KR200493903Y1 - Water tank Device for Hydroponic Cultivation - Google Patents

Abstract

A water tank device for hydroponic cultivation includes a fishbowl body formed of a transparent material, a plant cultivation part configured to be rotatably mounted on the upper part of the fishbowl body, and a plurality of potpot accommodating parts for accommodating potted plants for plant cultivation, and the fishbowl body It characterized in that it comprises a control unit for automatically adjusting the rotation speed of the plant cultivation unit based on the oxygen concentration of the water.

Description

Water tank Device for Hydroponic Cultivation

The present invention relates to a water tank, and more particularly, to a water tank device for hydroponic cultivation.

In general, a fish tank is intended to inhabit various aquatic creatures such as ornamental fish and aquatic plants therein, to provide emotional stability to those who admire it, and to provide a cozy resting space for residential and cultural life.

Most of the conventionally used fish tanks are provided for ornamental purposes and are equipped with oxygen injectors, water supply drains, lighting devices, etc. necessary for ornamental fish so that they can live for a long time.

The lighting device used in the fish tank has the purpose of observing the swimming of ornamental fish, but also includes the purpose of decoration so that it can be used as an interior accessory in the place where the fish tank is installed.

A common fish tank has a disadvantage in that it is not easy to clean because moss is often caught inside.

In order to solve this problem, Korean Utility Model Registration No. 20-0401512 relates to "a fishbowl using a light emitting diode", and uses light emitting diodes, especially blue and ultraviolet light emitting diodes, to reduce power consumption while underwater. By inhibiting the growth of bacteria and microorganisms, it is possible to prevent the water in the tank from easily decaying, and the degree of fluorescence can be controlled. At the same time, there is an advantage in that the water temperature can be controlled by using the heat generated from the light emitting diode.

However, the "fish tank using a light emitting diode" has the disadvantage that the amount of light must be increased in order to increase the water temperature, and the temperature cannot be precisely controlled, so that the fish sensitive to the surrounding environment is killed by the management member.

In addition, there are cases in which aquatic plants are placed on the upper part of the aquarium or plants are grown by placing flowerpots, which may cause a problem in that the water contained in the aquarium is easily corrupted due to contaminants in the roots of plants.

KR20-0401512Y

The present invention has been proposed to solve the technical problems as described above, and it is a hydroponic cultivation tank device that can grow plants and fish at the same time as it has a structure that can be grown hydroponically or a flowerpot can be mounted in the upper space of the fishbowl body while raising ornamental fish. provides

In addition, there is provided a water tank device for hydroponic cultivation in which water can be circulated by rotation of the plant cultivation unit.

According to an embodiment of the present invention to solve the above problems, a fishbowl body formed of a transparent material, and configured to be rotated while being mounted on the upper part of the fishbowl body, a plurality of potted accommodating parts for accommodating pots for plant cultivation are provided. A water tank apparatus for hydroponic cultivation is provided, comprising: a plant cultivation unit to do; and a control unit for automatically adjusting the rotation speed of the plant cultivation unit based on the oxygen concentration of water in the fish tank body.

In addition, in the present invention, the surface of the plurality of flowerpot accommodating parts in contact with the water accommodated in the fishbowl body is characterized in that a plurality of projections are formed.

In addition, in the present invention, the plurality of flowerpot accommodating parts is characterized in that it rotates at an individual speed according to the control of the controller.

In addition, in the present invention, it is characterized in that a plurality of protrusions are formed with different densities for each flowerpot accommodating part on the surface of the plurality of flowerpot accommodating parts in contact with water accommodated in the fishbowl body.

In addition, in the present invention, a turbidity sensor unit that senses the turbidity of the water accommodated in the fishbowl body and transmits the turbidity data to the control unit, and the water quality that supplies a certain amount of external water so that the turbidity of the water is maintained within the standard turbidity range according to the control of the control unit It is characterized in that it includes a management unit.

The proposed water tank device for hydroponic cultivation can prevent the moss from forming in the tank because water can be circulated by the rotation of the plant cultivation unit.

