KR102330228B1 - Nutrient solution supply control apparatus for greenhouse - Google Patents

Abstract

The present invention relates to a nutrient solution supply control apparatus for greenhouses to efficiently control the amount of a nutrition solution supplied to plants. According to the present invention, the nutrient solution supply control apparatus comprises a nutrient supply tank, a main pipe, a plurality of distribution pipes, a nutrient solution pipe, a medium in which a plurality of plants are accommodated and are spaced apart from each other, a medium weight measuring sensor, a plurality of drainage pipes, a return pipe, a drainage reservoir, a nutrient solution tank, a nutrient solution tank weight measuring sensor, a drainage tank, and a control unit.

Description

Nutrient solution supply control apparatus for greenhouse

The present invention relates to a nutrient solution supply control device for a greenhouse, and in particular, a medium to which a nutrient solution is supplied and a plant is accommodated, a nutrient solution tank to which a nutrient solution is supplied and accommodated at the same time as the medium, and a drainage solution in which the drained solution discharged after the nutrient solution is put into the medium is accommodated It relates to a nutrient solution supply control device for a greenhouse that can efficiently control the amount of nutrient solution supplied to a medium by measuring the weight of each tank.

Facility horticulture is the continuous production of plant fruits and flowers by systematically controlling the cultivation conditions such as light, temperature, humidity and carbon dioxide in a facility. Since plants are grown inside a plant in the form of a plant or plant, it can be produced year-round, and because it is relatively less affected by external weather conditions such as weather, it has the advantage of increasing production compared to existing agricultural methods. It is expected to be able to induce technology establishment and related technology development.

In order to secure high productivity in facility horticulture and plant factories as described above, it is necessary to properly control the growth conditions of plants in a timely manner. It is required to adjust to an appropriate value according to the growth conditions of

In addition, the proper supply of nutrients and moisture in plant growth greatly affects the growth of plants and the quantity and condition of fruits. Since many methods are used to grow plants by planting and supplying a nutrient solution to the medium, proper supply of the nutrient solution to the medium is a more important factor in plant cultivation using the nutrient solution.

On the other hand, if the plant is given too much water, the growth is accelerated, the nodes are thin and the fruit is small, and if the water is too little, the overall growth is delayed. In addition, plants discharge water sucked from the roots of the plants to the leaves during photosynthesis. As the amount of insolation and leaf area increase, more water is discharged through the pores of the leaves. Accordingly, it is necessary to adjust the amount of nutrient solution supplied to the plant in consideration of the amount of moisture that the plant can absorb and discharge according to the growth period.

Therefore, in plant cultivation using a nutrient solution, the moisture content and nutrients in the root zone of the plant are controlled by changing the composition, injection timing and injection rate, injection amount, etc. of the nutrient solution. In order to control the environment of the root zone of such plants, it is necessary to set the optimal growth conditions of plants necessary for the regulation, and in order to proceed with this, it is necessary to measure the exact state of the environment.

On the other hand, in the prior art Patent Publication No. 10-1404518, by using a weight sensor to precisely measure the moisture content of the root zone of a plant, it was possible to measure the weight of the medium. Since the moisture content of the medium changes at the same time, it is difficult to accurately determine the weight of the plant and the medium by measuring the weight of the medium in which a simple plant is planted, and it is difficult to supply the nutrient solution according to the situation.

Therefore, there is a need for a nutrient solution supply control device for a greenhouse that solves the problems of the prior art.

Registered Patent Publication No. 10-1404518

The present invention was invented to solve the problems of the prior art as described above. A medium to which a nutrient solution is supplied and a plant is accommodated, a nutrient solution tank to which a nutrient solution is supplied and accommodated at the same time as the medium, and a drainage solution discharged after the nutrient solution is put into the medium. An object of the present invention is to provide a nutrient solution supply control device for a greenhouse that can efficiently control the amount of nutrient solution supplied to plants by measuring the weight of each of the received drainage tanks in real time.

