KR102374823B1 - System and method for providing internet of things based unmanned robot farm integrated marine residential tourism eco-friendly of the 4th industrial revolution using marine holdings - Google Patents

Abstract

An IoT-based unmanned robot aquaculture system according to an embodiment includes: a floating control structure constituting an IoT-based floating structure that has buoyancy to float on the water surface and controls buoyancy by inflow and outflow of seawater; a mobile robot operation rail having a robot workbench installed on the floating adjustable structure and capable of operating a robot using the installed robot workbench; and a fish farm installed under the floating control structure and raised and lowered as the inflow and outflow of seawater is controlled through the control of the floating structure configured in the floating control structure, wherein the farm system is equipped with a communication chip It is possible to automatically measure the ecological environment of the aquaculture farm through the configured communication environment, transmit and receive data with each component configured in the farm system, and communicate the transmitted/received data with a remote server.

Description

The 4th industrial revolution using maritime holdings, marine residential tourism, ecological integrated IoT, unmanned robot aquaculture farm

The description below relates to an unmanned robot farm based on the Internet of Things.

Numerous offshore farms are installed in the sea, but most offshore farms are fixed on the bottom of the sea and are installed in relatively shallow waters. In other words, red tides are mainly formed on the surface close to the water surface to block sunlight and consume oxygen in the water to kill farmed fish and fish. Similarly, even when a typhoon occurs, it is greatly affected at the sea surface, but it is hardly affected deep below the sea level, so it will be able to avoid damage from the typhoon.

However, most of the conventional marine aquaculture farms are of a fixed type and have a structure in which floating objects are installed at the sea level and a cage farm is connected to the floating objects.

As an example, Korean Patent Application Laid-Open No. 10-2011-0004967 relates to a floating offshore solar power generation system and an offshore farm using the same. A floating offshore solar power generation system that enables the raising and lowering of the farmhouse by the power obtained from the solar power generation system by installing a farm structure at the bottom, and lighting to help the seaweed growth, and an offshore farm using the same has been disclosed.

By constructing a subsea tidal generator and an upper solar power generation system using a variable fixed pile structure in the sea or the main body of an already installed offshore wind generator as a post, Solfeggio 432, 528, 963… With the Hz music wave, it is possible to provide a method and apparatus for installing robot-based fully automatic floating control food circulation ecology, tourism integrated marine aquaculture and residential pension, tanning, snorkeling underwater ecology floating control structure.

The IoT-based unmanned robot aquaculture system includes: a floating control structure constituting an IoT-based floating structure that has buoyancy to float on the water surface and controls buoyancy by inflow and outflow of seawater; a mobile robot operation rail having a robot workbench installed on the floating adjustable structure and capable of operating a robot using the installed robot workbench; and a farm installed under the floating control structure and raised and lowered as the inflow and outflow of seawater is controlled through the control of the floating structure configured in the floating control structure, wherein the farm system is configured as a communication chip is mounted It is possible to automatically measure the ecological environment of the aquaculture farm through the communication environment, transmit and receive data with each component configured in the farm system, and communicate the transmitted/received data with a remote server.

The aquaculture system may control the floating structure or the robot by inputting a command for adjusting the buoyancy by the inflow and outflow of the seawater based on the monitoring information obtained by monitoring the information generated in the aquaculture system.

The floating adjustable structure may include a connecting frame for fixedly coupling the floating structures included in the floating adjustable structure, and at least one or more floating structures may be interconnected through the connecting frame.

The floating control structure includes at least one floating structure configured through the connection frame is formed in a grid-like structure, and detachable columns or walls are installed in the upper and lower portions of the formed grid-type floating structure of the floating structure, , It may be possible to assemble a structure of a residential space of the same or similar type as a residential facility by connecting to the installed column or wall.

The robot includes a grid rail installed on the basis of a robot workbench installed on a floating adjustable structure formed in a grid-like structure, and the farm system, as the robot operates according to the installed grid rail Through the control, it is possible to operate and manage the aquaculture farm installed under the floating control structure.

