KR20210054808A - 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 Internet of Things-based unmanned robot fish farm according to an embodiment comprises: a floating controllable structure which 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 on which a task of a robot can be carried out using a robot worktable which is installed on an upper portion of the floating controllable structure; and a fish farm which is installed on a lower portion of the floating controllable structure and ascends and descends as the inflow and outflow of seawater is controlled through the control of the floating structure configured in the floating controllable structure. The fish farm system can automatically measure an ecological environment of the fish farm through a communication environment configured as a communication chip is mounted, can transmit and receive data with each component configured therein, and can communicate the transmitted and received data with a remote server.

Description

The 4th Industrial Revolution using maritime holdings, IoT, unmanned robot farming, integrated IoT, unmanned robot farming, marine residential tourism ecosystem

The description below is for an IoT-based unmanned robot farm.

Numerous marine farms have been installed on the sea, but most of the offshore farms are fixed on the bottom of the sea and are installed in relatively shallow seas, and the farms are fixed, so damage caused by typhoons and red tides could not be avoided. In other words, red tides are mainly formed on the surface close to the surface of the water, blocking sunlight and consuming oxygen in the water to kill the fish and shellfish that are farmed.If the farm can be lowered to the depths of the sea level, the damage to the red tides will be avoided. Likewise, even if a storm occurs due to a typhoon, it is greatly affected by the sea surface, but it is hardly affected in the deep areas below the sea level, so it will be possible to avoid the damage from the typhoon.

However, most of the conventional marine farms are fixed and have a structure in which a floating object is installed on the sea level and a cage farm is connected to the floating object, so the farm cannot be moved up and down relative to the sea level, so it was not possible to avoid red tide damage or typhoon damage.

For example, Korean Patent Application Publication 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 and offshore farm using the same to enable the raising and lowering of the farm by the power obtained from the solar power generation system by installing a farm structure at the bottom and lighting to help the algae growth. It is disclosed.

A submarine tidal power generator and an upper solar power generation system using a variable fixed pile structure on the sea or the main body of an offshore wind generator installed as a support were constructed, and Solpeggio 432, 528, 963, which is a bioactive wave of the theory of relativity. With Hz music wave, it is possible to provide a method and apparatus for installing a robot-based fully automatic floating control food circulation ecology, tourism integrated maritime aquaculture and residential pension, sun tanning, snorkeling submarine ecology floating control structure.

The IoT-based unmanned robotic aquaculture system includes: a floating control structure constituting an IoT-based floating structure that has buoyancy so as to float on the surface of the water and controls the buoyancy by inflow and outflow of seawater; A movable robot operation rail on which a robot worktable is installed on the floating adjustable structure, and the robot can work using the installed robotic worktable; And a farm that is installed under the floating control structure, and is elevated as the outflow of seawater is controlled through the control of the floating structure configured in the floating control structure, and the farm system is configured according to the mounting of a communication chip. It is possible to automatically measure the ecological environment of the farm through a communication environment, transmit/receive data with each component configured in the farm system, and communicate the transmitted/received data with a remote server.

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

The floating-adjustable structure may include a connection frame for fixing the floating structure configured in the floating-adjustable structure, and at least one floating structure may be interconnected through the connection frame.

The floating-adjustable structure includes at least one floating structure configured through the connection frame formed in a lattice-like structure, and a detachable column or wall is installed on the upper and lower portions of the floating structure of the formed lattice-like structure, and , By connecting to the installed pillars or walls, it may be possible to assemble a structure of a residential space having the same or similar shape as that of a residential facility.

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

The farm system includes alkaline water, wave water, and hexagonal water by removing salt from the farm by desalination by controlling the buoyancy through the floating structure, and filtering the filtered desalination by magnetic and electrolytic methods. It can be produced from drinking and farming water.

The farm system can manage the food circulation of the farm installed under the floating control structure through the robot, and obtain bioenergy generated by using the farm or microalgae existing on the sea.

The farm system includes a detachable cover installed on the upper and lower portions 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 under the floating control structure. Including opening and closing, the structure of the residential space or the farm, when an abnormality of sea level including typhoon, tsunami, abnormal high temperature, and red tide occurs, adjust the height of the floating structure configured in the floating control structure, or the It may be possible to move the living space or the farm.

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

A residential facility that provides a resting shelter may be installed in the upper or lower part of the floating adjustable structure.

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

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

The IoT-based unmanned robotic farm system according to an embodiment controls the elevation of the farm connected to the floating control structure through a floating structure that controls buoyancy by the inflow and outflow of seawater, thereby controlling the sea level of typhoons, tsunamis, abnormal high temperatures, red tides, etc. In case of abnormality, you can prepare for danger.

The IoT-based unmanned robotic farm system according to an embodiment increases efficiency by reducing labor and feed costs by autonomously operating a farm, and applying advanced aquaculture technology to supply an appropriate amount of food in time to reduce feed costs and reduce the sea environment. It can reduce pollution.

1 to 3 are diagrams for explaining an IoT-based unmanned robot farm system according to an exemplary 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 illustrating 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 farm system of FIG. 5. The farm system 100 may include a float-adjustable structure 110, a mobile robot driving rail 120, and a farm 130.

The IoT-based unmanned robotic farm 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 tourist element, and an ecological element are integrated.

