KR102487658B1 - Irrigation management system for smart seedling production - Google Patents

Abstract

The present invention relates to a smart seedling production irrigation management system capable of uniformly cultivating plants through monitoring the growth rate of plants planted in a nursery plate in real time and managing irrigation at a suitable fixed time.

Description

Smart seedling production irrigation management system {IRRIGATION MANAGEMENT SYSTEM FOR SMART SEEDLING PRODUCTION}

The present invention relates to a smart seedling production irrigation management system capable of uniformly cultivating plants through quantitative and regular irrigation management according to the growth rate of plants planted on a seedling board.

Recently, as plant factory research has been actively conducted as an alternative to the deterioration of the agricultural environment such as extreme weather and the demand for future agricultural technology, securing economic feasibility such as initial investment and operating costs has become an important requirement.

To this end, interest in the advancement of plant factory-related element technologies and the preoccupation of high value-added technologies through research on the basic technology for stable production of plants is increasing.

For example, among plant production technologies, the seedling process refers to all processes in which seeds are sown and then grown into young plants suitable for transplanting to the main cultivation site.

However, the conventional mass-produced seedling process system mainly controls only the generalized environment such as temperature, humidity, and light intensity. On the other hand, irrigation systems are often operated as non-regular and non-quantified systems.

That is, in the prior art, there are problems such as wasting water resources or irrigation less than an appropriate value due to inaccurate prediction as irrigation is performed by predicting the amount of evapotranspiration based on the meteorological environment. Accordingly, a fixed-time irrigation management system is required for mass production of uniform seedlings.

Republic of Korea Patent Registration No. 10-0846523 (Announcement date: 2008.07.17.)

The present invention has been made to solve the above-mentioned problems, and the growth rate of plants planted on the seedling plate is observed in real time, and smart seedling production irrigation is performed so that plants can be grown uniformly through irrigation management at the right quantity and time. Its purpose is to provide a management system.

The smart seedling production irrigation management system according to the present invention for realizing the above object is an irrigation tray having an upper side open and having a receiving space so that water can be stored therein; a seedling board seated in the opening and provided with a planting groove having an inlet hole formed at the bottom so as to be supplied with water stored in the receiving space; an irrigation unit supplying or recovering water in the accommodation space; a measuring unit measuring various information including the amount of water stored in the receiving space of the irrigation tray, the fresh water time, and the growth rate of plants planted on the seedling board; and a control unit which determines whether the measurement value measured through the measurement unit is the same as a standard value necessary for the growth of the plant, and then controls the irrigation unit according to the standard value.

In this case, the irrigation tray may be installed in multiple stages on the body frame.

In addition, the irrigation unit, a water tank in which water is stored; and a pump connected to the water tank and the irrigation tray via a connecting pipe to supply the water stored in the water tank to the accommodation space or to return the water stored in the water tank to the water tank.

In addition, the connection pipe, a first line connected to the lower part of the water tank and the pump; a second line connected to the pump and the pipe connector at the lower part of the irrigation tray to accommodate the water supplied through the first line in the accommodation space or to recover the water stored in the accommodation space; and a third line connected to the pump and an upper part of the water tank to store the water collected through the second line in the water tank.

In addition, the pipe connector, one side is fitted into the coupling hole of the irrigation tray, a thread is formed on the outer peripheral surface of the one side, the connector body formed in a tube shape so that the second line can be inserted therein; and a fixing nut fitted into the coupling hole and fastened to a screw thread of the connector body protruding into the receiving space to fix the connector body, wherein a plurality of incisions are made along an axial direction on an outer circumference of one side of the connector body. Grooves are spaced apart, and a plurality of barbs protrude from an inner circumferential surface of one side of the connector body, so that when the fixing nut is fastened, the barbs pressurize and fix the outer circumferential surface of the second line.

In addition, the measuring unit may include a water level measuring sensor installed inside the irrigation tray to measure the water level stored in the receiving space.