The aquaculture system is, as the buoyancy is controlled through the floating structure, the salt of the farm is removed and filtered by desalination, and the filtered desalination is performed using magnetic and electro-power decomposition methods to include alkaline water, wave water, and hexagonal water. It can be produced in drinking water and aquaculture water.

The farm system may manage the food circulation of the farm installed under the floating control structure through the robot, and obtain bioenergy generated using the microalgae present in the farm or in the sea.

In the aquaculture system, a detachable and detachable cover is installed in the upper and lower parts of the floating control structure, and a structure of a residential space installed on the upper part of the floating control structure through the installed detachable cover or a farm installed in the lower part of the floating control structure Including opening and closing, when an abnormality in the sea level including typhoon, tsunami, abnormal high temperature, and red tide occurs in the structure of the residential space or the farm, the height of the floating structure configured in the floating control structure is adjusted, or the It may be possible to move the living space or the farm.

The farm system, a power generation facility including a wind power generation or photovoltaic power generation facility is installed on the upper portion of the floating control structure, and a control device for transmitting the power produced by the power generation seonbi, produced in the installed power generation facility It is possible to control the lifting and lowering of the aquaculture farm installed at the lower part of the floating control structure by using the power.

A residential facility providing a rest shelter may be installed above or below the floating control structure.

In the farm system, sensor information is acquired to detect an abnormality inside the farm or outside the farm, and seawater automatically uses the acquired sensor information based on the detected abnormal information inside the farm or outside the farm. It can be managed through a controlled floating structure.

The farm system may propagate solfeggio waves including 423, 528, and 963 Hz generated in the vicinity of the farm system in water or air.

The IoT-based unmanned robot aquaculture system according to an embodiment controls the elevation of a farm connected to a floating control structure through a floating structure that controls buoyancy by inflow and outflow of seawater, thereby controlling the sea level such as typhoons, tsunamis, abnormal high temperatures, and red tides. You can prepare for danger in case of an emergency.

The IoT-based unmanned robot aquaculture system according to an embodiment autonomously operates a farm to reduce labor costs and feed costs to increase efficiency, and applies advanced aquaculture technology to supply an appropriate amount of food in a timely manner, thereby reducing feed costs and reducing the sea environment. contamination can be reduced.

1 to 3 are diagrams for explaining an IoT-based unmanned robot farm system according to an embodiment.
4 is a view for explaining a specific operation of the IoT-based unmanned robot farm system according to an embodiment.
5 is a block diagram for explaining the configuration of an IoT-based unmanned robot farm system according to an embodiment.

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

1 to 3 are diagrams for explaining an IoT-based unmanned robot farm system according to an embodiment. 1 to 3 will be described with reference to the components constituting the IoT-based unmanned robot aquaculture system of FIG. 5 . The farm system 100 may include a floating adjustable structure 110 , a mobile robot running rail 120 , and a farm 130 .

The IoT-based unmanned robot aquaculture system (hereinafter referred to as 'aquaculture system') can provide an integrated residential tourism ecosystem. The farm system 100 may provide a form in which a residential element, a tourism element, and an ecological element are integrated.

The fish farm system 100 has buoyancy to float on the water surface, and the floating control structure 110 constituting the IoT-based floating structure that controls the buoyancy by the inflow and outflow of seawater may be installed. In this case, the floating structure may be a floating object for controlling buoyancy. The aquaculture system 100 may include a connection frame that allows the floating structures included in the floating control structure 110 to be fixedly coupled, and at least one or more floating structures are interconnected through the connection frame. Floating adjustable structure 110 may be formed in a grid-type structure of at least one or more floating structures configured through a connection frame. At this time, the floating structure configured in the floating control structure 110 may be elevated (raised / descended) by the inflow and outflow of seawater. The farm system 100 may include a mobile robot operating rail 120 that is installed on the upper part of the floating adjustable structure with a robot workbench, and can perform robot work using the installed robot workbench. The aquaculture system 100 may control the floating structure or the robot by inputting a command for adjusting the buoyancy because it is an outflow of seawater based on the monitoring information obtained by monitoring the information generated in the aquaculture system. For example, in the farm system 100, grid rails are installed based on a robot workbench installed in a floating adjustable structure formed in a grid-type structure, and as the robot operates according to the installed grid rails, floating adjustment type through the control of the robot It is possible to operate and manage a farm installed in the lower part of the structure 110 . Accordingly, the robot can be controlled according to the command input from the farm system. In addition, the aquaculture system 100 may control the buoyancy with at least one or more floating structures configured in the floating control structure 110 . The aquaculture system 100 may control buoyancy by inflow and outflow of seawater through a floating structure. A net may be installed around the frame of the fish farm at the bottom of the floating control structure, and a farm structure having a net opening and shutting may be installed on the upper surface of the floating control structure, and the structure of the farm is a floating control structure through a wire at each corner can be fixedly installed on the

