KR102540853B1 - Multiple smart farm artificial intelligence integrated management system - Google Patents

Abstract

According to a number of smart farm artificial intelligence integrated management system of the present invention, a hydroponic cultivation device installed in the smart farm; Information collection unit for collecting cultivation information from the hydroponic cultivation device; and an integrated management unit for integrated management of the cultivation information collected by the information collection unit through an artificial intelligence algorithm.
The effect of the present invention is to integrate and manage the cultivation information collected by the information collection unit through artificial intelligence algorithms, thereby providing a number of smart farm artificial intelligence integrated management systems that can achieve periodic supply of consumables and smooth distribution management of harvests. can provide

Description

Multiple smart farm artificial intelligence integrated management system}

The present invention relates to a plurality of smart farm artificial intelligence integrated management system.

In general, smart farms (or plant factories), a concept introduced to maximize the production and quality of agricultural products through precise environmental control, are in the limelight as a solution to the food security crisis facing mankind. Here, the smart farm mainly controls the temperature, humidity, light amount, carbon dioxide concentration, etc. inside the greenhouse, and in the case of a farmhouse using a hydroponic cultivation method, the temperature, pH, electrical conductivity or even the concentration of individual nutrients constituting the nutrient solution is controlled.

However, growers who operate smart farms not only harvest crops through smart farms, but also manage facilities.

There was a problem in that it took a lot of time to check the various facilities and consumables consumed by the facilities one by one.

In particular, in adjusting the nutrient solution, as unfiltered raw water is used, it is inconvenient to have to manually adjust the nutrient solution.

In addition, in distributing the harvested product, it was difficult to ensure smooth distribution because the distribution amount could not be confirmed, and there was a problem in that the undistributed harvested product was discarded.

Republic of Korea Patent Publication 10-2018-0076766

An object of the present invention, which has been devised to solve the above problems, is to integrate and manage the cultivation information collected by the information collection unit through an artificial intelligence algorithm, so that periodic supply of consumables and smooth distribution management of harvests can be achieved. It is to provide a number of smart farm artificial intelligence integrated management systems.

According to a plurality of smart farm artificial intelligence integrated management system of the present invention for achieving the above object, a hydroponic cultivation device installed in a smart farm; Information collection unit for collecting cultivation information from the hydroponic cultivation device; and an integrated management unit for integrated management of the cultivation information collected by the information collection unit through an artificial intelligence algorithm.

In addition, the integrated management unit transmits consumable information of consumables necessary for crops grown through the hydroponic cultivation device to the grower terminal of the grower who grows crops with the hydroponic cultivation device and to the integrated manager terminal that manages the integrated management unit to supply consumables. management, and the consumable information includes one or more of seeds, rock wool, plant pots, nutrient solutions, and filter information.

In addition, the hydroponic cultivation device is installed in a smart farm pre-installed in different regions, and the crops grown from the hydroponic cultivation device, the yield of the crop harvested from the crop, and the cultivation including distribution center information through which the harvest is distributed a first input unit for receiving information; And a second input unit that is already provided in the distribution center and receives order information including required crops and an order amount of the crops; further comprising, wherein the integrated management unit is a first input unit of the hydroponic cultivation device installed in each region. Based on the cultivation information input from and the order information input from the second input unit installed in the distribution center, the hydroponic cultivation device harvested more than the order amount is supplied to the distribution center with more orders than the harvest amount. It is characterized by analysis and management.

In addition, the hydroponic cultivation apparatus, a cultivation room equipped with a door; an air conditioning unit for circulating air in the cultivation room; a frame unit installed inside the cultivation chamber; A bed part provided in the frame part; A filter part filtering raw water; A water purification tank storing purified water filtered by the filter part; A nutrient solution storage part storing a plurality of nutrient solutions, respectively; and a mixing unit for preparing a mixture by mixing the purified water and the nutrient solution, vaporizing the mixture to generate fog, and then supplying the fog to the bed unit.

In addition, the filter unit includes a sediment filter for filtering precipitates of raw water supplied to the outside; a carbon activated carbon filter for filtering adsorbates of the raw water; an RO filter for filtering micron substances; and a DI filter for filtering salt.

In addition, the mixing unit includes a measuring unit for measuring the EC value and the pH value of the mixture, and the hydroponic cultivation apparatus is such that the EC value and the pH value of the mixture measured by the measuring unit match a preset set value It further includes a; control unit for controlling the nutrient solution storage unit and the purified water tank so that the nutrient solution and purified water are supplied.

