KR20180086862A - Control apparatus for plants - Google Patents

Abstract

Disclosed is a plant control apparatus which comprises: a main body including a cover connected to be rotable on one side; a power supply unit installed in the main body; a generation unit for collecting moisture in the air by power supplied by the power supply uit; a storage unit for storing water collected by the generation unit; a supply unit for supplying water to a pot from the storage unit; and a processor for controlling the power supply unit and the supply unit according to a preset condition. The generation unit includes: a thermoelectric device having the different temperatures on one surface and the other surface when the power is supplied; and a condensation member connected to the one surface of the thermoelectric device to transfer heat, and condensing the moisture by the transferred heat.

Description

{CONTROL APPARATUS FOR PLANTS}

The present invention relates to a plant management apparatus capable of automatically supplying water generated from moisture in the air to plants.

In general, water is essential for plant growth.

It is not easy for plants to supply water to plants periodically, although supplying a certain amount of water may help plant growth or vitality.

In particular, when a person leaves the home or workplace for a long period of time, since the water necessary for the plant is not sufficiently supplied, the plant is deficient in growth and vitality due to lack of water,

On the other hand, when water is excessively supplied to the plant, there is a problem that the root rot is rotten, and the opposing force against the growth condition of the plant is remarkably lowered.

The present invention provides a plant management apparatus capable of automatically managing plants in an optimal environment to solve the above-mentioned problems.

According to an aspect of the present invention, there is provided a plant management apparatus comprising: a main body including a cover rotatably connected to one side; A power supply unit installed in the main body; A generator for collecting moisture in the air by a power source supplied from the power source; A storage unit for storing the water collected from the generation unit; A supply part for supplying water to the pot from the storage part; And a processor for controlling the power supply unit and the supply unit according to predetermined conditions, wherein the generation unit comprises: a thermoelectric element having one side and the other side having different temperatures when the power is supplied; And a condensing member connected to one surface of the thermoelectric element to transfer heat and to condense the moisture by the transferred heat.

A first driving member connected to the other side of the cover to move up and down the cover; A second driving member installed on the main body and moving the main body; And an illuminance sensor installed on the cover to sense illuminance, wherein the power source unit comprises: a solar cell panel installed on an upper surface of the cover; And a battery installed inside the main body and storing power generated from the solar cell panel, wherein the processor includes a first driving member for adjusting a tilt of the cover according to the sensed illuminance, And at least one driving member for moving the first driving member.

A water level sensor installed in the storage unit for sensing a water level of the water; A temperature sensor installed at one side of the flowerpot to sense the temperature of the flowerpot; And a humidity sensor installed on the other side of the flowerpot to sense the humidity of the flowerpot, and the processor controls the power supply unit and the flowerpot based on at least one of the sensed water level, the sensed temperature, The supply unit can be controlled.

And a memory for storing at least one plant growth information among the name of the plant, the temperature of the plant, the amount of sunshine, the moisture, or the condition information of the soil, Can be controlled.

An operation sensor for sensing a motion of an object in the vicinity; A photographing unit installed inside the main body and photographing a plant image; And the communication unit may transmit at least one of the sensed water level, the sensed temperature, the sensed humidity, the motion of the sensed surrounding object, or the photographed plant image to the external terminal device .

Wherein the condensing member comprises: a condensing plate having one side connected to the thermoelectric element and positioned along the vertical direction; And protruding protrusions protruding from the other side of the condensing plate at predetermined intervals and arranged in a first column and a second column, wherein the protruding protrusions located in the first column and the protruding protrusions located in the second column are positioned to be shifted from each other .

Wherein the supply unit includes a water supply line for providing a path for supplying water to the pots; A valve installed in the water supply line to adjust a supply amount of the water; And a pump for providing a pumping force to supply the water through the water supply line.

As described above, the plant management apparatus according to the present invention can generate water by condensing moisture in the air by supplying electric current to the thermoelectric elements through electric power produced through solar power generation. Accordingly, the water required for the plants can be self-sufficient to reduce the inconvenience caused by the water supply of the plants, and to provide an appropriate amount of water depending on the type of plants to be grown.

Especially, when the required moisture amount or roughness is required, it can be optimized and provided according to the plant or the time when management is difficult, so that the growth of the plant can be promoted.