The aquaculture system 100 can fully automatically adjust the height of the aquaculture farm 130 installed in the lower part of the floating control structure 110 through the control of the IoT-based floating structure that regulates the amount of inflow and outflow of seawater. Accordingly, the farm system 100 can prevent damage from red tides or typhoons.

The farm system 100 automatically measures the ecological environment of the farm through the communication environment configured as the communication chip is mounted, transmits and receives data with each component configured in the farm system 100, and transmits and receives the transmitted data to a remote location. It can also communicate with the server. In addition, the farm system 100 is equipped with Internet protocols such as MQTT, COAP, 400-900 Hz RFID, Zigbee, ... , 13.56 MHz, beacon, Bluetooth, 5G mobile communication chips, and artificial intelligence based on smart phones and Internet servers. It is possible to provide a smart farm with an intelligent (AI) operating system. For example, the farm system 100 may further include a farm ecology measurement device and a farm environment measurement device for measuring the ecology of the farm and the environment of the farm. Alternatively, the ecology of the farm and the environment of the farm may be measured in the farm system 100 .

In addition, the farm system 100 may install a power generation facility including a wind power generation or solar power generation facility on the upper portion of the floating control structure 110 . The farm system includes a control device that transmits power generated by the power generation facility, and can control the elevation of the farm installed at the lower part of the floating control structure 110 by using the power generated from the installed power generation facility. Alternatively, the farm system 100 may receive power transmitted from the control device through a submarine cable and transmit the power to land power. In this case, the submarine cable may be directly or indirectly connected to the farm system 100 . In addition, tidal power generation may be installed on the seabed. The aquaculture system 100 may integrate power produced by each facility module on the basis of a support for supporting the power generation facility. In installing power generation facilities, since a large area of land is required when installing on land, it is difficult to select a location for the facility, and the problem of causing other complaints about land use as well as the influence of the surrounding environment and the amount of sunlight irradiated with sunlight by the surrounding environment It is possible to solve the problem that the installation place is limited by

In addition, the farm system 100 may install a detachable cover that can be attached to the upper and lower portions of the floating control structure 110 . The farm system 100 can open and close the structure of the residential space installed on the upper part of the floating control structure 110 or the farmhouse 120 installed on the lower part of the floating structure through the installed detachable cover. For example, when an abnormality in the sea level including typhoon, tsunami, abnormal high temperature, and red tide occurs in the structure of the residential space or the farm, the height of the floating structure configured in the floating control structure is adjusted, or the living space or the fish farm is moved. This may be possible. For example, it can be submerged near the seabed with a floating structure and a separate gravity weight, or the seawater of the floating structure can be automatically discharged during recovery to return to the original position by buoyancy.

Referring to FIG. 2 , the aquaculture system can configure a farm that is raised and lowered by controlling the inflow and outflow of seawater through the control of the floating structure configured in the floating control structure at the lower part of the floating control structure.

For example, the aquaculture system may appropriately supply feed according to the breeding environment based on the food behavior data of the fish existing in the farm. For example, the farm system can acquire food behavior data for observing the type of fish, the amount of fish, and the behavior of the fish in the farm, and based on the acquired food behavior data, it is possible to determine the feeding time, the amount of food, etc. can be adjusted In this case, the farm system may input information about the adjusted feeding time and the amount of food as commands to the robot, and control so that the feed can be supplied through the robot.

In addition, the farm system may acquire sensor information to detect abnormalities inside the farm or outside the farm, and based on the detected abnormal information inside the farm or outside the farm using the acquired sensor information, seawater automatically Farms can be managed through controlled floating structures.