In addition, there is an advantage in that the rotation speed of the plant cultivation unit can be adjusted according to the oxygen concentration of water. That is, the smaller the oxygen concentration of water, the faster the rotation speed of the plant cultivation unit, so that the amount of oxygen supplied to the water can be increased.

1 is a first actual view of a water tank device for hydroponic cultivation;
Figure 2 is a second actual view of the water tank device for hydroponic cultivation
3 is a configuration diagram of a water tank device for hydroponic cultivation;
4 is a plan view of a water tank device for hydroponic cultivation;
5 is a detailed cross-sectional view of a flowerpot receiving unit;

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings in order to describe in detail enough that a person of ordinary skill in the art to which the present invention pertains can easily implement the technical idea of the present invention.

1 is a first actual view of the water tank apparatus 1 for hydroponic cultivation, FIG. 2 is a second actual view of the water tank apparatus 1 for hydroponic cultivation, and FIG. 3 is a configuration diagram of the water tank apparatus 1 for hydroponic cultivation.

The water tank apparatus 1 for hydroponic cultivation according to this embodiment includes only a simple configuration for clearly explaining the technical idea to be proposed.

1 to 3 , the water tank device 1 for hydroponic cultivation includes a fishbowl body 100 , a plant cultivation unit 200 , a filtration filter 301 , a first temperature sensor unit 331 , and a second temperature sensor unit. 332 , a third temperature sensor unit 333 and a control unit are included.

The main operation of the water tank device 1 for hydroponic cultivation configured as described above is made as follows.

The fish tank body 100 is formed of a transparent material. That is, it is preferably formed of transparent glass or plastic.

The plant cultivation unit 200 is mounted on the upper portion of the fish tank body 100 and is configured to be rotatable. The plant cultivation unit 200 may be mounted in such a way that it is fixed to the upper portion of the fish tank body 100 . Basically, the plant cultivation unit 200 is mounted through a ring on the upper part of the fishbowl body 100 so that the vertical height may be constant. That is, even if the water level of the fishbowl body 100 is lowered, it is fixed to the fishbowl body 100 by a ring to maintain a constant height.

Meanwhile, the plant cultivation unit 200 includes a plurality of flowerpot accommodating units 210 for accommodating flowerpots for plant cultivation. A detailed configuration of the plant cultivation unit 200 will be described later.

The controller may automatically adjust the rotation speed of the plant cultivation unit 200 based on the oxygen concentration of water in the fish tank body 100 . The fish tank body 100 is configured to rotate clockwise or counterclockwise under the control of the controller.

Therefore, the control unit adjusts the rotation speed of the plant cultivation unit 200 based on the oxygen concentration of water transmitted from the oxygen sensor, and the lower the oxygen concentration of water, the faster the rotation speed of the plant cultivation unit 200 is to supply oxygen to the water. amount can be increased.

That is, since some of the plurality of flowerpot accommodating units 210 of the plant cultivation unit 200 are located in water, the flow of water is rotated clockwise or counterclockwise when the plant cultivation unit 200 rotates. The control unit may periodically change the rotation direction of the plant cultivation unit 200 to increase the amount of oxygen in the water. In addition, the controller may control the rotation direction switching cycle to proceed faster as the oxygen concentration of the water decreases.

Although not shown in the drawings, the inside of the fishbowl body 100 detects the turbidity of the water contained in the fishbowl body 100 and transmits the turbidity data to the control unit, and the turbidity of the water according to the control of the control unit is in the reference turbidity range A water quality management unit for supplying a predetermined amount of external water to be maintained in the interior may be further provided. The control unit may adjust the rotation speed so that the turbidity of the water is not deteriorated by the rotation of the plant cultivation unit 200 .

The temperature sensor unit for detecting the water temperature of the fishbowl body 100 includes a first temperature sensor unit 331 disposed at the uppermost portion of the fishbowl body 100 and a second temperature sensor unit disposed lower than the first temperature sensor unit 330 . It is configured to include a sensor unit 332 and a third temperature sensor unit 333 disposed at the lowest position.

