KR102156965B1 - Dissolved oxygen augmenter - Google Patents

Abstract

The present invention relates to a device for increasing the amount of dissolved oxygen for supplying a nutrient solution, and more specifically, a nutrient solution, an element, water, and air are stirred together in a nutrient solution storage unit used for nutrient solution cultivation, while continuously supplying air to the nutrient solution to dissolve It relates to a dissolved oxygen amount enhancing device for supplying nutrient solution so that nutrient solution with high oxygen content can be supplied to plants.

Description

Dissolved oxygen augmenter for supplying nutrient solution

The present invention relates to a device for increasing the amount of dissolved oxygen for supplying a nutrient solution, and more specifically, a nutrient solution, an element, water, and air are stirred together in a nutrient solution storage unit used for nutrient solution cultivation, while continuously supplying air to the nutrient solution to dissolve It relates to a dissolved oxygen amount enhancing device for supplying nutrient solution so that nutrient solution with high oxygen content can be supplied to plants.

In general, the nutritional advantage of nutrient solution cultivation is that nutrients are dissolved in the culture medium in a state that can be used by plants, their supply and control can be easily controlled, and there is no risk of any toxic substances appearing. On the other hand, if nutrients are insufficient, they must be added artificially, there is no buffering effect due to a large amount of supply, and if there is insufficient air, there is a disadvantage that it will not be able to reach the plant.

In addition, in soil cultivation, the soil is loosely bound to nutrients, and the shortage is supplied by itself from the soil, and even when fertilized in a large amount, it has a buffering action, good ventilation, and the roots are fixed by the soil. Disadvantages are that the deficiency of necessary nutrients is liable to occur, nutrients are insolubilized, or the roots have to find and grow nutrients directly, and rational control of nutrients is difficult, and toxic substances are sometimes produced.

In addition to the differences in nutritional characteristics as described above, there are various differences between soil cultivation and nutrient solution cultivation. It can be seen that nutrient solution cultivation in facility horticulture has faster crop growth than soil cultivation and can be cultivated annually without the need for years of rest due to serial cultivation obstacles, and labor reduction and production increase by automation of the production system, high quality and planned production, etc. While there are many advantages, there is a problem that there is a problem that there is a high failure rate due to a lack of oxygen due to the solution of the root sphere (root) in the soil, and various physiological functions are weakened due to the decrease in the activity of root respiration.

In general, plants absorb oxygen from epidermal cells and pores and are used for mitochondria respiration, and the generated energy affects the absorption of nutrients and water. In the case of nutrient solution cultivation, as the soil is replaced with a solution, the oxygen absorbed from the rhizome pores is closed and depends on the dissolved oxygen present in the solution.At this time, the dissolved oxygen in the solution is limited, so it is not easily recovered if absorption is lost.

The difference between nutrient solution cultivation and soil cultivation is that the optimal environment of crops such as various nutrients, temperature, PH, and oxygen is artificially controlled depending on the root zone, and nutrients, moisture, temperature, and PH can be artificially controlled, but the oxygen sector is artificial. It was difficult to control and became the biggest obstacle to nutrient culture development.

In addition, in the nutrient solution used in the nutrient solution cultivation, the concentration of the nutrient solution is not constant due to poor agitation in the nutrient solution storage unit. There was also a problem that did not.

Korean Utility Model Registration No. 20-0272578 Korean Patent Registration No. 10-1348597

The present invention is a nutrient solution capable of supplying a nutrient solution with a high amount of dissolved oxygen, evenly stirring the nutrient solution, elements, water and air even if only the operation of supplying water to the nutrient solution storage unit storing the nutrient solution required for nutrient solution cultivation It is an object to provide a device for increasing the amount of dissolved oxygen for supply.

In order to achieve the above object, the present invention is located inside a nutrient solution storage unit used for nutrient solution cultivation, and one side receives water from the outside, stores it inside, and discharges it to the other side; It is located in communication with the upper part of the lower body, and one side receives air from the outside and stores it inside, and is formed in an up-down direction to form a flow path through which water discharged from the lower body moves and discharges to the upper part, and one side of the flow path There is an upper body portion formed with an air hole so that the air stored therein can naturally move toward the flow path by the pressure of the moving water; And a separator located between the upper body and the lower body so that the water and air stored in each of the insides do not mix, but a flow path hole corresponding to the flow path through which water in the lower body moves to the upper body is formed. Body portion; characterized in that it includes.

At this time, the lower body portion, a water injection portion in communication with a water supply pipe for supplying water from the outside of the nutrient solution storage portion at one side; A water storage unit for storing water supplied through the water supply pipe therein; And a water discharge part formed at the top to discharge water stored in the water storage part.