In addition, the measurement unit may include a weight sensor installed on the lower surface of the irrigation tray to measure the weight of the irrigation tray.

In addition, one side of the irrigation tray may further include an overflow pipe for discharging the water stored in the receiving space to the outside when the water level is higher than a predetermined water level.

In addition, the inside of the irrigation tray may further include a spray nozzle cartridge for spraying water toward the inlet hole of the seedling plate.

In addition, the irrigation tray may further include a bubble generating cartridge for generating bubbles in the water stored in the receiving space.

In addition, an upper irrigation supply cartridge for supplying water to the receiving space or the seedling plate is provided on the upper side of the irrigation tray.

In addition, the watering tray may further include a mesh plate disposed in contact with the lower surface of the seedling plate to prevent the roots of plants planted in the seedling plate from growing out of the inlet hole. .

In addition, the mesh plate may be formed of a copper material.

The smart seedling production irrigation management system according to the present invention having the above configuration observes the growth rate of plants planted on the seedling plate of the irrigation tray in real time through the measuring unit, and cultivates the plants through irrigation management at the right time. can do.

In particular, the present invention can promote uniformity of plant growth by managing the same seedling process on one system time walk and matching the irrigation time for each seedling process.

In addition, by securing the relationship between the weight of the plant and the growth state, it is possible to immediately reflect changes in supply factors such as irrigation speed and watering interval, thereby improving plant cultivation efficiency.

1 is a schematic configuration diagram showing the configuration of a smart seedling production irrigation management system according to the present invention;
2 is a schematic configuration diagram showing a configuration in which the irrigation tray according to the present invention is applied in multiple stages;
Figure 3 is a detailed view of 'A' part of Figure 1;
4 is a detailed view of part 'B' of FIG. 1;
5a to 5d are examples in which cartridges for various functions can be selectively applied according to the characteristics of plants to be grown.

Hereinafter, the configuration and operation of specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Here, in adding reference numerals to the components of each drawing, it should be noted that the same components are marked with the same numerals as much as possible, even if they are displayed on different drawings.

1 is a schematic diagram showing the configuration of a smart seedling production irrigation management system according to the present invention.

Referring to FIG. 1, the smart seedling production irrigation management system 100 according to a preferred embodiment of the present invention includes an irrigation tray 110, a seedling plate 120, an irrigation unit 130, a measuring unit 140, A controller 150 may be included.

The detailed description of the configuration of the present invention is as follows.

The irrigation tray 110 has an upper side opening 111 so that the seedling plate 120 to be described later can be seated, and a receiving space S can be provided therein so that a predetermined amount of water can be accommodated.

In this case, an overflow pipe 113 may be provided on one side of the irrigation tray 110 to discharge the water stored in the receiving space S to the outside when the water level exceeds a predetermined level.

That is, when more than necessary water is supplied into the accommodating space S of the irrigation tray 110, some of the water stored in the accommodating space S may be discharged to the outside through the overflow pipe 113. Accordingly, it is possible to limit the amount of water stored in the receiving space (S).

As shown in FIG. 2, a plurality of irrigation trays 110 may be disposed on a body frame (not shown) formed in multiple stages. Accordingly, by stacking a plurality of irrigation trays 110 spaced apart from each other at a predetermined height on the body frame, mass cultivation of plants 1 and plant cultivation efficiency can be improved. Hereinafter, in the present invention, an example of a case where a plurality of irrigation trays 110 are stacked on the body frame will be shown and described, and a detailed description of the configuration of the present invention will be described with reference to FIG. 1.

Referring back to FIG. 1, the seedling plate 120 is seated in the opening 111 of the watering tray 110, and has a plurality of planting grooves ( 121) may be provided. In this case, in the present invention, an example of a case where seedlings of plants are planted in the planting groove 121 will be shown and described.