In addition, the farm system may manage the food circulation of the farm installed under the floating control structure, and may acquire bioenergy generated using microalgae existing in the farm or in the sea. The aquaculture system can not only produce bioenergy using microalgae in the ocean, but also recycle marine organic waste. In addition, the farm system may generate electricity through bioluminescence using light (eg, fireflies) or sea animals. In addition, the farm system controls the buoyancy through the floating structure, removes salt from the farm, filters the desalination, and uses the magnetic and electro-power decomposition methods for filtered desalination. Drinking water and aquaculture including alkaline water, wave water, and hexagonal water Can be created by number. In addition, the farm system can control the production of algae by installing a lighting equipment on the upper or lower part of the floating control structure and driving the installed lighting equipment.

In addition, the farm system can estimate the size and weight of the fish through the underwater image. For example, a camera capable of taking underwater pictures may be installed inside or outside the farm. The farm system may receive the image data acquired from the installed camera, and estimate the size and weight of the fish through analysis of the received image data.

In addition, the farm system can be adjusted to automatically supply dissolved oxygen when the oxygen in the water is insufficient. As the farm system manages oxygen information inside the farm, dissolved oxygen can be supplied when oxygen in the water is insufficient.

In addition, the farm system can propagate solfeggio waves including 423, 528, and 963 Hz generated in the vicinity of the farm system in water or air. Therefore, as a wave healing method based on the theory of relativity of the human body for marine aquaculture and marine healing, solfeggio waves can be propagated into water or air through a music transmission device installed in the farm system or interlocked with the farm system during the healing process.

Referring to FIG. 3 , the aquaculture system may include a connecting frame that allows the floating structures configured in the floating control structure to be fixedly coupled, and at least one or more floating structures may be interconnected through the connection frame. In the farm system, at least one floating structure configured through a connecting frame may be formed in a grid-like structure. The fish farm system installs detachable columns or walls at the top and bottom of the formed grid-type floating structure, and connects to the installed pillars or walls to enable assembly of a structure of a residential space of the same or similar type as a residential facility. can For example, a column or wall may be automatically folded, moved, and detached.

Also, in the aquaculture system, a residential facility providing a resting shelter may be installed above or below the floating adjustable structure. In addition to the rest shelter, housing-related facilities such as a swimming pool, a tanning beach, and a pension may be installed.

In addition, the farm system may install a detachable cover that can be attached to the upper and lower parts of the floating control structure. The farm system can open and close the structure of the residential space installed on the upper part of the floating control structure or the farm installed on the lower part of the floating structure through the installed detachable cover. When an abnormality in sea level including typhoon, tsunami, abnormal high temperature, and red tide occurs in the structure of the residential space or the farm, it may be possible to adjust the height of the floating structure configured in the floating control structure or to move the living space or the farm. .

4 is a view for explaining a detailed operation of the IoT-based unmanned robot farm system according to an embodiment.

The aquaculture system can provide an unmanned robot aquaculture farm based on the 4th industrial revolution marine residential tourism ecological integration IoT. The farm system is equipped with Internet protocols such as MQTT and COAP, 400-900 Hz RFID, Zigbee, ... , 13.56 MHz, beacon, Bluetooth, and 5G mobile communication chips, and an artificial intelligence (AI) operating system based on smart phones and Internet servers. It is possible to provide a smart farm with For example, a farm system may constitute a 5G communication environment.

The farm system has a buoyancy to float on the water surface, and includes a floating control structure constituting an IoT-based floating structure that controls buoyancy by inflow and outflow of seawater, and a robot workbench is installed on the floating control structure, and installed By using a robot workbench, the robot can be controlled through a movable robot operating rail that can work with the robot to operate and manage a farm installed at the bottom of the floating adjustable structure. In addition, the aquaculture system can be raised and lowered by controlling the inflow and outflow of seawater through the control of the floating structure configured in the floating control structure.