In addition, the user can receive the growth status of the plants through bi-directional communication with the plant management apparatus, and can check the management status of the plants, and can more conveniently and accurately monitor the growth status of the plants. Further, there is an effect that the user can control the plant management apparatus remotely, or supply water and light to plants automatically in the absence of the user.

1 is a perspective view illustrating a plant management apparatus according to an embodiment of the present invention.
2 is a side view showing the structure of a plant management apparatus according to an embodiment of the present invention.
3A is an enlarged perspective view of a condensing member of the plant management apparatus according to an embodiment of the present invention.
3B is an enlarged front view of a condensing member of the plant management apparatus according to an embodiment of the present invention.
4 is a block diagram showing a configuration of a plant management apparatus according to an embodiment of the present invention.
5 is a block diagram illustrating in detail a configuration coupled to a processor in accordance with an embodiment of the present invention.
6 is a block diagram showing in detail the configuration of the sensing unit shown in FIG.
7 is a block diagram showing in detail the structure of the database shown in Fig.

Before describing the present invention in detail, a method of describing the present specification and drawings will be described.

It is to be understood that the terminology used herein should be broadly interpreted as encompassing any and all of the terms, as well as the legal and technical interpretations of technicians skilled in the art, The appearance of the technology, and the like. In addition, some terms are arbitrarily selected by the applicant. These terms may be construed in the meaning defined herein and may be interpreted based on the general contents of this specification and the ordinary technical knowledge in the art without specific terms definition.

In addition, the same reference numerals or signs in the drawings attached to the present specification indicate components or components that perform substantially the same function. For ease of explanation and understanding, different embodiments will be described using the same reference numerals or symbols. That is, even though all of the elements having the same reference numerals are shown in the plural drawings, the plural drawings do not mean one embodiment.

Further, in the present specification and claims, terms including ordinal numbers such as "first "," second ", etc. may be used for distinguishing between elements. These ordinals are used to distinguish between identical or similar components, and the use of such ordinal numbers should not be construed as limiting the meaning of the term. For example, the components associated with such an ordinal number should not be limited in their order of use or placement order by their numbers. If necessary, each ordinal number may be used interchangeably.

As used herein, the singular forms "a", "an" and "the" include plural referents unless the context clearly dictates otherwise. In this application, the terms "comprise", "comprising" and the like are used to specify that there is a stated feature, number, step, operation, element, component, or combination thereof, But do not preclude the presence or addition of features, numbers, steps, operations, components, parts, or combinations thereof.

Further, in an embodiment of the present invention, when a part is connected to another part, this includes not only a direct connection but also an indirect connection through another medium. Also, the meaning that a part includes an element does not exclude other elements, but may include other elements, unless specifically stated otherwise.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view showing a plant management apparatus according to an embodiment of the present invention, and FIG. 2 is a side view showing the configuration of a plant management apparatus according to an embodiment of the present invention. FIG. 3A is an enlarged perspective view of a condensing member of a plant management apparatus according to an embodiment of the present invention, and FIG. 3B is an enlarged front view of a condensing member of the plant management apparatus according to an embodiment of the present invention.

The plant management apparatus according to an embodiment of the present invention may be provided to manage plants planted in pots having various shapes and designs in order to separately plant plants from the ground in various indoor or outdoor places including homes, offices, and the like.

1 and 2, a plant management apparatus 100 according to an embodiment of the present invention includes a main body 10 on which a pollen 1 planted with plants 2 is placed, A supply unit 50 for supplying water to the pollen 1 from the storage unit 40 and a supply unit 50 for supplying water from the storage unit 40 to the processor 60 ).

The body 10 may include a housing 12 and a cover 14. The housing 12 may have a hexahedron shape with an open top so as to provide space for accommodating the pollen 1. However, the housing 12 is not limited thereto as long as it can provide a space in which the pollen 1 is placed.