Referring to FIG. 3 , an inlet hole 123 may be formed at the bottom of the planting groove 121 to receive water stored in the accommodation space S. That is, the seedling board 120 may receive water necessary for plant growth through the inlet hole 123 in a bottom irrigation method.

In addition, a mesh plate 125 disposed in contact with the lower surface of the seedling plate 120 may be provided on the inner lower side of the irrigation tray 110. The mesh plate 125 can pass the water supplied to the planting groove 121, but prevent the roots 1a of the plant 1 planted in the planting groove 121 from growing out of the inlet hole 123. there is.

In this case, the mesh plate 125 is preferably made of a copper (Cu) material. For reference, as the mesh plate 125 is formed of a copper material, the root 1a of the plant 1 can be resistant to bacteria due to the characteristics of the copper material.

Referring back to FIG. 1 , the irrigation unit 130 may supply water into the accommodating space S of the irrigation tray 110 or recover water stored in the accommodating space S.

Specifically, the irrigation unit 130 is connected to the water tank 131 in which water is stored, and the water tank 131 and the irrigation tray 110 are connected via a connection pipe 133, and the water stored in the water tank 131 It may include a pump 135 for supplying to the receiving space (S) or recovering the water stored in the receiving space (S) to the water tank 131.

The connection pipe 133 is connected to the first line 133a connected to the lower part of the water tank 131 and the pump 135, and to the pipe connector 136 of the pump 135 and the lower part of the irrigation tray 110, The second line 133b for storing the water supplied through the first line 133a in the receiving space S or recovering the water stored in the receiving space S, and the pump 135 and the water tank 131 It may include a third line 133c that is connected to the upper part and receives the water recovered through the second line 133b back into the water tank 131.

In this case, a solenoid valve 134 is provided in the second line 133b to selectively supply and block water.

Referring to FIG. 4, the pipe connector 136 has one side fitted into the coupling hole 115 of the irrigation tray 110, and a thread is formed on the outer circumferential surface of the one side, and a second line 133b is inserted therein. A connector body 136a formed in a tube shape may be provided.

In addition, it may include a fixing nut 136b fitted into the coupling hole 115 and fastened to the screw thread of the connector body 136a protruding into the receiving space S to fix the connector body 136a. there is.

In addition, a plurality of incision grooves 136c are spaced apart along the axial direction on the outer circumference of one side of the connector body 136a so that the outer circumference of one side of the connector body 136a can be closed. In addition, a plurality of barbs 136d may protrude from an inner circumferential surface of one side of the connector body 136a. Accordingly, when the fixing nut 136b is fastened, the barb 136d presses the outer circumferential surface of the second line 133b, thereby firmly fixing the connector body 136a.

In addition, a gasket 136e is interposed in the gap between the coupling hole 115 and the pipe connector 136 to improve watertight performance.

Referring to FIGS. 5A to 5D , the present invention may selectively apply cartridges for various functions according to the characteristics of the growing plant 1 .

For example, as shown in FIG. 5A, the configuration according to one embodiment of the smart seedling production irrigation management system 100 applied to FIGS. 1 and 2 of the present invention can be applied and used as a cartridge structure.

In another embodiment, as shown in FIG. 5B, replacement installation so that a spray nozzle cartridge 137 for spraying water toward the inlet hole 123 of the seedling plate 120 can be provided inside the irrigation tray 110 It can be. The denominator nozzle cartridge 137 may perform the irrigation process by spraying water toward the inlet hole 123 of the seedling plate 120 in a state in which water is not stored in the receiving space S.

In another embodiment, as shown in FIG. 5C, a bubble-generating cartridge 138 for generating bubbles in the water stored in the receiving space S may be provided inside the irrigation tray 110. That is, when a plurality of watering trays 110 are stacked in multiple stages on the body frame, the watering tray 110 (see FIG. 2) disposed on the top of the body frame is disposed close to the lighting of the ceiling and can be affected by temperature. there is. Accordingly, when the temperature of the water stored in the irrigation tray 110 in the uppermost compartment is higher than the standard value, the temperature of the water can be lowered by generating bubbles through the bubble generating cartridge 138. In addition, by generating bubbles in the water stored through the bubble generating cartridge 138, the amount of dissolved oxygen contained in the water can be increased.