In order to achieve the above object, the present invention provides a nutrient solution supply tank in which a nutrient solution is accommodated, a main pipe that receives the nutrient solution from the nutrient solution supply tank and is formed as a tube, and each end on the main pipe is connected to each other. A plurality of distribution pipes that are spaced apart and each receive the same amount of nutrient solution from the main pipe, and one end are connected on the main pipe, and receive the same amount of nutrient solution as each distribution pipe from the main pipe, each A plurality of nutrient solutions are provided, each of which is spaced apart from each other, and a nutrient solution is supplied from the other end of each of the distribution pipes, and an accommodating space is formed inside, and a plurality of plants are accommodated while being spaced apart from each other; and the medium; and a medium weight measuring sensor provided to measure the weight of the medium, and a plurality of drain pipes each having one end connected to each other spaced apart from each other on the medium and receiving drainage discharged from the medium, on the medium One end is connected and is supplied with drainage discharged from the medium, and a plurality of each is provided and each is provided with a collection tube spaced apart from each other, and the drainage is supplied from the drainage tube, an accommodating space is formed on the inside, and on the outside A drain storage tank connected with a drain discharge pipe for discharging the drained solution contained inside is connected, and the nutrient solution is supplied from the other end of the nutrient solution pipe. A nutrient solution tank provided with a measuring sensor and connected to a nutrient solution return pipe for discharging the nutrient solution contained inside to the nutrient solution supply tank, and a nutrient solution tank connected to the nutrient solution tank and provided to measure the weight of the nutrient solution tank A sensor, receiving the drainage from the other end of the recovery pipe, an accommodating space is formed inside, a second water level measuring sensor measuring the level of the received drainage is provided inside, and the drainage received inside is transferred to the drainage reservoir on the outside A drainage tank connected to a drainage return pipe for supplying, a drainage tank weight measurement sensor connected to the drainage tank and provided to measure the weight of the drainage tank, the medium weight measurement sensor, and the nutrient solution A control unit provided to be connected to a tank weight sensor, a drain tank weight sensor, a first water level sensor, and a second water level sensor to receive a signal, and to supply or block the nutrient solution supplied from the nutrient solution supply tank to the main pipe; , a pH measuring sensor and an EC measuring sensor respectively provided on the nutrient solution tank and the draining tank, a solar radiation sensor connected to the control unit, measuring solar radiation that is solar radiation energy from the sun and transmitting it to the control unit, and the nutrient solution supply A drainage circulation pipe connected between the tank and the drainage storage tank and supplying the drainage of the drainage storage tank to the nutrient solution supply tank, a sterilization unit connected to the drainage circulation pipe to sterilize the drainage, and connected on the main pipe a flow rate sensor that measures the flow rate of the nutrient solution and transmits it to the control unit; a filter connected to the main pipe and provided to filter foreign substances contained in the nutrient solution; provided on the medium; Provided is a nutrient solution supply control device for greenhouses composed of a Time Domain Reflectometry sensor that measures the moisture content and delivers it to the control unit.

The apparatus for controlling supply of nutrient solution for a greenhouse according to the present invention as described above measures the weight of each of the medium, the nutrient solution tank and the drainage tank using the medium weight measurement sensor, the nutrient solution tank weight measurement sensor, and the drainage tank weight measurement sensor, and in real time By transmitting a signal to the control unit, it is possible to efficiently control the amount and frequency of nutrient solution supplied to plants, as well as the amount of drainage, as well as efficiently control the time the drainage is discharged from the medium, enabling economical plant cultivation. There is also the advantage of facilitating plant cultivation by workers because the yield or harvest time of plants can also be grasped by changing the weight of each medium, nutrient solution tank, and drainage tank.

1 is a schematic diagram of a nutrient solution supply control device for a greenhouse according to the present invention.

Hereinafter, specific details for carrying out the present invention will be described in more detail with reference to the accompanying drawings.