The cover 14 may be rotatably connected to one side of the housing 12. One side of the cover 14 is rotatably connected to the upper surface of the housing 12 through a connecting shaft (not shown), and the other side of the cover 14 is connected to the first driving member 70 It can ascend and descend. The first driving member 70 may include a driving cylinder 72 provided in the housing 12 and a cylinder rod 74 driven by the driving cylinder 72. That is, the other side of the cover 14 is connected to the cylinder rod 74, and can be moved up and down by driving the drive cylinder 72. Accordingly, the inclination of the cover 14 can be changed by driving the driving cylinder 72. [

On the other hand, a wheel 77 may be installed below the housing 12. The wheel 77 may be connected to a rotating shaft (not shown) connected to the housing so as to be rotatable, and the housing 12 may be moved by driving the second driving member 76 driving the rotating shaft.

The power supply unit 20 may include a solar panel 22 and a battery 24. The solar panel 22 may be installed on the upper surface of the cover 14. [ The electric power produced by the solar panel 22 can be stored in the battery 24 installed in the housing 12. [

Accordingly, the power supply unit 20 of the plant management apparatus 100 according to an embodiment of the present invention can produce the environmentally-friendly power by using the solar panel 22 without supplying any external power. However, the power generation method of the power supply unit 20 is not limited thereto, and power may be supplied by various methods such as a commercial power supply, a wind power generation, a dry battery, and an electrolone power reception.

The generating unit 30 may include a thermoelectric element 32, a condensing member 35, and a cooler 39. When power is supplied from the power supply unit 20, the thermoelectric elements 32 may have different temperatures on one side and the other side. Specifically, the thermoelectric element 32 uses a Peltier effect in which heat is generated or absorbed at the junction of the two metals when current flows to the junction between the semiconductor and the two metals. The amount and direction of cooling and heating can be adjusted.

That is, in the thermoelectric element 32, electrons absorbing heat energy from the periphery move to the inside of the semiconductor at the contact portion between the metal and the semiconductor charged with negative (-), and heat absorption occurs. In the contact portion between the metal and the semiconductor charged with positive (+), heat is generated by the release of the heat energy of the electrons, so that it is possible to switch to the cooling mode or the heating mode.

The condensing member 35 is connected to one surface of the thermoelectric element 32 to receive heat, and moisture in the air can be condensed by the heat transferred.

The condensing member 35 may include protrusions 351a and 351b protruding from the condensing plate 350 and the condensing plate 350.

The condensing plate 350 may be connected to the low temperature portion of the thermoelectric element 32 and may be located at the upper portion of the storage portion 40. For example, one side of the condensing plate 350 may be connected via a connecting member 34 to transfer heat from the thermoelectric element 32. The plurality of connecting members 34 may be spaced apart from the condensing plate 350 at regular intervals so that the heat of the thermoelectric elements 32 may be uniformly transmitted.

The condensing plate 350 may be disposed on the upper portion of the storage unit 40 and may be disposed upright along the vertical direction. The protrusions 351a and 351b may be spaced apart from the condensing plate 350 at predetermined intervals. The protruding protrusions 351a and 351b may be arranged in a plurality of rows perpendicular to the condensing plate 350. For example, the protrusions 351a and 351b may be provided in the first row and the second row in the condensing plate 350, and the protrusions 351a and 351b located in the first row and the second row may be formed at regular intervals Can be located.

At least one protrusion 351a located in the first row and at least one protrusion 351b located in the second row may be arranged to be offset from each other. That is, the imaginary line l _a passing through the center of the protruding protrusions 351 a located in the first row and the imaginary line l _b passing through the center of the protruding protrusions 351 _b located in the second row are positioned to be parallel to each other. Accordingly, the projecting protrusions 351a and 351b can improve the contact area with air and effectively condense moisture in the air.

The connecting member 34, the condensing plate 350, and the projecting projections 351a and 351b may be made of copper having a high thermal conductivity.

The cooler 39 may be located on the other side of the thermoelectric element 32. Here, one surface of the thermoelectric element 32 may be a low temperature portion where heat is absorbed, and the other surface of the thermoelectric element 32 may be referred to as a high temperature portion where heat is generated.

The generating unit 30 may include a heat sink 37 on the other side of the thermoelectric element 32. The heat sink 37 may be positioned between the high temperature portion of the thermoelectric element 32 and the cooler 39. The heat sink 37 is installed on the side of the heat generating part and is heat-exchanged with the outside air, so that the heat transfer of the thermoelectric element 32 can be smoothly performed. The cooler 39 supplies air to the heat sink 37 to increase the heat exchange efficiency and to prevent the thermoelectric elements 32 from being overheated.