The farm system can acquire sensor information from sensors installed around the farm or in the farm through the wireless Internet. For example, there may be a fish detection sensor for fish detection, or there may be a sensor for measuring a farm environment. In addition, each sensor for detecting a fish group and measuring a farm environment may be installed in the farm system, or a fish group detection and farm environment may be measured using sensor information obtained using a plurality of sensors. The farm system may periodically store the results of fish detection and measurement of the farm environment, and analyze the stored results.

For example, the farm system may measure the fish body through the farm environment measurement sensor, or detect the fish population. The aquaculture system can screen fish by detecting fish bodies and groups of fish. In addition, the farm system may control the breeding environment of the farm. For example, the farm system can control the breeding environment using external environmental information such as temperature, humidity, wind speed, etc. around the farm and internal environmental information including status information of fish bodies and groups inside the farm.

In addition, the farm system can feed automatically. For example, the farm system may control the robot to move according to a mobile robot operation rail configured in the farm system. The robot can supply food to a set position according to a command input from the aquaculture system.

In addition, there may be a robot that cleans the net inside the farm. The robot may clean the mesh according to the state of the mesh. At this time, the robot cleaning the mesh can remove foreign substances attached to the mesh while moving the mesh.

Additionally, the farm system can fly drones for monitoring the farms around the farms. In this case, the drone for monitoring the farm is for monitoring the farm, and monitors the surroundings of the farm, and when an abnormality occurs, it can generate an alarm or transmit a message including whether there is an abnormality to the farm system. The farm system can determine whether the farm is abnormal from the message received from the monitoring drone. In addition, underwater drones may be present in the vicinity of the farm system. The farm system can transmit and receive information related to the underwater drone and the farm system by interworking with the underwater drone.

In addition, the farm system can perform and control the power supply. The farm system can control the power produced through the power generation facility through wireless communication. The farm system can deliver the electricity generated through the power generation facility to the place where it is needed in the farm.

The device described above may be implemented as a hardware component, a software component, and/or a combination of the hardware component and the software component. For example, devices and components described in the embodiments may include, for example, a processor, a controller, an arithmetic logic unit (ALU), a digital signal processor, a microcomputer, a field programmable gate array (FPGA). , a programmable logic unit (PLU), microprocessor, or any other device capable of executing and responding to instructions, may be implemented using one or more general purpose or special purpose computers. The processing device may execute an operating system (OS) and one or more software applications running on the operating system. A processing device may also access, store, manipulate, process, and generate data in response to execution of the software. For convenience of understanding, although one processing device is sometimes described as being used, one of ordinary skill in the art will recognize that the processing device includes a plurality of processing elements and/or a plurality of types of processing elements. It can be seen that can include For example, the processing device may include a plurality of processors or one processor and one controller. Other processing configurations are also possible, such as parallel processors.

Software may comprise a computer program, code, instructions, or a combination of one or more thereof, which configures a processing device to operate as desired or is independently or collectively processed You can command the device. The software and/or data may be any kind of machine, component, physical device, virtual equipment, computer storage medium or apparatus, to be interpreted by or to provide instructions or data to the processing device. may be embodied in The software may be distributed over networked computer systems and stored or executed in a distributed manner. Software and data may be stored in one or more computer-readable recording media.

The method according to the embodiment may be implemented in the form of program instructions that can be executed through various computer means and recorded in a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, etc. alone or in combination. The program instructions recorded on the medium may be specially designed and configured for the embodiment, or may be known and available to those skilled in the art of computer software. Examples of the computer-readable recording medium include magnetic media such as hard disks, floppy disks and magnetic tapes, optical media such as CD-ROMs and DVDs, and magnetic such as floppy disks. - includes magneto-optical media, and hardware devices specially configured to store and execute program instructions, such as ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine language codes such as those generated by a compiler, but also high-level language codes that can be executed by a computer using an interpreter or the like.