In addition, the bed portion, a bed in which an inlet into which the fog is introduced is formed on one side and an outlet through which the mixture in which the fog is liquefied is discharged on the other side; cover; And a humidity measurement unit provided inside the bed to measure humidity; including, the hydroponic cultivation apparatus, a control unit for controlling the amount of fog introduced into the bed through the humidity inside the bed measured by the humidity measurement unit; more includes

In addition, the bed unit includes: a fog transfer pipe connected to the mixing unit and transporting fog; a fog branch pipe branched from the fog conveyor pipe and connected to the inlet of the bed; provided in the fog branch pipe to control the transport of the fog; It further includes a fog supply valve for opening and closing the fog branch pipe so that the fog branch pipe is opened and closed, and the control unit controls the fog supply valve so that the humidity value inside the bed is maintained at a preset humidity value.

In addition, the plant or seed to be planted in the port is packaged, and the packaged plant or seed is printed on the outside of the barcode where the set value of the mixture required for hydroponic cultivation is stored; further comprising, the hydroponic cultivation device, It may further include a recognition unit recognizing the barcode, wherein the control unit resets the preset setting value according to barcode information recognized by the recognition unit.

The frame unit and the bed are coupled to each other, and the bed is replaced, a coupling unit that can be separated from the frame unit; further including, wherein the coupling unit includes: a first plate having an upper surface on a lower surface of the frame unit; A second plate having an upper side provided on the lower side of the bed and facing the first plate; A first rotation pin provided rotatably along the first plate between the first plate and the frame portion; A second rotation pin rotatably provided along the second plate between the two plates and the bed, and when the first rotation pin and the second rotation pin are rotated, a portion of the first rotation pin It is inserted between the second plate and the bed, a part of the second rotation pin is inserted between the first plate and the frame unit, and the bed is coupled to the frame unit by the first rotation pin and the second rotation pin. It is characterized in that the sea bed can be separated.

As described above, the effect of the present invention is a number of smart farm artificial intelligence types that can achieve periodic supply of consumables and smooth distribution management for harvests by integrating and managing the cultivation information collected by the information collection unit through artificial intelligence algorithms. An integrated management system can be provided.

1 is a configuration diagram showing a plurality of smart farm artificial intelligence integrated management system according to a preferred embodiment of the present invention.
Figure 2 is a perspective view showing a hydroponic cultivation device of a plurality of smart farm artificial intelligence integrated management system according to a preferred embodiment of the present invention.
Figure 3 is a perspective view showing the inside of the hydroponic cultivation device of a plurality of smart farm artificial intelligence integrated management system according to a preferred embodiment of the present invention.
Figure 4 is a side view showing a hydroponic cultivation device of a plurality of smart farm artificial intelligence integrated management system according to a preferred embodiment of the present invention.
Figure 5 is a schematic diagram showing a hydroponic cultivation device of a plurality of smart farm artificial intelligence integrated management system according to a preferred embodiment of the present invention.
Figure 6 is a cross-sectional view showing the bed portion of a plurality of smart farm artificial intelligence integrated management system according to a preferred embodiment of the present invention.
Figure 7 is a bottom view showing the bed portion of a plurality of smart farm artificial intelligence integrated management system according to a preferred embodiment of the present invention.
8 and 9 are exploded perspective views showing the coupling portion of the modular hydroponic cultivation device according to a preferred embodiment of the present invention.
Figure 10 is a cross-sectional view showing the coupling portion of the modular hydroponic cultivation device according to a preferred embodiment of the present invention.
Figure 11 is a plan view showing the locking and release of the coupling portion of the modular hydroponic cultivation device according to a preferred embodiment of the present invention.

Advantages and features of the present invention, and methods of achieving them, will become clear with reference to the detailed description of the following embodiments taken in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only these embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention belongs. It is provided to completely inform the person who has the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numbers designate like elements throughout the specification.

Hereinafter, the present invention will be described with reference to drawings for explaining a plurality of smart farm artificial intelligence integrated management systems according to embodiments of the present invention.

1 to 7, a plurality of smart farm artificial intelligence integrated management system according to the present invention includes a hydroponic cultivation device 110, an information collection unit 120 and an integrated management unit 130.

First, the hydroponic cultivation device 110 is installed in a smart farm. At this time, smart farms are already installed in different regions. That is, the hydroponic cultivation apparatus 110 is also installed in different regions.

In addition, the hydroponic cultivation device 110 may be installed in multiple numbers inside one smart farm. Also, in the plurality of hydroponic cultivation devices 110, different crops may be grown or the same crops may be grown.

The information collection unit 120 may collect cultivation information from the hydroponic cultivation device 110 .

At this time, the cultivation information collected by the information collection unit 120 may include the amount of nutrient solution and flow rate information of raw water supplied to filter the raw water. In addition, the cultivation information is obtained by measuring the temperature, humidity, carbon dioxide, volatile organic compounds (VOC), etc. of the cultivation room 10 of the hydroponic cultivation device 110 with an air quality sensor when crops are grown with the hydroponic cultivation device 110. Air quality measurement information may be further included.