Referring to FIG. 1, the nutrient solution supply control device for a greenhouse according to the present invention includes a nutrient solution supply tank 10 in which the nutrient solution is accommodated, and a main body formed by receiving the nutrient solution from the nutrient solution supply tank 10 and a tube body. A plurality of distribution pipes 14, each of which ends are connected to each other spaced apart from each other on the pipe 12 and the main pipe 12, and receives the same amount of nutrient solution from the main pipe 12, respectively, and the main pipe A nutrient solution pipe 16 having one end connected to the top of the 12 and receiving the same amount of nutrient solution as each distribution pipe 14 from the main pipe 12, and a nutrient solution from the other end of each of the distribution pipes 14 is supplied, and an accommodating space is formed inside, and a medium 20 in which a plurality of plants 18 are accommodated spaced apart from each other, and connected to the medium 20, to measure the weight of the medium 20 A plurality of drain pipes 24 provided with a medium weight measurement sensor 22, each end connected to each other spaced apart from each other on the medium 20, and receiving drainage discharged from the medium 20, and the medium ( 20), one end is connected and provided, a recovery pipe 26 that receives the drain discharged from the medium 20, and the drain is supplied from the drain pipe 24, and an accommodating space is formed on the inside, and on the outside A drainage reservoir 30 provided with a connection to a drainage discharge pipe 28 for discharging the drainage contained inside is supplied with the nutrient solution from the other end of the nutrient solution pipe 16, and an accommodating space is formed on the inside, A nutrient solution tank 36 provided with a first water level measuring sensor 32 for measuring the level of the nutrient solution, and a nutrient solution return pipe 34 for discharging the nutrient solution contained inside to the nutrient solution supply tank 10 is connected to the outside; , a nutrient solution tank weight measurement sensor 38 provided in connection with the nutrient solution tank 36 and provided to measure the weight of the nutrient solution tank 36, and receiving drainage from the other end of the recovery pipe 26, accommodated inside A possible space is formed, and a second water level measurement sensor 40 for measuring the level of the received drainage is provided on the inside, and on the outside, the drainage accommodated in the inside is supplied to the drainage reservoir 30 . A drain tank 44 having a drain return pipe 42 connected thereto, and a drain tank weight measuring sensor 46 connected to the drain tank 44 and provided to measure the weight of the drain tank 44; The medium weight measurement sensor 22, the nutrient solution tank weight measurement sensor 38, the drainage tank weight measurement sensor 46, the first water level measurement sensor 32, and the second water level measurement sensor 40 are connected to each other to transmit a signal. It is received and consists of a control unit 48 provided to supply or block the nutrient solution supplied from the nutrient solution supply tank 10 to the main pipe 12 .

First, the nutrient solution supply tank 10 in which the nutrient solution is accommodated is provided.

At this time, the nutrient solution supply tank 10 is a tank for mixing and storing the nutrient solution required for plant growth, and is provided with a pump and a valve (not shown), and the pump and valve are controlled by the control unit 48 to be described later. it will work

A main pipe 12 formed of a tube body and receiving the nutrient solution from the nutrient solution supply tank 10 is provided.

At this time, it is preferable that a flow rate measuring sensor 60 is provided on the main pipe 12 to measure the flow rate of the nutrient solution and deliver it to the control unit 48 to be described later, and thereby the distribution pipe 14 and the nutrient solution pipe ( 16), the amount of nutrient solution supplied can be precisely measured.

In addition, it is more preferable that a filter 62 capable of filtering impurities or foreign substances in the nutrient solution is provided on the main pipe 12 and used, which causes clogging of the distribution pipe 14 and the nutrient solution pipe 16 to be described later. this will be prevented.

A plurality of distribution pipes 14 are provided on the main pipe 12, each end connected to each other to be spaced apart from each other, and receiving the same amount of nutrient solution from the main pipe 12, respectively.

At this time, the distribution pipe 14 is provided in plurality and spaced apart from each other at equal intervals on the medium 20 to be described later, and the discharge amount per hour of each of the distribution pipes 14 is determined according to its inner diameter.

A nutrient solution pipe 16 having one end connected to the main pipe 12 and receiving the same amount of nutrient solution as each distribution pipe 14 from the main pipe 12 is provided.

At this time, when one nutrient solution pipe 16 is provided and used, the amount of nutrient solution discharged from one nutrient solution pipe 16 is small. Since it is difficult to measure precisely with the nutrient solution tank weight measurement sensor 38, it is preferable to use a plurality of them, and when a plurality of nutrient solution pipes 16 are provided, the value measured by the nutrient solution tank weight measurement sensor 38 will be described later. The amount of the nutrient solution discharged from one nutrient solution pipe 16 is calculated by dividing it according to the quantity of the nutrient solution pipe 16 on the controller 48 to be used.

A nutrient solution is supplied from the other end of each of the distribution pipes 14, and an accommodating space is formed inside, and a medium 20 in which a plurality of plants 18 are spaced apart from each other and accommodated is provided.

At this time, any one or two types from the group consisting of a Time Domain Reflectometry sensor 64 , a Frequency Domain Reflectometry sensor 66 , or a Tensiometer sensor 68 for measuring the moisture content of the medium 20 on the medium 20 . It is preferable that the above is provided and used, and these are delivered by measuring the moisture content on the medium 20 to the control unit 48 to be described later. For this reason, the control unit 48 can easily control the amount of supply according to the number of times of supply of the nutrient solution according to the moisture content on the medium 20 to control the amount of time and amount of drainage discharged from the medium 20 .