In another embodiment, as shown in FIG. 5D, an upper irrigation supply cartridge 139 for supplying water to the accommodation space S may be provided on the inner upper side of the irrigation tray 110. That is, in the case of the irrigation tray 110, water is supplied or recovered through the coupling hole 115 on the bottom surface. Therefore, if it is necessary to irrigate from the top according to the growth characteristics of the plant 1, the upper irrigation cartridge 139 can be used.

In this case, in FIG. 5D, an example of the case where one upper irrigation supply cartridge 139 is provided on one side has been shown and described, but is not limited thereto, and a plurality of cartridges 139 installed on both sides of the irrigation tray 110 or at other specific locations It can be changed when installed.

Referring back to FIG. 1, the measuring unit 140 measures various information including the amount of water stored in the receiving space S of the irrigation tray 110, the fresh water time, and the growth rate of plants planted on the seedling plate 120. can be measured in real time.

Specifically, the measuring unit 140 may include a water level measuring sensor 141 installed at a predetermined position inside the irrigation tray 110 . Accordingly, the water level of the water stored in the receiving space S can be measured in real time through the water level measuring sensor 141 .

In addition, the measurement unit 140 may include a weight measurement sensor 143 installed on the lower surface of the irrigation tray 110. Accordingly, the weight of the irrigation tray 110 can be measured in real time through the weight measurement sensor 143 .

In addition, the measurement unit 140 may be equipped with an observation camera 145 (see FIG. 2 ) to check the growth state of the plant 1 planted on the seedling plate 120 in real time.

The control unit 150 may determine whether the measurement value measured by the measurement unit 140 is the same as the standard value necessary for the growth of the corresponding plant 1, and then control the irrigation unit 130 according to the standard value.

That is, the control unit 150 controls the irrigation unit 130 using the real-time information measured by the measuring unit 140, thereby matching the irrigation time for each seedling process of the growing target plant 1 to grow the plant 1 of can be promoted.

The control unit 150 can immediately control the irrigation unit 130 according to the growth rate and condition of the plant 1 . That is, the control unit 150 can immediately reflect changes in supply factors such as irrigation speed, interval, fresh water time, etc. by securing a relationship between the weight of the plant 1 and the growth state.

Specifically, the control unit 150 observes the growth rate of the plant 1 planted on the watering tray 110 in real time through the weight measurement sensor 143 and the observation camera 145 of the measurement unit 140, The same amount of irrigation suitable for the growing season of the plant 1 may be supplied.

In addition, it is possible to match the watering time through forced drainage of the water stored in the receiving space (S) of the irrigation tray (110).

The smart seedling production irrigation management system 100 according to the present invention configured as described above measures the growth rate of the plant 1 planted on the seedling plate 120 of the irrigation tray 110 through the measuring unit 140 in real time. , and the plant (1) can be grown through irrigation management at the right time.

In particular, the present invention manages the same seedling process on one system time walk and matches the irrigation time for each seedling process, thereby achieving uniform growth of the plant (1).

In addition, it is possible to improve the cultivation efficiency of the plant (1) by securing the relationship between the weight and the growth state of the plant (1) and immediately reflecting changes in supply factors such as irrigation speed and watering intervals.

In addition, the smart seedling production irrigation management system 100 according to the present invention is not limited to the seedling process and can be applied to differentiated cultivation.

In the above, the present invention has been shown and described with specific specific examples, but the present invention is not limited to the above-described embodiments, and various changes and modifications are possible without departing from the technical spirit of the present invention.