At this time, the upper body portion, an air injection portion communicating with an air supply pipe for supplying air from the outside of the nutrient solution storage portion at one side; An air storage unit for storing the air supplied through the air supply pipe therein; And the water communicated with the water discharge part to move the water discharged through the water discharge part up and down to discharge it to the upper part, and at this time, air stored in the air storage part naturally flows into one side by the pressure of the moving water. It characterized in that it consists of; a flow path formed with a hole.

In this case, the air hole is formed to protrude from one side of the flow path in the center direction, so that the inner diameter of the flow path is narrowed.

In addition, a base portion serving as a separation membrane so that air and water stored in the upper body portion and the lower body portion are not mixed; And a flow path hole formed on one side of the base part at a position corresponding to the water discharge part, and having an inner diameter corresponding to the outer diameter of the flow path so that the flow path can pass therethrough.

As can be seen from the above description, in the present invention, even if only the operation of supplying water to the nutrient solution storage unit storing the nutrient solution required for nutrient solution cultivation, the nutrient solution, elements, water and air are uniformly stirred, and the amount of dissolved oxygen There is an advantage that it can supply this high nutrient solution.

1 is a perspective view of an apparatus for increasing an amount of dissolved oxygen for supplying a nutrient solution according to an embodiment of the present invention.
2 is a cross-sectional view (AA`) of a dissolved oxygen amount enhancing apparatus for supplying a nutrient solution according to an embodiment of the present invention.
3 is a plan view of an apparatus for increasing an amount of dissolved oxygen for supplying a nutrient solution according to an embodiment of the present invention.
4 is a perspective view of a lower body according to an embodiment of the present invention.
5 is a perspective view of an upper body according to an embodiment of the present invention.
6 is a perspective view of an intermediate body according to an embodiment of the present invention.
7 is a perspective view of a flow path according to an embodiment of the present invention.
8 is a cross-sectional view (BB′) of a flow path according to an embodiment of the present invention.
9 is a state diagram of use according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily implement the present invention.

In the accompanying drawings, FIG. 1 is a perspective view of an apparatus for increasing the amount of dissolved oxygen for supplying a nutrient solution according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view (AA`) of the apparatus for increasing an amount of dissolved oxygen for supplying a nutrient solution according to an embodiment of the present invention. 3 is a plan view of an apparatus for increasing the amount of dissolved oxygen for supplying nutrient solution according to an embodiment of the present invention, FIG. 4 is a perspective view of a lower body according to an embodiment of the present invention, and FIG. 5 is an upper body part according to an embodiment of the present invention. 6 is a perspective view of an intermediate body according to an embodiment of the present invention, FIG. 7 is a perspective view of a flow path according to an embodiment of the present invention, and FIG. 8 is a cross-sectional view of a flow path according to an embodiment of the present invention (BB` ), and Figure 9 is a state diagram of use according to an embodiment of the present invention.

Referring to FIGS. 1 to 9, the apparatus 100 for increasing the amount of yonzone oxygen for supplying the nutrient solution according to the present invention is located inside the nutrient solution storage unit 200 used for nutrient solution cultivation, and one side receives water from the outside. It is located in communication with the lower body portion 110 that is stored in and discharged to the other side, and is located in communication with the upper portion of the lower body portion 110, and one side receives air from the outside and stores it inside, and is formed in the vertical direction and is formed in the lower body portion ( A flow path 133 through which water discharged from 110 moves and discharges to the upper end is formed, and an air hole is formed at one side of the flow path 133 so that the air stored therein can naturally move toward the flow path 133 by the pressure of the moving water. It is located between the upper body portion 130 and the upper body portion 130 and the lower body portion 110 with 134 formed therein, and serves as a separator so that water and air stored inside each do not mix, but the lower body portion The flow path 133 corresponding to the flow path 133 through which the water in 110 moves to the upper body portion 130 is formed, including an intermediate body portion 120 having a hole formed therein.

The device for increasing the amount of dissolved oxygen for supplying the nutrient solution 100 is located inside the nutrient solution storage unit 200 used for nutrient solution cultivation, and is stored in the nutrient solution storage unit 200 by mixing and discharging water and air supplied from the outside. As the nutrient solution, elements, water and air are naturally stirred, it is possible to solve the problem that the concentration of the nutrient solution is different depending on the position where the nutrient solution is supplied because the nutrient solution is not properly agitated. In addition, as water and air supplied from the outside are continuously supplied to the nutrient solution, the amount of dissolved oxygen in the nutrient solution, which has been a problem in the prior art, can be increased.