In addition, on the medium 20 or on the phase spaced apart from the medium 20, a temperature sensor, a humidity sensor and It may further include an insolation sensor 54, and the control unit 48 may adjust the amount of nutrient solution injected into the medium 20 by further considering one or more of temperature, humidity, insolation, and evaporation according to insolation.

A medium weight measuring sensor 22 is provided in connection with the medium 20, measuring the weight of the medium 20 and transmitting the measured value to a control unit 48 to be described later.

At this time, the medium weight measurement sensor 22 is provided on the upper portion of the medium 20 as in FIG. 1 to measure the weight of the medium 20 or is provided at the lower portion of the medium 20 in the form of a conventional scale. It may be used, and any form may be used as long as it can measure the weight of the medium 20 in real time and transmit the measured value to the control unit 48 .

On the medium 20, each end is provided to be spaced apart from each other, and a plurality of drainage pipes 24 receiving drainage discharged from the medium 20 are provided.

At this time, the drain pipe 24 is to be absorbed or evaporated from the plant 18 in the medium 20 and the remaining drainage is discharged.

One end is connected to the medium 20 , and a recovery pipe 26 for receiving drainage discharged from the medium 20 is provided.

At this time, the drain discharged through the recovery pipe 26 is supplied to a drain tank 44 to be described later, and the weight of the drain accommodated in the drain tank 44 is to a drain tank weight measurement sensor 46 to be described later. The weight is measured and the measured value is transmitted to the control unit 48, and the control unit 48 adjusts the amount of drainage by adjusting the number of times and supply of the nutrient solution through the measured value.

In addition, it is preferable that a plurality of the recovery pipe 26 is provided and used, and when one is provided and used, the discharge amount of the drain discharged from one recovery pipe 26 is small. Since it is difficult to precisely measure the weight of the drainage accommodated in the drainage tank weight measurement sensor 46 to be described later, it is preferable that a plurality of them are provided and used, and when a plurality of recovery pipes 26 are provided, the drainage tank weight measurement sensor The amount of drainage discharged from one recovery pipe 26 is calculated by dividing the value measured in (46) according to the quantity of the recovery pipe 26 on the control unit 48, which will be described later.

It receives the drainage from the drainage pipe 24, an accommodating space is formed inside, and a drainage storage tank 30 to which a drainage discharge pipe 28 for discharging the drainage accommodated inside is connected to the outside is provided.

At this time, the drainage liquid accommodated in the drainage storage tank 30 may be discharged to a sewage treatment facility, a purification facility, or the like or may be disposed of in a river after purifying pollutants, but in the present invention, the nutrient solution supply tank 10 and A drainage circulation pipe 56 for supplying the drainage of the drainage storage tank 30 to the nutrient solution supply tank 10 is connected between the drainage storage tanks 30 and provided on the drainage circulation pipe 56 to sterilize the drainage. A portion 58 may be additionally provided to sterilize the drainage, and the sterilized drainage may be mixed with the nutrient solution and supplied to the main pipe 12 again for use.

At this time, one or a plurality of lamps emitting ultraviolet rays are provided on the sterilization unit 58 , and the sterilization unit 58 sterilizes the drainage under the control of the controller 48 to be described later.

The nutrient solution is supplied from the other end of the nutrient solution pipe 16, an accommodating space is formed inside, and a first water level measurement sensor 32 for measuring the level of the received nutrient solution is provided inside, and the nutrient solution accommodated inside the outside is provided. A nutrient solution tank 36 to which a nutrient solution return pipe 34 discharged to the nutrient solution supply tank 10 is connected is provided.

At this time, the first water level measuring sensor 32 provided in the nutrient solution tank 36 measures the level of the nutrient solution inside the nutrient solution tank 36 and transmits it to the control unit 48 to be described later, and the first water level measuring sensor 32 ), when the level of the nutrient solution inside the nutrient solution tank 36 reaches a certain level, the nutrient solution is discharged to the nutrient solution supply tank 10 through the nutrient solution return pipe 34 .

In addition, a pH measuring sensor 50 and an EC measuring sensor 52 are provided on the nutrient solution tank 36, respectively, to measure the hydrogen ion concentration index (pH) and electrical conductivity of the nutrient solution, and then a control unit 48 to be described later It is preferable to deliver it to the nutrient solution, which makes it possible to easily control the mixing ratio of raw water and fertilizer in the nutrient solution.

A nutrient solution tank weight sensor 38 for measuring the weight of the nutrient solution tank 36 and connected to the nutrient solution tank 36 is provided.