The storage unit 40 may be a water tank having a storage space for storing the collected water from the generation unit 30. [ The storage portion 40 may be located below the condensing member 35 and water condensed by the condensing member 35 may fall into the storage portion 40 by its own weight.

The supply unit 50 plays a role of supplying water to the pollen 1 from the storage unit 40. The supply section 50 may include a water supply line 52, valves 55a and 55b, and a pump 58. [ The water supply line (52) provides a path for supplying water to the pollen (1). One end of the water supply line 52 may be connected to a lower portion of the storage unit 40 and the other end of the water supply line 52 may be connected to the upper part of the flowerpot 1 to supply water to the flowerpot 1 . The discharge port may be provided with an injection nozzle so as to evenly spray the soil of the pollen (1).

The valves 55a and 55b are installed in the water supply line 52 to adjust the supply amount of water. The pump 58 may provide a pumping force through the water supply line 52 such that water in the reservoir 40 is supplied to the pollen 1. Here, the valves 55a and 55b are located upstream and downstream of the pump 58, respectively, so that the water in the storage section 40 can be supplied to the flowerpot by opening the valves 55a and 55b.

The humidity sensor (4) is installed on one side of the pollen (1) to sense the humidity of the soil. For example, the humidity sensor 4 may be inserted into the soil to sense a change in resistance that depends on the moisture content of the soil. The higher the water content of the soil, the lower the resistance with better current flow, and the lower the water content of the soil, the less current flows.

Based on these data, a dry reference resistance value of the water content of the soil can be obtained. The humidity sensor 4 can transmit a sensing signal to the pro sensor 60 when the reference resistance value is sensed.

The temperature sensor 6 is provided on the other side of the pollen 1 and can sense the temperature around the pollen 1.

The plant management apparatus 100 according to an embodiment of the present invention may further include a light emitting unit 84. The light emitting unit 84 may be a light emitting diode (LED). The light emitting portion 84 may be located inside the housing 12 to irradiate the plant 2 with light. The processor 60 may apply a current to the light emitting portion 84 when a sensing signal of the ambient light sensor 28 or the temperature sensor 6 is received by the processor 60. [

The plant management apparatus 100 according to an embodiment of the present invention may further include a photographing unit 82. The photographing unit 82 may be located at one side of the light emitting diode so as to photograph the plant 2. The photographing unit 82 can photograph the plant 2 and generate image data. The image data may be photographed periodically or continuously. On the other hand, it can be generated as a moving image file or an image file. The generated image data may be received by the processor 60 and the processor 60 may transmit the image data to the memory 65 and stored in the memory 65. [

The plant management apparatus 100 according to an embodiment of the present invention may further include a communication unit (90 in FIG. 5). The communication unit 90 is connected to the processor 60 to transmit and receive the image data generated through the photographing unit 82. The user can display the image data through the display on the computer or the mobile terminal. Meanwhile, the communication unit 90 may input a command to the processor 60 via the user's computer or the mobile terminal. That is, the user can receive the sensed values of the image data and sensors through the communication unit 90, and management of the pollen 1 can be performed based on the processor 60 or the command value.

The plant management apparatus 100 according to an embodiment of the present invention may further include an illuminance sensor 28, a water level sensor 42, and an operation sensor 86 in addition to the sensors described above.

First, the illuminance sensor 28 may be installed on the upper surface of the cover 14, and may be located on one side of the solar cell panel 22. The illuminance sensor 28 can sense the illuminance of sunlight emitted from the sun. For example, the standard state of the illuminance may be 25 ° C and the irradiance may be 1000 W / m ^2. That is, when the illuminance sensor 28 senses the illuminance outside the error value range in the standard state, ). ≪ / RTI >

The water level sensor 42 may be installed in the storage unit 40. The water level sensor 42 can sense the water level of the collected water in the storage unit $ 0. In one example, the water level sensor 42 may include a first water level sensor 42a and a second water level sensor 42b. The first water level sensor 42a can sense the lowest water level of the collected water in the storage unit 40 and the second water level sensor 42b can sense the highest water level of the water collected in the storage unit 40. [ The processor 60 can receive the sensed sensed signals from the first level sensor 42a and the second level sensor 42b, respectively.