The integrated management unit 130 may integrate and manage the cultivation information collected by the information collection unit 120 through an artificial intelligence algorithm. At this time, the integrated management unit 130 may perform integrated management under the control of the control unit 50 of the hydroponic cultivation apparatus 110 to be described later.

For example, the control unit 50 may collect the amount of nutrient solution used and compare it with the nutrient solution previously supplied from the integrated manager to determine whether additional nutrient solution is necessary. At this time, when the amount of the collected nutrient solution corresponds to the preset additional required amount, an additional notification signal of the nutrient solution may be generated, and the generated additional notification signal may be transmitted to the grower terminal 170 and the integrated manager terminal 160.

Here, the grower terminal 170 is a terminal of a grower who cultivates crops through the hydroponic cultivation device 110, and the integrated manager terminal 160 is a terminal of an integrated manager who manages a plurality of hydroponic cultivation devices 110. .

The integrated manager receiving the additional notification signal can supply the necessary nutrient solution to the grower through delivery. That is, the integrated management unit 130 can perform integrated management of supplying the nutrient solution to growers before the nutrient solution is exhausted through the usage of the nutrient solution.

On the other hand, the control unit 50 collects the flow rate information of the raw water supplied to filter the raw water, and when the flow rate of the raw water exceeds a predetermined flow rate value, generates a replacement notification signal for the filter unit 29, and generates The replacement notification signal may be transmitted to the grower terminal 170 and the integrated manager terminal 160. At this time, the integrated manager receiving the replacement notification signal can supply the necessary filter unit 29 to the grower through delivery or the like. That is, the integrated management unit 130 can determine the replacement time of the filter unit 29 through the raw water flow rate information and perform integrated management of supplying the filter unit 29 to growers in advance.

On the other hand, the information collection unit 120 may be provided in the hydroponic cultivation apparatus 110, it is possible to further collect consumable information. Consumables information may include any one or more of seeds, rock wool, plant pots, nutrient solution, and filter unit 29 information.

At this time, the integrated management unit 130 transmits consumable information of consumables necessary for crops grown through the hydroponic cultivation device 110 to the grower terminal 170 and integrated management unit 130 of the grower who grows crops with the hydroponic cultivation device 110. ) may be transmitted to the integrated manager terminal 160 for managing consumables.

For example, the grower may additionally order seeds, rock wool, plant pots, nutrient solution, and the filter unit 29 using the grower terminal 170 .

At this time, the integrated management unit 130 determines consumables to be additionally ordered and expected time through information on consumables additionally ordered by the grower and the order pattern, and provides order information on the consumables to the terminal 170 of the grower at the determined expected time. can Here, if the grower accepts the order information, the general manager may provide consumables according to the order information.

On the other hand, a plurality of smart farm artificial intelligence integrated management system according to the present invention may further include a first input unit 140 and a second input unit 150.

The first input unit 140 may receive cultivation information including crops grown from the hydroponic cultivation device 110, yields of crops harvested from the crops, and distribution center information where the harvested products are distributed.

The second input unit 150 may receive order information, which is already provided in the distribution center and includes required crops, order quantity of crops harvested from the crops, and distribution center information for ordering the harvested crops.

At this time, the integrated management unit 130, based on the cultivation information input from the first input unit 140 of the hydroponic cultivation device 110 installed in each region and the order information input from the second input unit 150 installed in the distribution center It is possible to analyze and distribute the harvest and order quantity so that the harvest of the hydroponic cultivation device 110 harvested more than the order quantity can be supplied to the distribution center with more orders than the harvest quantity.

For example, the yield of strawberries in the first hydroponic cultivation device 110 is 100KG, the harvest harvested in the first hydroponic cultivation device 110 is distributed to the first distribution center, and in the second hydroponic cultivation device 110 When the yield of strawberries is 50KG and the crop harvested from the second hydroponic cultivation device 110 is being distributed to the second distribution center, the order quantity of strawberries from the first distribution center is 80KG and the order quantity of strawberries from the second distribution center is 70KG In the case of, the second hydroponic cultivation device 110 is provided to the grower terminal 170 of the first hydroponic cultivation device 110 so that the harvested crop is provided to the first distribution center and the remaining 20KG is distributed to the second distribution center. Second distribution center information input through the second input unit 150 of the distribution center may be provided.

In this way, the second distribution center can secure strawberry crops by matching the order amount to the maximum, and the grower of the first hydroponic cultivation device 110 may not have crop products in stock. That is, by analyzing the harvest amount and the order amount of the integrated management unit 130, it is possible to manage the distribution of the harvested product.

On the other hand, the hydroponic cultivation device 110 includes a cultivation chamber 10, an air conditioning unit 11, a frame unit 16, a bed unit 17, a filter unit 29, a water purification tank 33, a nutrient solution storage unit ( 39), a mixing unit 40 and a control unit 50.