As described above, although the embodiments have been described with reference to the limited embodiments and drawings, various modifications and variations are possible from the above description by those skilled in the art. For example, the described techniques are performed in an order different from the described method, and/or the described components of the system, structure, apparatus, circuit, etc. are combined or combined in a different form than the described method, or other components Or substituted or substituted by equivalents may achieve an appropriate result.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

Claims (12)

In the IoT-based unmanned robot farm system,
a floating control structure that has buoyancy to float on the water surface and constitutes an Internet of Things-based floating structure that controls buoyancy by inflow and outflow of seawater;
a movable robot operation rail having a robot workbench installed on the floating adjustable structure and capable of operating a robot using the installed robot workbench; and
A fish farm installed at the lower part of the floating control structure and raised and lowered as the inflow and outflow of seawater is controlled through the control of the floating structure configured in the floating control structure
including,
The farm system automatically measures the ecological environment of the farm through the communication environment configured as the communication chip is mounted, transmits and receives data with each component configured in the farm system, and transmits the transmitted and received data to a remote server communicates with and controls the floating structure or the robot by inputting a command to control the buoyancy with the inflow and outflow of the seawater based on the monitoring information obtained by monitoring the information generated in the aquaculture system, and to the robot workbench As the robot is operated according to the installed rail, the farm installed under the floating control structure is operated and managed through the control of the robot, and it is connected to the pillars or walls installed in the upper and lower parts of the floating structure to provide a living space, , A detachable and detachable cover is installed in the upper and lower parts of the floating control structure, and the structure of the residential space installed on the upper part of the floating control structure or the fish farm installed at the bottom of the floating control structure through the installed detachable cover It includes opening and closing doing
An unmanned robot farm system based on the Internet of Things. delete According to claim 1,
The floating adjustable structure,
It includes a connection frame for fixedly coupling the floating structure configured in the floating control structure, and at least one floating structure is configured in a form in which at least one floating structure is interconnected through the connection frame
Internet of Things-based unmanned robot farm system, characterized in that. 4. The method of claim 3,
The floating adjustable structure,
At least one or more floating structures configured through the connection frame are formed in a grid-like structure,
Detachable pillars or walls are installed in the upper and lower parts of the floating structure of the grid-type structure formed above, and it is possible to assemble a structure of a residential space of the same or similar form as a residential facility by connecting to the installed pillars or walls
Internet of Things-based unmanned robot farm system, characterized in that. According to claim 1,
The mobile robot operating rail,
Comprising that the grid rail is installed based on the robot workbench installed on the floating adjustable structure formed in the grid structure
Internet of Things-based unmanned robot farm system, characterized in that. According to claim 1,
The farm system is
As the buoyancy is controlled through the floating structure, the salt of the aquaculture is removed and filtered by desalination, and the filtered desalination is subjected to magnetic and electrolytic decomposition methods to produce alkaline water, wave water, and hexagonal water containing drinking water and aquaculture water. to generate
Internet of Things-based unmanned robot farm system, characterized in that. According to claim 1,
The farm system is
Through the robot, the food circulation of the farm installed in the lower part of the floating control structure is managed, and the bioenergy generated using the microalgae present in the farm or in the sea is obtained.
Internet of Things-based unmanned robot farm system, characterized in that. According to claim 1,
The farm system is
When an abnormality in the sea level including typhoon, tsunami, abnormal high temperature, and red tide occurs in the structure of the residential space or the farm, the height of the floating structure configured in the floating control structure is adjusted, or the residential space or the farm movable
Internet of Things-based unmanned robot farm system, characterized in that. According to claim 1,
The farm system is
A power generation facility including a wind power generation or photovoltaic power generation facility is installed on the upper portion of the floating control structure, and a control device for transmitting electric power produced by the power generation facility is installed, and using the power produced by the installed power generation facility Controlling the lifting and lowering of the aquaculture farm installed at the lower part of the floating control structure
Internet of Things-based unmanned robot farm system, characterized in that. According to claim 1,
A residential facility providing a rest shelter is installed in the upper or lower part of the floating adjustable structure
Internet of Things-based unmanned robot farm system, characterized in that. According to claim 1,
The farm system is
A floating structure in which sensor information is acquired to detect an abnormality inside the farm or outside the farm, and seawater is automatically adjusted based on abnormal information inside or outside the farm, detected using the acquired sensor information managed through
Internet of Things-based unmanned robot farm system, characterized in that. According to claim 1,
The farm system is
Solfeggio waves including 423, 528, and 963 Hz generated in the vicinity of the farm system are propagated in water or air.
Internet of Things-based unmanned robot farm system, characterized in that.

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