That is, when the height of the fishbowl body 100 is high, the water temperature in the upper, middle, and lower regions of the accommodated water may be different from each other. In particular, when the water is heated or cooled by the temperature control unit disposed on the bottom surface of the fishbowl body 100, a large difference in water temperature between the upper, middle, and lower regions of the accommodated water may occur. When the temperature difference between the zone, the middle zone, and the bottom zone exceeds the reference temperature difference (ΔT) range, the operating time of the temperature controller is automatically controlled.

For example, if the water temperature in the upper zone is 20 degrees Celsius, the water temperature in the lower zone is 24 degrees Celsius, and the reference temperature difference (ΔT) is set to 5 degrees - within the reference temperature difference (ΔT) range - Power is continuously supplied to the temperature controller until the average value of the water temperature in the zone, the water temperature in the middle zone, and the water temperature in the lower zone reaches the target temperature value.

For another example, if the water temperature in the upper layer area is 20 degrees Celsius, the water temperature in the lower layer area is 24 degrees Celsius, and the reference temperature difference (ΔT) is set to 3 degrees - exceeding the reference temperature difference (ΔT) range -, the control unit Control to supply power to the temperature control unit only for a predetermined time at a predetermined time interval. That is, the control unit may control the temperature controller to turn on the temperature control unit for 1 minute (TURN ON) / 4 minutes turn off (TURN OFF) every 5 minutes. At this time, the temperature control unit is repeatedly turned on (TURN ON) and turned off (TURN OFF) until the average value of the water temperature of the upper layer region, the water temperature of the middle layer region, and the water temperature of the lower layer region reaches the target temperature value.

The filtering filter 301 serves to separate an area in charge of plant cultivation and an area in which fish are active. The filtering filter 301 may be composed of a UF hollow fiber membrane filter, and blocks foreign substances from entering the plant cultivation area.

4 is a plan view of a water tank device for hydroponic cultivation, and FIG. 5 is a detailed cross-sectional view of a flowerpot accommodating part.

An operation associated with the flowerpot accommodating unit 210 and a structure thereof will be described with reference to FIGS. 4 and 5 .

The plant cultivation unit 200 includes a plurality of flowerpot accommodating units 210 for accommodating flowerpots for plant cultivation. The controller may automatically adjust the rotation speed of the plant cultivation unit 200 based on the oxygen concentration of water in the fish tank body 100 . That is, the rotating body 220 of the plant cultivation unit 200 is configured to rotate clockwise or counterclockwise according to the control of the controller.

Meanwhile, the plurality of flowerpot accommodating units 210 are also configured to rotate at individual speeds under the control of the controller.

Therefore, since the rotating body 220 of the plant cultivation unit 200 rotates clockwise or counterclockwise, each pot receiving unit 210 also rotates clockwise or counterclockwise according to the control of the control unit, so that oxygen in the water The amount to be supplied can be variably adjusted.

On the other hand, a plurality of protrusions are formed on the surface of the plurality of flowerpot accommodating parts 210 in contact with the water accommodated in the fishbowl body 100 . Therefore, when the flowerpot accommodating part 210 rotates, the contact area with water increases, so that the amount of oxygen supplied in the water is increased.

In addition, on the surface of the plurality of flowerpot accommodating parts 210 in contact with the water accommodated in the fishbowl body 100 , a plurality of protrusions are formed with different densities for each flowerpot accommodating part 210 . Accordingly, the controller may selectively operate any one or more of the plurality of flowerpot accommodating units 210 based on the amount of oxygen in the water to adjust the oxygen supply amount. That is, the controller may selectively drive any one or more of the plurality of flowerpot accommodating units 210 in consideration of the density of the protrusions, and adjust the rotational speed of the flowerpot accommodating unit 210 to adjust the oxygen supply amount.

As shown in FIG. 5 , the protrusion formed on the surface of the flowerpot accommodating part 210 may be formed in a conical shape.