At this time, the nutrient solution tank weight measurement sensor 38 is provided at the upper portion of the nutrient solution tank 36 as shown in FIG. 1 to measure the weight of the nutrient solution tank 36 or in the form of a conventional scale of the nutrient solution tank 36. It may be provided and used at the bottom, and any form may be used as long as it can measure the weight of the nutrient solution tank 36 in real time and transmit the measured value to the control unit 48 to be described later.

Drainage is supplied from the other end of the collection pipe 26, an accommodating space is formed inside, and a second water level measurement sensor 40 for measuring the level of the received drainage is provided on the inside, and the drainage accommodated inside the outside is provided. A drainage tank 44 to which the drainage return pipe 42 supplied to the drainage storage tank 30 is connected is provided.

At this time, the second water level measuring sensor 40 provided in the drainage tank 44 measures the level of the drainage inside the drainage tank 44 and transmits it to the control unit 48 to be described later, and the second water level measuring sensor 40 ), when the water level of the drainage inside the drainage tank 44 reaches a certain level, the drainage is discharged to the drainage storage tank 30 through the drainage return pipe 42 .

In addition, a pH measurement sensor 50 and an EC measurement sensor 52 are provided on the drainage tank 44, respectively, to measure the hydrogen ion concentration index (pH) and electrical conductivity of the drainage phase to measure the measured values. Control unit 48 to be described later It is preferable to deliver it to the nutrient solution, which makes it possible to easily control the mixing ratio of raw water and fertilizer in the nutrient solution.

On the other hand, the drainage discharged from the medium 20 is at least 15-40% of the amount of nutrient solution supplied in order to maintain the hydrogen ion concentration index (pH), electrical conductivity, and nutrient balance on the medium 20. it would be desirable

A drain tank weight sensor 46 is provided in connection with the drain tank 44 and measures the weight of the drain tank 44 .

At this time, the drainage tank weight measurement sensor 46 is provided on the upper portion of the drainage tank 44 as shown in FIG. 1 to measure the weight of the drainage tank 44 or to measure the weight of the drainage tank 44 in the form of a conventional scale. It may be provided and used in the lower part, and any form may be used as long as it can measure the weight of the drainage tank 44 in real time and transmit the measured value to the control unit 48 to be described later.

The medium weight measurement sensor 22, the nutrient solution tank weight measurement sensor 38, the drainage tank weight measurement sensor 46, the first water level measurement sensor 32, the second water level measurement sensor 40, the pH measurement sensor 50 ), EC measurement sensor 52, solar radiation sensor 54, flow measurement sensor 60, Time Domain Reflectometry sensor 64, Frequency Domain Reflectometry sensor 66, and Tensiometer sensor 68 are connected and provided to transmit a signal and a control unit 48 for supplying or blocking the nutrient solution supplied from the nutrient solution supply tank 10 to the main pipe 12 is provided.

At this time, the control unit 48 is provided to control valves, pumps, etc., which are conventional means for supplying or blocking fluid, and the like, thereby easily regulating the amount of supply of nutrient solution and the amount of discharge of drainage.

On the other hand, the control unit 48 includes a medium weight measurement sensor 22 , a nutrient solution tank weight measurement sensor 38 , a drainage tank weight measurement sensor 46 , a first water level measurement sensor 32 , and a second water level measurement sensor 40 . ), pH measuring sensor 50, EC measuring sensor 52, insolation sensor 54, flow measuring sensor 60, Time Domain Reflectometry sensor 64, Frequency Domain Reflectometry sensor 66 and Tensiometer sensor 68 When the measured value of Accordingly, it is possible to determine the supply amount and supply period of the nutrient solution, thereby enabling efficient management of the nutrient solution. In addition, since the nutrient solution supplied to the plants can also be given the required amount at the required time, it is possible to have excellent effects in plant growth and harvesting of fruits.

In addition, it is more preferable that the filter 62 is provided and used on the tube through which the nutrient solution or drainage solution moves.

The nutrient solution supply control device for a greenhouse according to the present invention configured in this way measures the weight of each of the medium 20, the nutrient solution tank 36 and the drain tank 44, the medium weight measurement sensor 22, the nutrient solution tank weight measurement sensor 38 , by using the drainage tank weight measurement sensor 46 and transmitting a signal to the control unit 48 in real time, it is possible not only to efficiently control the amount and frequency of nutrient solution supplied to the plant, but also the amount of drainage. The time discharged from the medium 20 can also be efficiently controlled, so there is an advantage that economical plant cultivation is possible. There is also the advantage of facilitating plant cultivation by workers because the yield or harvest time can also be easily grasped.