1: plant 1a: root
100: smart seedling production irrigation management system 110: irrigation tray
111: opening S: accommodation space
113: overflow piping 115: coupling hole
120: seedling board 121: planting home
123: inlet hole 125: mesh plate
130: irrigation unit 131: water tank
133: connector 133a: first line
133b: second line 133c: third line
134: solenoid valve 135: pump
136: pipe connector 136a: connector body
136b: fixing nut 136c: cutting groove
136d: barb 136e: gasket
137: atomizing nozzle cartridge 138: bubble generating cartridge
139: Cartridge for upper irrigation supply 140: Measuring unit
141: water level measurement sensor 143: weight measurement sensor
145: observation camera 150: control unit

Claims (13)

An irrigation tray with an open top and a receiving space for storing water therein;
a seedling board seated in the opening and provided with a planting groove having an inlet hole formed at the bottom so as to be supplied with water stored in the receiving space;
an irrigation unit supplying or recovering water in the accommodation space;
a measuring unit measuring various information including the amount of water stored in the receiving space of the irrigation tray, the fresh water time, and the growth rate of plants planted on the seedling board; and
After determining whether the measurement value measured through the measuring unit is the same as the reference value required for the growth of the plant, a control unit controlling the irrigation unit according to the reference value; includes,
The irrigation unit,
A water tank in which water is stored, and a pump connected to the water tank and the irrigation tray via a connecting pipe to supply the water stored in the water tank to a receiving space or to return the water stored in the water tank to the water tank, ,
The connector is
A first line connected to the lower portion of the water tank and the pump, and a pipe connector connected to the pump and the lower portion of the irrigation tray to accommodate water supplied through the first line in the accommodation space or water stored in the accommodation space A second line for recovering, and a third line connected to the pump and the upper part of the tank to store the water recovered through the second line in the tank,
The pipe connector,
One side is fitted into the coupling hole of the irrigation tray, a thread is formed on the outer circumferential surface of the one side, and a connector body formed in a tube shape so that the second line can be inserted therein, and is fitted into the coupling hole to accommodate the A fixing nut fastened to the thread of the connector body protruding into the space to fix the connector body, wherein a plurality of incision grooves are formed spaced apart along an axial direction on an outer circumference of one side of the connector body, and one side of the connector body A smart seedling production irrigation management system in which a plurality of barbs protrude from the inner circumferential surface, and the barbs pressurize and fix the outer circumferential surface of the second line when the fixing nut is fastened.
According to claim 1,
The irrigation tray,
A smart seedling production irrigation management system that is installed in multiple stages on the body frame.
delete delete delete According to claim 1,
The measuring unit,
A smart seedling production irrigation management system comprising a; water level measurement sensor installed inside the irrigation tray to measure the water level stored in the receiving space.
According to claim 1,
The measuring unit,
A smart seedling production irrigation management system including a weight measurement sensor installed on the bottom of the irrigation tray to measure the weight of the irrigation tray.
According to claim 1,
On one side of the irrigation tray,
Smart seedling production irrigation management system further comprising a; overflow pipe that discharges the water stored in the receiving space to the outside when the water level is higher than a predetermined level.
According to claim 1,
Inside the irrigation tray,
Smart seedling production irrigation management system further comprising a spray nozzle cartridge for spraying water toward the inlet hole of the seedling plate.
According to claim 1,
Inside the irrigation tray,
A smart seedling production irrigation management system further comprising a bubble generating cartridge that generates bubbles in the water stored in the receiving space.
According to claim 1,
On the inner upper side of the irrigation tray,
Smart seedling production irrigation management system further comprising a; upper irrigation supply cartridge for supplying water to the receiving space or the seedling plate.
According to claim 1,
Inside the irrigation tray,
A smart seedling production irrigation management system further comprising a mesh plate disposed in contact with the bottom surface of the seedling plate to prevent the roots of plants planted in the seedling plate from growing out of the inlet hole.
According to claim 12,
The mesh plate,
A smart seedling production irrigation management system that is formed of copper material.

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