The cultivation chamber 10 is provided with a door, and a frame part 16, a bed part 17, etc., which will be described later, are provided therein. In addition, the cultivation room 10 may be provided with an LED module capable of supplying light necessary for hydroponic cultivation, and may be provided on top of each bed 18.

In addition, the cultivation room 10 may be made of various materials such as glass greenhouse, vinyl house, SISP panel, sandwich panel, concrete, etc., but is not limited thereto.

In addition, the cultivation room 10 may be installed according to the grower's needs or the space of the smart farm secured by the grower.

The air conditioning unit 11 may circulate air in the cultivation chamber 10 . At this time, the air conditioning unit 11 may include an air conditioner 12 , an intake fan 13 , an exhaust fan 14 , and a humidifier 15 .

The temperature of the cultivation chamber 10 can be controlled through the air conditioning unit 11 . The intake fan 13 is equipped with a HEPA filter to filter internal air circulated inside the cultivation chamber 10 or external air supplied to the inside of the cultivation chamber 10 . In addition, the inside of the cultivation room 10 can be made into a positive pressure or negative pressure environment through the intake fan 13, so that penetration of viruses and the like can be prevented.

The exhaust fan 14 may exhaust air inside the cultivation chamber 10 .

The humidifier 15 may control humidity so that a preset optimum humidity of the cultivation room 10 can be maintained.

The frame part 16 may be manufactured in a multi-stage manner so that the bed part 17 to be described later may be stacked and provided.

The bed part 17 is provided in the frame part 16 .

The bed unit 17 may further include a bed 18, a cover 21, and a humidity measuring unit 23.

The bed 18 has an inlet 19 through which fog is introduced on one side and an outlet 20 through which the mixture in which the liquefied fog is discharged is formed on the other side.

The cover 21 is coupled to the top of the bed 18, and a fixing hole 22 into which the port is inserted and fixed is formed.

The humidity measuring unit 23 is provided inside the bed 18 to measure humidity.

Here, the control unit 50 may adjust the amount of fog introduced into the bed 18 through the humidity inside the bed 18 measured by the humidity measuring unit 23 .

More specifically, the bed unit 17 may further include a fog transport pipe 24 , a fog branch pipe 25 and a fog supply valve 26 .

The fog transport pipe 24 is connected to the mixing unit 40 to transport fog.

The fog branch pipe 25 is branched from the fog transport pipe 24 and connected to the inlet 19 of the bed 18.

The fog supply valve 26 is provided in the fog branch pipe 25 to open and close the fog branch pipe 25 so as to control the transport of fog.

That is, the control unit 50 may control the fog supply valve 26 so that the humidity value inside the bed 18 is maintained at a preset humidity value. For example, when the humidity value inside the bed 18 is lower than the predetermined humidity value, the fog supply valve 26 may be completely opened to allow a large amount of fog to flow in.

In addition, the fog supply valve 26 is connected to the motor 27 and the shaft of the motor 27 so that it can operate under the control of the controller 50 and is rotatably provided inside the fog branch pipe 25. may include section 28 .

The filter unit 29 can filter raw water.

At this time, in order to filter the raw water, the filter unit 29 is a sediment filter for filtering sediment such as rust, soil, and sand of the raw water supplied to the outside, a carbon activated carbon filter for filtering adsorbed substances such as odor, taste, and color, and a reverse An RO filter for filtering 0.001 micron substances using osmotic pressure and a DI filter for filtering salt may be included.

In this way, by using purified water that has passed through a number of filters, it is possible not only to constantly prepare a nutrient solution that needs to be prepared differently according to the components contained in the raw water, but also to use a certain nutrient solution and grow a certain plant regardless of region. .

In addition, the filter unit 29 includes a raw water supply pipe 30 through which raw water is supplied from the outside, a raw water flow rate measuring unit 31 provided in the raw water supply pipe 30 and measuring the flow rate of the supplied raw water, and the raw water supply pipe 30 It may further include a raw water supply valve 32 for opening and closing.

At this time, the raw water supply valve 32 may be made of a solenoid valve, but is not limited thereto.

The purified water tank 33 stores purified water filtered by the filter unit 29 .

In this case, the purified water tank 33 may include a purified water level sensor 34 for measuring the water level of stored purified water.

Further, the control unit 50 may control the raw water supply valve 32 to close the raw water supply pipe 30 when purified water is stored up to a predetermined water level through the purified water level sensor 34 .

As a certain amount of purified water is stored in the purified water tank 33, the purified water supplied to the mixing unit 40 can be smoothly supplied.

On the other hand, the control unit 50, when the flow rate of the raw water measured by the raw water flow rate measurement unit 31 exceeds a predetermined flow rate value, generates a replacement notification signal of the filter unit 29, and sends the generated replacement notification signal The hydroponic cultivation device 110 can be transferred to the grower terminal 170 of the grower who grows crops and the integrated manager terminal 160 for integrated management of the hydroponic cultivation device 110 .