10: nutrient solution supply tank 12: main tube
14: distribution pipe 16: nutrient solution pipe
18: plant 20: medium
22: medium weight measurement sensor 24: drain pipe
26: recovery pipe 28: drainage discharge pipe
30: drainage storage tank 32: first water level measurement sensor
34: nutrient solution return pipe 36: nutrient solution tank
38: nutrient solution tank weight measurement sensor 40: second water level measurement sensor
42: drainage return pipe 44: drainage tank
46: drainage tank weight measurement sensor 48: control unit
50: pH measuring sensor 52: EC measuring sensor
54: solar radiation sensor 56: drainage circulation pipe
58: sterilization unit 60: flow measurement sensor
62: filter

Claims (5)

a nutrient solution supply tank 10 in which the nutrient solution is accommodated;
a main pipe 12 formed as a tube body and receiving the nutrient solution from the nutrient solution supply tank 10;
a plurality of distribution pipes 14 each having one end connected to each other spaced apart from each other on the main pipe 12 and receiving the same amount of nutrient solution from the main pipe 12;
One end is connected on the main pipe 12, and the same amount of nutrient solution is supplied from the main pipe 12 to each distribution pipe 14, and a plurality of nutrient solution pipes are provided and each is provided with a distance from each other. (16);
a medium 20 in which a nutrient solution is supplied from the other end of each of the distribution pipes 14, an accommodating space is formed inside, and a plurality of plants 18 are spaced apart from each other and accommodated;
a medium weight sensor 22 provided in connection with the medium 20 and provided to measure the weight of the medium 20;
A plurality of drainage pipes 24 each having one end connected to each other on the medium 20 and receiving drainage discharged from the medium 20;
a collection pipe 26 having one end connected to the medium 20, receiving drainage discharged from the medium 20, provided in plurality and spaced apart from each other;
Drainage storage tank 30 that receives the drainage from the drainage pipe 24, has an accommodating space formed on the inside, and is provided with a drainage discharge pipe 28 connected to the outside for discharging the drainage accommodated in the inside to the outside;
The nutrient solution is supplied from the other end of the nutrient solution tube 16, an accommodating space is formed inside, and a first water level measurement sensor 32 for measuring the level of the received nutrient solution is provided inside, and the nutrient solution accommodated inside the outside is provided. a nutrient solution tank 36 connected to a nutrient solution return pipe 34 discharged to the nutrient solution supply tank 10;
a nutrient solution tank weight sensor 38 which is connected to the nutrient solution tank 36 and is provided to measure the weight of the nutrient solution tank 36;
Drainage is supplied from the other end of the recovery pipe 26, an accommodating space is formed on the inside, and a second water level measurement sensor 40 for measuring the level of the received drainage is provided on the inside, and the drainage accommodated in the inside is provided on the outside. a drain tank 44 to which a drain return pipe 42 supplied to the drain storage tank 30 is connected;
a drainage tank weight measuring sensor 46 which is connected to the drainage tank 44 and is provided to measure the weight of the drainage tank 44;
The medium weight measurement sensor 22, the nutrient solution tank weight measurement sensor 38, the drainage tank weight measurement sensor 46, the first water level measurement sensor 32, and the second water level measurement sensor 40 are connected to each other to transmit a signal. a control unit 48 provided to supply or block the nutrient solution supplied from the nutrient solution supply tank 10 to the main pipe 12;
a pH measuring sensor 50 and an EC measuring sensor 52 respectively provided on the nutrient solution tank 36 and the drain tank 44;
a solar radiation sensor 54 connected to the control unit 48, measuring the amount of insolation, which is solar radiation energy from the sun, and transmitting it to the control unit 48;
a drainage circulation pipe 56 connected between the nutrient solution supply tank 10 and the drainage storage tank 30 and supplying the drainage solution from the drainage storage tank 30 to the nutrient solution supply tank 10;
a sterilization unit 58 connected to the drainage circulation pipe 56 to sterilize the drainage;
a flow rate sensor (60) connected to the main pipe (12), measuring the flow rate of the nutrient solution and transmitting it to the control unit (48);
a filter 62 connected to the main pipe 12 and provided to filter foreign substances contained in the nutrient solution;
a Time Domain Reflectometry sensor 64 provided on the medium 20, measuring the moisture content of the medium 20 and transmitting it to the control unit 48;
A nutrient solution supply control device for a greenhouse, characterized in that consisting of. delete delete delete delete

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