In addition, the motion sensor 86 may be installed inside the cover 14. Fig. The motion sensor 86 can sense motion within a certain distance from the plant 2. [ When the motion sensor 86 senses a motion within a certain distance, the processor 60 can receive the sensed sensing signal.

Hereinafter, the operation of the present invention will be described with reference to the connection structures of the processor 60 provided in the plant management apparatus 100 according to an embodiment of the present invention.

4 is a block diagram showing a configuration of a plant management apparatus according to an embodiment of the present invention. 4, the processor 60 of the plant management apparatus 100 according to an embodiment of the present invention is connected to the power source unit 20, the generation unit 30, the storage unit 40, and the supply unit 50 . The processor 60 controls the power supply unit 20 to supply power to the generator unit 30 to collect moisture in the air and controls the supply unit 50 to collect Water can be supplied to the pollen 1.

The predetermined conditions described above and the detailed configuration connected to the processor 60 will be described with reference to FIG. 5 to FIG.

FIG. 5 is a block diagram illustrating a detailed configuration of a processor connected to a processor according to an embodiment of the present invention. FIG. 6 is a detailed block diagram of the configuration of the sensing unit shown in FIG. 7 is a block diagram showing in detail the structure of the database shown in Fig.

5 to 7, the processor 60 includes driving units 70 and 75 (referred to as a driving unit) that receive a sensing signal through the illuminance sensor 28 Thereby optimizing the power generation of the solar panel 22. The processor 60 may control the first driving member 70 to change the tilt of the cover 14 to which the solar panel 22 is attached or to change the tilt of the cover 14 to which the solar panel 22 is attached when the detection signal is received from the light intensity sensor 28, And the position of the solar cell panel 22 can be moved by controlling the second driving member 75. In this way, the solar panel 22 can be optimally positioned in the standard state of the light to produce power efficiently.

On the other hand, the processor 60 controls the first driving member 70 and the second driving member 75 to control the light emitting unit 84 to transmit light to the plant 2 when the illuminance does not reach the standard state You can also investigate. The processor 60 also controls the light emitting unit 84 to emit light to the plant 2 to raise the temperature to satisfy the growth condition of the plant 2 even when a sensing signal is received from the temperature sensor 6 .

The processor 60 supplies the electric power charged in the battery 24 to the generator 30 to collect the moisture in the air and supplies the moisture to the storage unit 40 when the sensing signal is received from the humidity sensor 4. [ do. At the same time, the water in the storage part 40 can be supplied to the pots 1 by controlling the valves 55a, 55b and the pumps 58 of the supplying part 50. [

When the sensing signal is received from the water level sensor 42, the processor 60 supplies the electric power charged in the battery 24 to the generating unit 30 to collect moisture in the air, .

Specifically, the water level sensor 42 includes a first water level sensor 42a and a second water level sensor 42b. When the sensing signal is received from the first water level sensor 42a, the electric power charged in the battery 24 is supplied to the generator 30 to collect moisture, and the sensing signal is received from the second water level sensor 42b , It is possible to prevent the water in the storage unit (40) from overflowing by shutting off the power supplied to the generator (30).

The cultivation temperature condition and the plant cultivation temperature condition, the plant cultivation water condition and the plant soil condition described above can be set by the database stored in the memory 65. [ The database stores the growth condition information according to the name of the plant, and the processor can perform water supply and temperature control according to the plant conditions set through the database.

Therefore, the depth of different plant roots appears at the time when the plants shoot and grow, and at the time when the plants grow, and in the period when the fruit grows, more moisture is required. Therefore, Temperature can be provided.

The processor 60 can also store the image data of the plant 2 photographed by the photographing section 82 in the memory 65. [ The stored image data or the status information of the plant management apparatus 100 may be transmitted to the user through the communication unit 90. [

The user can receive the image data or the status information of the plant management apparatus through a computer program of the computer or a mobile application stored in the mobile terminal. The communication unit 90 may receive information from the user's computer and the mobile terminal through a separate input interface and provide the received information to the processor 60. [

Accordingly, the user can confirm the growth state of the plant in real time, and can observe the detailed view by the size of the plant, the number of the leaves, the size of the fruit, and the like. In addition, interest and interest in plant cultivation can be improved through the two-way communication of the communication unit 90.