In addition, the replacement notification signal may include filter unit 29 information, location information of the cultivation room 10, and grower terminal 170 information.

Accordingly, the integrated manager terminal 160 may receive the replacement notification signal and generate order information for the filter unit 29 to be replaced through location information of the cultivation room 10 . At this time, the integrated manager can deliver the filter unit 29 to the grower after confirming the order information.

The nutrient solution storage unit 39 stores a plurality of nutrient solutions, respectively. In addition, the supply pump 46, which will be described later, can check the amount of nutrient solution supplied to the mixing unit 40.

At this time, the control unit 50 may collect the amount of nutrient solution used.

For example, the control unit 50 may collect the amount of nutrient solution used and compare it with the nutrient solution previously supplied from the integrated manager to determine whether additional nutrient solution is necessary. At this time, when the amount of the collected nutrient solution corresponds to the preset additional required amount, an additional notification signal of the nutrient solution may be generated, and the generated additional notification signal may be transmitted to the grower terminal 170 and the integrated manager terminal 160.

The integrated manager receiving the additional notification signal can supply the necessary nutrient solution to the grower through delivery.

Further, the additional notification signal may include nutrient solution information, location information of the cultivation chamber 10, and grower terminal 170 information.

Accordingly, the integrated manager terminal 160 may receive an additional notification signal and generate order information for necessary nutrient solution through location information of the cultivation room 10 . At this time, the integrated manager can deliver the nutrient solution to the grower after checking the order information.

The mixing unit 40 may prepare a mixture by mixing the purified water and the nutrient solution, vaporize the mixture to generate fog, and then supply the fog to the bed unit 17 .

The mixing unit 40 may include a measurement unit 41 that measures the EC value and the pH value of the mixture.

In addition, the controller 50 controls the nutrient solution storage unit 39 and the purified water tank 33 so that the nutrient solution and purified water are supplied so that the EC value and pH value of the mixture measured by the measurement unit 41 match the preset set values. can control. At this time, the preset setting value is pre-stored in the measuring unit 41 .

For example, the measuring unit 41 may include an EC sensor for measuring electrical conductivity and a pH sensor for measuring a pH value.

The EC sensor may be provided in the mixing tank of the mixing unit 40 to measure the electrical conductivity of the mixture.

In addition, the EC sensor is a sensor that indirectly measures the concentration of the nutrient solution and is an absolutely important part for supplying the nutrient solution. Electrical conductivity is defined as 'the reciprocal of the electrical resistance of a solution between parallel electrodes with a cross-sectional area of 1 cm2 and a distance of 1 cm', and the unit is expressed as S/cm (siemens). The flow of electricity in the nutrient solution is influenced by the amount of ions in the nutrient solution, and the higher the amount of ions, the easier it is to conduct electricity. A large EC value means that the amount of ions in the nutrient solution is high, and the nutrient concentration is high.

The pH sensor may be provided in the mixing tank of the mixing unit 40 to measure the pH of the mixture.

pH represents the concentration of hydrogen ions in an aqueous solution and is closely related to the absorption of nutrients, so there is an appropriate range for growth. In general, when preparing a culture solution, adjust the concentration of the nutrient solution and then slowly add an acid or alkali solution to adjust the pH. The pH sensor uses a glass electrode sensor and its measurement principle uses a phenomenon in which a potential difference in proportion to the difference occurs when there are two types of solutions with different pH on both sides of the glass thin film.

On the other hand, the hydroponic cultivation device 110 may further include a supply pump 46 provided in the purified water tank 33 and the nutrient solution storage unit 39 to supply purified water and nutrient solution to the mixing unit 40 .

In addition, the above-described mixing unit 40 may further include a mixing tank for storing purified water and nutrient solution, and a circulation pump 42 provided inside the mixing tank to circulate the purified water and nutrient solution and prepare a mixture.

At this time, the circulation pump 42 continuously circulates the mixture in the mixing tank to prevent crystallization of the nutrient solution, and can maintain the EC value and pH value of the mixture constant as a whole.

In addition, the hydroponic cultivation device 110 connects the purified water tank 33 and the mixing tank, and includes a purified water supply pipe 35 equipped with a purified water supply valve 36 capable of controlling the supply of purified water, a nutrient solution storage unit 39 and A nutrient solution supply pipe 37 connected to the mixing tank and having a nutrient solution supply valve 38 capable of controlling the supply of the nutrient solution may be further included.

In addition, the mixing unit 40 includes a mixture level sensor 43 for measuring the level of the mixture, a fog generator 44 for vaporizing the mixture and generating fog, and a fog conveying pipe for supplying the fog to the bed unit 17 ( 24) may further include a supply fan 45 for supplying.