In the following, the configuration for exhibiting the above effects will be described in detail.

First, the device for increasing the amount of dissolved oxygen for supplying the nutrient solution 100 is largely composed of a lower body portion 110, an intermediate body portion 120, and an upper body portion 130.

First, the lower body part 110 has a water injection part 111 communicating with a water supply pipe 220 that supplies water from the outside of the nutrient solution storage part 200 on one side, and the water supply pipe 220 It is composed of a water storage unit 112 for storing the supplied water therein, and at least one or more water discharge units 113 formed at the top to discharge the water stored in the water storage unit 112.

The lower body part 110 receives water supplied from the outside and stores and discharges it. To this end, the water supply pipe 220 for supplying water from the outside passes through the nutrient solution storage unit 200 and communicates with the water injection unit 111 formed on one side of the lower body unit 110. Accordingly, water supplied from the outside moves through the water supply pipe 220 and moves to the lower body part 110 through the water injection part 111.

The water that has moved through the water injection unit 111 is stored in a storage space formed inside the lower body unit 110, and this storage space is the water storage unit 112. As water is continuously supplied even after the water is stored in the water storage unit 112, the water stored in the water storage unit 112 must be discharged. To this end, the water storage unit ( At least one water discharge part 113 is formed to discharge the water stored in 112. In an embodiment of the present invention, eight water discharge parts 113 are formed. When the baby is baby in more detail, the water discharge part 113 is formed, which is spaced at a certain distance from the upper center to discharge water at equal intervals. It enters the lower body part 110 through the water injection part 111, is stored in the water storage part 112, which is a storage space formed therein, and then through the water discharge part 113 formed on the upper part. Will be discharged.

An upper body part 130 is formed on the upper part of the lower body part 110.

The upper body part 130 has an air injection part 131 communicating with an air supply pipe 230 for supplying air from the outside of the nutrient solution storage part 200 on one side, and an air injection part 131 supplied through the air supply pipe 230. An air storage unit 132 that stores air therein, and the water discharged through the water discharge unit 113 by communicating with the water discharge unit 113 is moved up and down to discharge it to the upper end. It consists of a flow path 133 having an air hole 134 formed at one side so that air stored in the air storage unit 132 can be naturally introduced by the pressure of water.

Unlike the lower body part 110, the upper body 130 receives air from the outside and stores and discharges it. To this end, the air supply pipe 230 for supplying air from the outside passes through the nutrient solution storage unit 200 or the lid 210, and communicates with the air injection unit 131 formed on the upper surface of the upper body unit 130. do. The air that has moved through the air injector 131 is stored in the air storage unit 132, which is a storage space formed inside the upper body unit 130, and thereafter, the water discharge unit 113 of the lower body unit 110 The water discharged through) moves along the connected flow path 133 and is discharged into the nutrient solution storage unit 200. The flow path 133 is installed at a position corresponding to the water discharge part 113, is formed in an up-down direction of the upper body part 130 and protrudes upward, and at one side, the pressure generated through the movement of water As a result, an air hole 134 is formed so that air naturally stored in the air storage unit 132 can be introduced into the flow path 133.

At this time, in order for the air stored in the air storage unit 132 to flow into the flow path 133 well, the diameter of the flow path 133 must be changed. Accordingly, referring to FIG. 8, the air hole 134 is formed to protrude from one side of the flow path 133 in the center direction. At this time, the air hole 134 extends to the central portion of the flow path 133, and the end of the air hole 134 is formed to be inclined downward in the direction of water. Accordingly, the flow path 133 is formed to have a narrower inner diameter. Referring to FIG. 8, when the diameter of the flow path 133 of the portion where the air hole 134 is formed decreases in the movement of water moving from the bottom of the flow path 133 to the top, the pressure of the water passing through this portion Decreases and vice versa increases speed. This is the Venturi effect. In fluid mechanics, when the fluid flowing through the pipe meets the narrower part, the speed increases and the pressure decreases to preserve the mechanical energy.

At this time, the pressure of the air hole 134 is reduced, and the air at a relatively high pressure naturally moves toward the flow path 133 through which water moves due to a pressure difference, so that the inlet of the flow path 133 (the lower part on the drawing) ), only water is input, and only air is introduced through the air hole 134, but water and air are mixed and discharged at the outlet of the flow path 133 (the upper part of the drawing).

Accordingly, the water discharged through the flow path 133 is discharged into the nutrient solution storage unit 200 while generating bubbles. Due to this, the nutrient solution and the elements in the inside of the nutrient solution storage unit 200 are stirred.