On the other hand, when the detection signal is received from the operation sensor 86, the processor 60 may control the alarm unit 88 to generate a warning sound.

That is, since the plant management apparatus 100 according to the embodiment of the present invention utilizes the electric power produced environmentally by using the solar power generation, no external power is required, Can be managed.

In addition, water can be generated by supplying electric current to the thermoelectric element 32 through the electric power produced through the solar power generation to condense moisture in the air. Accordingly, the water required for the plants can be self-sufficient to reduce the inconvenience caused by the water supply of the plants, and to provide an appropriate amount of water depending on the type of plants to be grown. Especially, when the required moisture amount or roughness is required, it can be optimized and provided according to the plant or the time when management is difficult, so that the growth of the plant can be promoted.

In addition, the user can receive the growth state of plants through bi-directional communication with the plant management apparatus 100 to check the management state of the plant, and can more conveniently and accurately monitor the growth state of the plant. In addition, the user can remotely control the plant management apparatus 100 or automatically supply water and light to the plant when the user is absent.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the present invention.

1: Plants 2: Plants
4: Humidity sensor 6: Temperature sensor
10: main body 12: housing
14: Cover 20: Power source
22: Solar cell panel 24: Battery
30: generating portion 32: thermoelectric element
35: condensing member 37: heat sink
39: cooler 40: storage unit
42a: first water level sensor 42b: second water level sensor
50: supply part 52: water supply line
55a, 55b: valve 58: pump
60: Processor 65: Memory
70: first driving member 75: second driving member
80: sensor part 82: photographing part
84: light emitting portion 86: motion sensor
88: alarm part 100: plant management device
350: condensing plate 351a, 351b:

Claims (7)

A body including a cover rotatably connected to one side;
A power supply unit installed in the main body;
A generator for collecting moisture in the air by a power source supplied from the power source;
A storage unit for storing the water collected from the generation unit;
A supply part for supplying water to the pot from the storage part; And
And a processor for controlling the power supply unit and the supply unit according to predetermined conditions,
Wherein the generation unit comprises:
A thermoelectric element having one side and the other side having different temperatures when the power source is supplied; And
And a condensing member connected to one surface of the thermoelectric element to transfer heat and to condense the moisture by the transferred heat. The method according to claim 1,
A first driving member connected to the other side of the cover to move up and down the cover;
A second driving member installed on the main body and moving the main body; And
And an illuminance sensor provided on the cover for sensing illuminance,
The power supply unit,
A solar cell panel mounted on an upper surface of the cover; And
And a battery installed in the main body to store electric power generated from the solar cell panel,
Wherein the processor controls at least one driving member among a first driving member for adjusting a tilt of the cover or a second driving member for moving the main body according to the sensed illuminance. The method according to claim 1,
A water level sensor installed in the storage unit for sensing a water level of the water;
A temperature sensor installed at one side of the flowerpot to sense the temperature of the flowerpot; And
And a humidity sensor installed on the other side of the flowerpot to sense the humidity of the flowerpot,
Wherein the processor controls the power supply unit and the supply unit based on at least one of the sensed level, the sensed temperature, or the sensed humidity. The method of claim 3,
A memory for storing at least one plant growth information among a name of a plant, a temperature of the plant, an amount of sunshine, moisture, or soil condition information,
Wherein the processor controls the power supply unit and the supply unit based on the plant growth information. The method of claim 3,
An operation sensor for sensing a motion of an object in the vicinity;
A photographing unit installed inside the main body and photographing a plant image; And
Further comprising:
Wherein the communication unit transmits at least one of the sensed water level, the sensed temperature, the sensed humidity, the motion of the sensed surrounding object, or the photographed plant image to the external terminal device. The method according to claim 1,
Wherein the condensing member
A condensing plate having one side connected to the thermoelectric element and positioned along the vertical direction;
And protruding protrusions projecting at predetermined intervals on the other side of the condensing plate and arranged in a first row and a second row,
Wherein the projecting projections located in the first row and the projecting projections located in the second row are located shifted from each other. The method according to claim 1,
Wherein the supply unit includes:
A water supply line providing a path for supplying water to the pots;
A valve installed in the water supply line to adjust a supply amount of the water; And
And a pump for providing a pumping force to supply the water through the water supply line.

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