Looking at the structure of the flowerpot accommodating part 210 in more detail

A fiber filter layer 215 is formed on the inner surface for accommodating the flowerpot to primarily filter foreign substances falling from the flowerpot. In addition, a main opening 213 is formed on the lower surface of the flowerpot accommodating part 210 , and water is supplied through the main opening 213 .

The frame 211 of the flowerpot accommodating part 210 is formed in a double structure, so that an empty space is formed therein, and this empty space can be supplied or discharged with water through a plurality of openings 212 formed on the outer surface. make up the structure

A tilt sensor capable of detecting the inclination of the plant cultivation unit 200 is disposed in the control unit, and the control unit detects the inclination of the plant cultivation unit 200 and then adjusts the rotation speed of each pot accommodating unit 210 to adjust the frame (211) It is possible to adjust the plant cultivation unit 200 to be horizontal while discharging the water introduced through the empty space inside.

On the other hand, a surface heating layer 214 is formed on the lower surface of the empty space of the frame 211 to control the temperature of the pot. The surface heating layer 214 is spaced apart from the fish habitat area, and is disposed above the fish habitat area, so that the effect on the fish habitat area can be minimized.

For reference, the control unit, the main motor driving unit for rotating the plant cultivation unit 200, and the auxiliary motor driving unit for rotating each flowerpot receiving unit 210 are preferably formed in a waterproof structure, and the individual positions are different from the gist of the design. Since it is not related, it may be disposed in various positions according to embodiments.

The proposed water tank device for hydroponic cultivation can prevent the moss from forming in the tank because water can be circulated by the rotation of the plant cultivation unit.

In addition, there is an advantage in that the rotation speed of the plant cultivation unit can be adjusted according to the oxygen concentration of water. That is, the smaller the oxygen concentration of water, the faster the rotation speed of the plant cultivation unit, so that the amount of oxygen supplied to the water can be increased.

As such, those skilled in the art to which the present invention pertains will understand that the present invention may be embodied in other specific forms without changing the technical spirit or essential characteristics thereof. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. The scope of the present invention is indicated by the following claims rather than the above detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention. do.

100: fish tank body
200: plant cultivation department
211: frame
213: main opening
212: opening
214: surface heating layer
215: fiber filter layer
220: rotating body
301: filtration filter
331: first temperature sensor unit
332: second temperature sensor unit
333: third temperature sensor unit

Claims (5)

Fish tank body formed of a transparent material;
a plant cultivation unit mounted on the upper part of the fish tank body and configured to be rotatable, the plant cultivation unit having a plurality of flowerpot accommodating units for accommodating flowerpots for plant cultivation; and
A control unit for automatically adjusting the rotation speed of the plant cultivation unit based on the oxygen concentration of water in the fish tank body;
The frame of each flowerpot accommodating part is formed in a double structure so that an empty space is formed therein, and the empty space forms a structure in which water is supplied or discharged through a plurality of openings formed on the outer surface,
The control unit detects the inclination of the plant cultivation unit and then adjusts the rotation speed of each pot receiving unit to discharge the water introduced into the empty space inside the frame while controlling the plant cultivation unit to be horizontal. water tank device.
According to claim 1,
A water tank apparatus for hydroponic cultivation, characterized in that a plurality of projections are formed on the surface of the plurality of flowerpot accommodating parts in contact with the water accommodated in the fishbowl body.
According to claim 1,
The plurality of flowerpot accommodating parts,
Water tank device for hydroponic cultivation, characterized in that it rotates at an individual speed under the control of the control unit.
4. The method of claim 3,
On the surfaces of the plurality of flowerpot accommodating parts in contact with water accommodated in the fishbowl body,
A water tank device for hydroponic cultivation, characterized in that a plurality of protrusions are formed with different densities for each pot receiving unit.
According to claim 1,
a turbidity sensor unit for detecting the turbidity of the water accommodated in the fishbowl body and transmitting the turbidity data to the control unit; and
The water tank apparatus for hydroponic cultivation further comprising a; water quality management unit for supplying a predetermined amount of external water so that the turbidity of the water is maintained within the reference turbidity range according to the control of the control unit.

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