In addition, as water is supplied, air is also supplied, so that the amount of dissolved oxygen in the nutrient solution increases, and at the same time, the amount of dissolved oxygen in the nutrient solution can be continuously increased.

The mixed nutrient solution is discharged through the nutrient solution outlet 240 formed at one side of the nutrient solution storage unit 200, and the nutrient solution is supplied to the crop through a nutrient solution providing unit (not shown) connected thereto.

Finally, an intermediate body portion 120 positioned between the lower body portion 110 and the upper body portion 130 is configured.

The intermediate body 120 is located between the upper body 130 and the lower body 110, so that air and water stored in the air storage unit 132 and the water storage unit 112 are not mixed. It is formed in a position corresponding to the base portion 121 serving as a separation membrane and the water discharge portion 113 on one side of the base portion 121, so that the flow path 133 can pass through. Consists of; a hole-shaped flow path hole 122 having an inner diameter corresponding to the outer diameter.

The base unit 121 is configured to be an independent storage space in which the water storage unit 112 and the air storage unit 132 are completely separated, and the flow path hole 122 includes the flow path 133 It communicates with the discharge part 113 and is a hole formed to pass through to protrude from the upper part of the upper body part 130.

In addition, the lower body portion 110, the intermediate body portion 120, the upper body portion at the edge portion for the coupling and airtightness of the lower body portion 110, the middle body portion 120 and the upper body portion 130 A coupling means 140 for coupling 130 into one is formed, and the coupling means 140 combines the lower body 110, the intermediate body 120, and the upper body 130 into one. Any means that can be done will be possible.

Additionally, in the case of another embodiment of the present invention, it is possible to prevent green algae if it is installed and operated in a reservoir or the like.

As described above, the present invention has been described in detail using preferred embodiments, but the scope of the present invention is not limited to specific embodiments, and should be interpreted by the appended claims. In addition, it goes without saying that various modifications can be implemented without departing from the scope and spirit of the present invention by those who have acquired ordinary knowledge in this technical field.

Dissolved oxygen increase device for supply of 100
110 Lower body
111 Water injection unit 112 Water storage unit
113 Water outlet
120 middle body
121 Base 122 Eurohole
130 upper body
131 Air injection unit 132 Air storage unit
133 Euro 134 air hole
140-coupling means
200 nutrient solution storage
210 Lid 220 Water supply pipe
230 Air supply pipe 240 Nutrient solution outlet

Claims (5)

It is located inside the nutrient solution storage unit used for nutrient solution cultivation, and one side receives water from the outside, stores it inside and discharges it to the other side;
It is located in communication with the upper part of the lower body, and one side receives air from the outside and stores it inside, and it is formed in a vertical direction to move water discharged from the lower body to form a plurality of flow paths to discharge it to the upper part. An upper body portion having an air hole formed at one side of the flow path so that air stored therein can naturally move toward the flow path by the pressure of the moving water; And
A plurality of flow path holes that are located between the upper body and the lower body and serve as a separation membrane to prevent mixing of water and air stored in each of them, but corresponding to a plurality of flow paths through which water in the lower body moves to the upper body. Is configured to include; is formed intermediate body portion;
The upper body part,
At one side, an air injection unit communicating with an air supply pipe for supplying air from the outside of the nutrient solution storage unit;
An air storage unit for storing the air supplied through the air supply pipe therein; And
An air hole in one side to allow the air stored in the air storage unit to naturally flow into the upper part by communicating with the lower body and moving the water discharged through the lower body in an up-down direction. It consists of a flow path;
The air hole is formed to protrude from one side of the flow path in a central direction so that the air hole extends to the center of the flow path, and the air hole end is formed to be inclined downward in the direction of water, so that the inner diameter of the flow path is narrowed. Dissolved oxygen increase device for supplying nutrient solution. The method of claim 1,
The lower body part,
At one side, a water injection unit in communication with a water supply pipe for supplying water from the outside of the nutrient solution storage unit;
A water storage unit for storing water supplied through the water supply pipe therein; And
At least one water discharge unit formed on the upper portion to discharge the water stored in the water storage unit; Dissolved oxygen amount enhancing device for supplying nutrient solution, characterized in that consisting of. delete delete The method of claim 1,
The intermediate body part,
A base portion serving as a separation membrane so that air and water stored in the upper body portion and the lower body portion, respectively, are not mixed; And
It is formed in a position corresponding to the water discharge portion on one side of the base portion, and has a hole-shaped passage hole having an inner diameter corresponding to the outer diameter of the passage so that the passage can pass through; Device.

Images