At this time, the control unit 50, when the water level of the mixture measured by the mixture level sensor 43 is less than the preset mixture minimum water level, the purified water supply valve 36 and the nutrient solution supply valve ( 38) can be controlled to correspond to a preset set value.

On the other hand, a plurality of smart farm artificial intelligence integrated management system according to the present invention further includes a packaging unit.

In the packaging unit, plants or seeds to be planted in the pot are packaged, and a barcode storing set values of a mixture required for hydroponic cultivation of the packaged plants or seeds is printed on the outside.

At this time, the hydroponic cultivation device 110 may further include a recognition unit for recognizing the barcode.

Accordingly, the control unit 50 may reset a preset setting value according to the barcode information recognized by the recognition unit.

For example, when a grower changes crops, if the recognition unit recognizes the barcode of the packaging part in which the seeds or plants of the crop to be changed are packaged, the stored value stored in the barcode is automatically reset to the set value. Accordingly, when a grower plants a seed or plant of a crop to be changed in the port, the control unit 50 controls the nutrient solution storage unit 39 and the purified water tank 33 according to the reset set value (stored value stored in the barcode). can do.

On the other hand, a plurality of smart farm artificial intelligence integrated management system according to the present invention may further include a coupling unit (60).

The coupling part 60 couples the frame part 16 and the bed 18 to each other, and can be easily separated from the frame part 16 when the bed 18 is replaced.

For example, since the bed 18 is provided with a plurality of ports, it is easy to separate the bed 18 when replacing a cultivated plant. At this time, the frame part 16 and the bed 18 are separated through the coupling part 60, and the bed 18 can be completely separated from the frame part 16. In addition, even when the bed 18 is separated for maintenance, the separated and new bed 18 can be firmly coupled to the frame unit 16 through the coupling part 60.

Referring to FIGS. 6 to 9 , the coupling part 60 includes a first plate 70 , a second plate 80 , a first rotation pin 74 and a second rotation pin 84 .

The upper side of the first plate 70 is provided on the lower side of the frame unit 16 .

In addition, the first plate 70 has a first inner groove 71 formed in a semicircular shape on one side facing the second plate 80 to be described later, and entered in a semicircular shape on the upper side so that both ends are open A first upper insertion groove 72 is formed, and a first upper fitting protrusion 73 is formed between the first inner insertion groove 71 and the first upper insertion groove 72 .

The second plate 80, the upper side is provided on the lower side of the bed 18, doedoe is provided to face the first plate (70).

In addition, the second plate 80 has a second inner groove 81 formed in a semicircular shape on one side facing the first plate 70, inserted in a semicircular shape on the upper side, and open at both ends to the second plate 80. An upper insertion groove 82 is formed, and a second upper fitting protrusion 83 is formed between the second inner groove 81 and the second upper insertion groove 82 .

The first rotation pin 74 is rotatably provided along the first plate 70 between the first plate 70 and the frame part 16 .

In addition, the first rotation pin 74 has a semicircular first lower fitting protrusion 75 inserted into the first inner groove 71, and is spaced apart from the first lower fitting protrusion 75 to form a semicircular shape. A first rotation protrusion 76 protruding and fitted into the first upper insertion groove 72 and rotated is formed, and is formed in a semicircular shape between the first lower fitting protrusion 75 and the first rotation protrusion 76, The upper fitting protrusion 73 is rotated inside and a first lower insertion groove 77 having both ends open is formed.

The second rotation pin 84 is rotatably provided along the second plate 80 between the second plate 80 and the bed 18 .

In addition, the second rotation pin 84 has a semicircular second lower fitting protrusion 85 inserted into the second inner groove 81, and is spaced apart from the second lower fitting protrusion 85 to form a semicircular shape. A second rotation protrusion 86 protrudes and is inserted into the second upper insertion groove 82 and rotates. It is formed in a semicircular shape between the second lower fitting protrusion 85 and the second rotation protrusion 86, The upper fitting protrusion 83 is rotated inside and a second lower insertion groove 87 having both ends open is formed.

That is, when the first rotation pin 74 and the second rotation pin 84 are rotated, a part of the first rotation pin 74 is inserted between the second plate 80 and the bed 18, and the second rotation pin A portion of 84 is inserted between the first plate 70 and the frame portion 16 to prevent the frame portion 16 and the bed 18 from being separated from each other.

In other words, when the first rotation pin 74 is rotated, the first upper insertion groove 72 and the first lower insertion groove 77, both ends of which are opened, rotate the first lower fitting protrusion 75 and the first rotation. The protrusion 76 protrudes and is inserted into the second inner groove 81 and the second upper insertion groove 82, respectively, and the second rotation pin 84 can be rotated.

In addition, the second rotation pin 84 can be rotated separately.

