the nutrient solution cultivation port assembly according to the present invention configured as described in more detail as follows.

The nutrient solution cultivation port assemblies 10 in which a plurality of (3 to 6 in this embodiment) nutrient solution cultivation ports 12 are placed on the conveyor chain are fixed at predetermined intervals and drive the conveyor.

At the same time, the nutrient solution is injected from the nutrient solution injection nozzle 39 provided at the top, and the nutrient solution is supplied to the stacked nutrient solution cultivation port assembly 10 passing through the lower point of the nozzle. In this way, the nutrient solution supplied through the nozzle 39 is stored in the nutrient solution reservoir 60 located at the uppermost side, and when the nutrient solution reservoir 60 is filled, the nutrient solution stored below through the connecting member 40 is stored. To ports 21 and 21 '. That is, the nutrient solution supplied to the nutrient solution reservoir 60 is introduced into the nutrient solution cultivation port 21 through the nutrient solution inlet 22c formed on the circumferential surface of the nutrient solution supply pipe 41 and the ridge 22 of the connecting member 40. Inflow.

When the nutrient solution introduced in this way is supplied above the height of the ridge 22, the ridge 22 of the hollow 22a of the ridge 22 and the connecting member positioned at the lower portion and the ridge of the nutrient solution cultivation port 21 ′ positioned at the lower portion ( 22 ') is discharged to the nutrient solution cultivation port (21') at the bottom to wet the culture soil (200).

And when the nutrient solution supply pipe 41 and the ridge 22 of the connecting member 40 by the packing member 50 as shown in Figure 4 to 6 the nutrient solution introduced from the nutrient solution supply pipe 41 is The nutrient solution supplied through the first groove 51 of the packing member 50 and supplied above the height of the ridge 22 flows out downward through the second groove 52 of the packing member 50. .

Therefore, the nutrient solution supplied through the nozzle is uniformly supplied to each nutrient solution cultivation port and stored, and the stored nutrient solution can be continuously supplied to the culture soil.

And in the process of stacking the nutrient solution cultivation port (20, 20 ') according to the present invention on the support wing 23 formed on the outer peripheral surface of the nutrient solution cultivation port (20) located on the upper, that is to the main body 21 of the ordinary light Since the support wing 23 formed is supported at the upper edge of the main body 20 'of the nutrient solution cultivation port 20' positioned at the lower side, the culture soil is exposed along the edge of the upper side of the main body 21, so that the planting space of the plant Relatively wider, easier to harvest cultivated plants, such as root vegetables or herbs.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent embodiments are possible.

Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

Since the nutrient solution cultivation port assembly of the present invention can grow plants in multiple stages using stacked ports, it can be widely used in facility cultivation apparatuses such as greenhouses and houses.

1 is a perspective view showing a nutrient solution cultivation apparatus according to the present invention,

Figure 2 is an exploded perspective view showing an extract of the nutrient solution cultivation port assembly according to the present invention,

3 is a cross-sectional view of the nutrient solution cultivation port assembly according to the present invention,

Figure 4 is an exploded perspective view showing another embodiment of the nutrient solution cultivation port assembly according to the present invention,

5 is a cross-sectional view of the nutrient solution cultivation port assembly according to the present invention.

Figure 6 is a multi-sectional view showing a state in which the packing member, the connecting member and the ridge is combined.

Claims (5)

It is stacked on top of each other, the upper part of the main body of the nutrient solution port which is located at a lower interval and is installed at a predetermined interval on the outer circumferential surface of the main body and the main body including a ridge having a hollow defining a storage height of the nutrient solution in the center Nutrient solution cultivation ports comprising support wings in contact, The nutrient solution cultivation port assembly is provided between the nutrient solution cultivation ports provided with a connecting member for forming a passage for supplying nutrient solution to the nutrient solution supply and nutrient solution cultivation port. The method of claim 1, The connecting member is coupled to the hollow of the ridge formed on the lower surface of the nutrient solution cultivation port located in the upper portion and the nutrient solution supply pipe is located at the upper end of the ridge, and the cover is formed in the radial direction at the lower end of the nutrient solution supply pipe Nutrient cultivation port assembly. The method of claim 1, The nutrient cultivation port assembly, characterized in that it further comprises a strut passing through the hollow formed in the ridges of the nutrient cultivation port and the connecting member located in the yarn of the nutrient cultivation ports. The method of claim 1, An end portion of the ridge portion is coupled to the lower end of the connecting member and its nutrient solution cultivation port assembly, characterized in that the medicinal inlet formed with a groove in the nutrient solution longitudinal direction. It is stacked on top of each other, the upper part is open, the storage height of the nutrient solution in the central portion, the upper and lower strait body including a ridge having a hollow, and the nutrient solution cultivation is installed at a predetermined interval on the outer peripheral surface of the main body Nutrient cultivation ports including support wings supported on the body of the pot, A connecting member having a nutrient solution supply pipe positioned between the stacked nutrient solution cultivation ports and having an upper end coupled to a hollow of the nutrient solution cultivation port located above, and a cover formed radially at an end of the nutrient solution supply pipe; It is combined with the ridge of the nutrient solution cultivation port located at the bottom and corresponding to the lower end of the nutrient solution supply pipe to combine the nutrient solution supply pipe and the ridge, the first groove is formed on the outer peripheral surface to form the inflow passage of the nutrient solution, the inner peripheral surface And a packing member having a second groove formed therein to form a discharge passage of the nutrient solution in the longitudinal direction thereof.

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