And, when the second rotation pin 84 is rotated, the second lower fitting protrusion 85 and the second rotation protrusion are formed at one end of the second upper insertion groove 82 and the second lower insertion groove 87, both ends of which are opened. 86 protrudes and is inserted into the first inner groove 71 and the first upper insertion groove 72, respectively.

That is, the first rotation pin 74 is coupled to the first plate 70 and the second plate 80, and the second rotation pin 84 is coupled to the second plate 80 and the first plate 70. By doing so, the frame unit 16 and the bed 18 are coupled and are not separated.

In addition, each of the first plate 70 and the second plate 80 is formed with an upper holding protrusion 61 protruding from both sides.

In addition, the first rotation pin 74 and the second rotation pin 84 are formed with protruding connection portions 62 at the ends of the outer surfaces of the first rotation protrusion 76 and the second rotation protrusion 86, A lower locking protrusion 63 is formed at the end of the connecting portion 62.

Accordingly, when the lower holding protrusion 63 formed on the first plate 70 is rotated in one direction, it rotates along the outer circumferential surface of the first plate 70, and any one upper holding protrusion formed on the first plate 70 It hangs on (61) and the rotation radius is limited, and a part of the first lower fitting protrusion 75 and the first rotating protrusion 76 can be inserted into the second inner groove 81 and the second upper insertion groove 82, respectively. there is.

And, when the lower locking protrusion 63 formed on the first plate 70 is rotated in the other direction, it rotates along the outer circumferential surface of the first plate 70, and the second inner groove 81 and the second upper insertion groove ( 82) can separate the first lower fitting protrusion 75 and the first rotary protrusion 76, each part of which is inserted.

In this way, as the user easily manipulates the coupling part 60 to rotate the lower locking protrusion 63, the first rotation pin 74 and the second rotation pin 84 can be easily rotated.

Those skilled in the art to which the present invention pertains will understand that the present invention can be embodied in other specific forms without changing its technical spirit or essential features. Therefore, the embodiments described above should be understood as illustrative in all respects and not limiting. The scope of the present invention is indicated by the claims to be described later rather than the detailed description above, and all changes or modifications derived from the meaning and scope of the claims and equivalent concepts thereof are included in the scope of the present invention. should be interpreted In addition, the operation sequence of the components described in the above-described process does not necessarily have to be performed in a time-series order, and even if the execution sequence of each component and step is changed, if the gist of the present invention is satisfied, these processes will fall within the scope of the present invention. Of course you can.

110: hydroponic cultivation device 120: information collection unit
130: integrated management unit 140: first input unit
150: second input unit 160: integrated manager terminal
170: grower terminal
10: cultivation room 11: air conditioning unit
12: air conditioner 13: intake fan
14: exhaust fan 15: humidifier
16: frame part 17: bed part
18: bed 19: inlet
20: outlet 21: cover
22: fixed hole 23: humidity measuring unit
24: fog transfer pipe 25: fog branch pipe
26: fog supply valve 27: motor
28: flat part 29: filter part
30: raw water supply pipe 31: raw water flow rate measuring unit
32: raw water supply valve 33: purified water tank
34: purified water level sensor 35: purified water supply pipe
36: purified water supply valve 37: nutrient solution supply pipe
38: nutrient solution supply valve 39: nutrient solution storage unit
40: mixing unit 41: measuring unit
42: circulation pump 43: mixture level sensor
44: fog generator 45: supply fan
46: supply pump 50: control unit
60: coupling part
61: upper locking protrusion 62: connection part
63: lower protrusion 70: first plate
71: first inner groove 72: first upper insertion groove
73: first upper fitting protrusion 74: first rotation pin
75: first lower fitting protrusion 76: first rotating protrusion
77: first lower insertion groove 80: second plate
81: second inner groove 82: second upper insertion groove
83: second upper fitting protrusion 84: second rotation pin
85: second lower fitting protrusion 86: second rotating protrusion
87: second lower insertion groove

Claims (10)

Hydroponic cultivation devices installed in smart farms;
Information collection unit for collecting cultivation information from the hydroponic cultivation device; and
An integrated management unit for integrated management of the cultivation information collected by the information collection unit through an artificial intelligence algorithm;
The hydroponic cultivation device,
A bed having an inlet through which fog is introduced on one side and an outlet through which the mixture in which the fog is liquefied is discharged on the other side;
a cover coupled to an upper portion of the bed and having a fixing hole into which a port is inserted and fixed;
A bed unit including; a humidity measurement unit provided inside the bed to measure humidity; and
Through the humidity inside the bed measured by the humidity measuring unit, a control unit for adjusting the amount of fog flowing into the bed; a plurality of smart farm artificial intelligence integrated management system including.
According to claim 1,
The integrated management unit transmits consumable information of consumables required for crops grown through the hydroponic cultivation device to the grower terminal of the grower who grows crops with the hydroponic cultivation device and to the integrated manager terminal that manages the integrated management unit to manage consumables. make it possible,
The consumable information includes a plurality of smart farm artificial intelligence integrated management systems including any one or more of seeds, rock wool, plant pots, nutrient solutions, and filter information.
According to claim 2,
The hydroponic cultivation device is installed in a smart farm already installed in different areas,
A first input unit for receiving cultivation information including crops grown from the hydroponic cultivation device, yields of crops harvested from the crops, and distribution center information through which the crops are distributed; and
A second input unit that is already provided in the distribution center and receives order information including required crops and an order amount of the crops; further comprising;
The integrated management unit, based on the cultivation information input from the first input unit of the hydroponic cultivation apparatus installed in each region and the order information input from the second input unit installed in the distribution center, the harvest of the hydroponic cultivation apparatus harvested more than the order amount A number of smart farm artificial intelligence integrated management systems characterized by analyzing and managing harvest and order quantities so that they can be supplied to distribution centers with more orders.
Hydroponic cultivation devices installed in smart farms;
Information collection unit for collecting cultivation information from the hydroponic cultivation device; and
An integrated management unit for integrated management of the cultivation information collected by the information collection unit through an artificial intelligence algorithm;
The hydroponic cultivation device,
A cultivation room equipped with a door;
an air conditioning unit that circulates air in the cultivation chamber;
a frame unit installed inside the cultivation chamber;
a bed part provided in the frame part;
A filter unit for filtering raw water;
a water purification tank storing the purified water filtered by the filter unit;
Nutrient storage unit in which a plurality of nutrient solutions are stored, respectively; and
A mixing unit for preparing a mixture by mixing the purified water and the nutrient solution, vaporizing the mixture to generate fog, and then supplying the fog to the bed unit;
The bed part,
A bed having an inlet through which the fog is introduced on one side and an outlet through which the mixture in which the fog is liquefied is discharged on the other side;
a cover coupled to an upper portion of the bed and having a fixing hole into which a port is inserted and fixed; and
A humidity measuring unit provided inside the bed to measure humidity; including,
The hydroponic cultivation device, through the humidity inside the bed measured by the humidity measuring unit, a control unit for adjusting the amount of fog introduced into the bed; a plurality of smart farm artificial intelligence integrated management system further comprising.
According to claim 4,
The filter part,
A sediment filter for filtering sediments of raw water supplied to the outside;
A carbon activated carbon filter for filtering adsorbates of the raw water;
RO filter for filtering micron materials;
A number of smart farm artificial intelligence integrated management systems including; DI filter for filtering salt.
According to claim 4,
The mixing unit includes a measurement unit for measuring the EC value and the pH value of the mixture,
The hydroponic cultivation device further includes a control unit for controlling the nutrient solution storage unit and the purified water tank so that the EC value and the pH value of the mixture measured by the measuring unit match the preset set values so that the nutrient solution and purified water are supplied. A number of smart farm artificial intelligence integrated management systems.
According to claim 4,
The bed part,
a fog transfer pipe connected to the mixing unit to transport fog;
a fog branch pipe branched off from the fog transport pipe and connected to the inlet of the bed;
A plurality of smart farm artificial intelligence integrated management system further comprising; a fog supply valve provided in the fog branch pipe to open and close the fog branch pipe to control the transport of the fog.
According to claim 7,
The control unit, a plurality of smart farm artificial intelligence integrated management system, characterized in that for controlling the fog supply valve so that the humidity value inside the bed is maintained at a preset humidity value.
According to claim 7,
A packaging unit in which the plants or seeds to be planted in the port are packaged, and a barcode on the outside of which is stored a set value of a mixture required for hydroponic cultivation of the packaged plants or seeds; further comprising,
The hydroponic cultivation device further includes a recognition unit for recognizing the barcode,
The control unit, a plurality of smart farm artificial intelligence integrated management system, characterized in that for resetting the preset setting value according to the information of the barcode recognized by the recognition unit.
According to claim 7,
Further comprising: a coupling portion capable of coupling the frame portion and the bed to each other and separating the bed from the frame portion when the bed is replaced;
The coupling part,
a first plate having an upper side on a lower side of the frame unit;
a second plate having an upper surface disposed on a lower surface of the bed and facing the first plate;
a first rotation pin rotatably provided between the first plate and the frame along the first plate;
A second rotation pin rotatably provided along the second plate between the second plate and the bed; includes,
When the first rotation pin and the second rotation pin are rotated, a portion of the first rotation pin is inserted between the second plate and the bed, and a portion of the second rotation pin is inserted between the first plate and the frame portion,
The bed is coupled to the frame unit by the first rotation pin and the second rotation pin, and a number of smart farm artificial intelligence integrated management systems, characterized in that the bed can be separated if necessary.

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