The aquaculture system 100 has buoyancy so as to float on the water surface, and a floating adjustable structure 110 constituting an IoT-based floating structure that adjusts buoyancy by inflow and outflow of seawater may be installed. In this case, the floating structure may be a floating object that controls buoyancy. The aquaculture system 100 includes a connection frame for fixing the floating structure configured in the floating control structure 110, and at least one floating structure is interconnected through the connection frame. The floating adjustable structure 110 may have at least one floating structure configured through a connection frame formed in a lattice-like structure. At this time, the floating structure configured in the floating adjustable structure 110 may be elevated (raised/lowered) due to the outflow of seawater. The farm system 100 may include a movable robot operation rail 120 in which a robot worktable is installed on the upper part of the floating control structure, and the robot working with the installed robot worktable is possible. The aquaculture system 100 may control a floating structure or a robot by inputting a command for controlling buoyancy due to the outflow of seawater based on the monitoring information obtained by monitoring information generated in the aquaculture system. For example, in the farm system 100, a grid rail is installed on the basis of a robot workbench installed in a floating adjustable structure formed in a grid structure, and as the robot is operated according to the installed grid rail, the floating control type is controlled by the robot. It is possible to operate and manage the farm installed under 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 buoyancy with at least one floating structure configured in the floating control structure 110. The aquaculture system 100 may control buoyancy through the inflow and outflow of seawater through a floating structure. A net can be installed around the farm frame under the float control structure, and a fish farm structure equipped with a net opening and closing can be installed on the upper surface of the float control structure, and the structure of the farm is a float control structure through wires at each corner. Can be installed fixed on.

The farm system 100 can fully automatically adjust the height of the farm 130 installed under the floating control structure 110 through the control of the IoT-based floating structure that controls the amount of inflow and outflow of seawater. Accordingly, the farm system 100 may prevent damage from a red tide or a typhoon.

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 data remotely. 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 chip, and is equipped with a smart phone and internet server-based artificial Smart farms with an intelligent (AI) operating system can be provided. For example, the farm system 100 may further include a farm ecology measuring device and a farm environment measuring 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 produced by the power generation facility, and can control the elevation of the farm installed under the floating control structure 110 by using the power produced by the installed power generation facility. Alternatively, the farm system 100 may receive power transmitted from a control device through a submarine cable and transmit it as land power. At this time, 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 farm system 100 may integrate and process power generated by each facility module based on a support for supporting the power generation facility. In installing power generation facilities, it is difficult to select a facility location because a large area of land is required when installing on land, and the amount of sunlight irradiated by the surrounding environment and the problem of causing other civil complaints to the use of the land as well as the environmental impact It is possible to solve the problem that the installation location is limited by.

In addition, the farm system 100 may install a detachable cover that is detachable on the upper and lower portions of the floating adjustable structure 110. The farm system 100 may open and close the structure of a residential space installed on the upper part of the floating adjustable structure 110 or the farm 120 installed under the floating structure through an installed detachable cover. For example, in the case of sea level abnormalities including typhoons, tsunamis, abnormal high temperatures, and red tides, the structure of a residential space or a farm, adjust the height of a floating structure composed of a floating-adjustable structure, or move a residential space or a farm. This could be possible. For example, the floating structure and a separate gravity weight can be submerged close to the sea floor, or the seawater of the floating structure can be automatically discharged during restoration, and the floating structure can be returned to its original position by buoyancy.

Referring to FIG. 2, the aquaculture system may configure a farm that is elevated by controlling the inflow and outflow of seawater through the control of a floating structure configured in a floating control structure under the floating control structure.

For example, the farm system can properly supply feed according to the breeding environment based on the feeding behavior data of fish existing in the farm. For example, the farm system can acquire feeding behavior data that observes the type of fish in the farm, the amount of fish, and the behavior of the fish, and based on the obtained feeding behavior data, the feeding time and the amount of food can be determined. Can be adjusted. At this time, the farm system can control the feed to be supplied through the robot by inputting information on the controlled feeding time and the amount of feeding to the robot as a command.

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

In addition, the farm system manages the food circulation of the farm installed under the floating control structure, and may acquire bioenergy generated by using microalgae existing in the farm or at sea. Aquaculture systems not only produce bio-energy using marine microalgae, but also recycle marine organic waste. In addition, the farm system can also generate electricity through bioluminescence using light (eg, fireflies) or undersea animals. In addition, the farm system removes salt from the farm by controlling the buoyancy through the floating structure and filters it by desalination, and the filtered desalination is filtered by magnetic and electrolytic methods to provide drinking water and aquaculture including alkaline water, wave water, and hexagonal water. Can be generated by number. In addition, the farm system can control the production of seaweed by installing 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 fish through underwater images. For example, a camera capable of shooting underwater may be installed inside or outside the farm. The farm system can receive image data acquired from an installed camera, and estimate the size and weight of fish through analysis of the received image data.

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

In addition, the farm system can propagate Solpeggio waves including 423, 528, and 963 Hz generated around the farm system into water or air. Accordingly, as a method of healing the theory of relativity of the human body for maritime aquaculture and marine healing, the Solpeggio wave may 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 includes a connection frame for fixing a floating structure configured in a floating control structure, and at least one floating structure may be interconnected through the connection frame. In the farm system, at least one floating structure configured through a connection frame may be formed in a lattice-like structure. The aquaculture system is configured to install detachable columns or walls on the upper and lower portions of the floating structure of the formed lattice structure, and connect them to the installed columns or walls to assemble the structure of a residential space in the same or similar form as the residential facility. I can. For example, a column or a wall may be automatically folded, moved, or detached.

In addition, a residential facility providing a resting shelter may be installed on the upper or lower part of the floatable structure in the farm system. In addition to the resting shelter, residential-related facilities such as swimming pools, tanning beaches, and pensions can be installed.

In addition, in the farm system, a removable cover can be installed on the upper and lower portions of the floating adjustable structure. The farm system can open and close the structure of the residential space installed on the upper part of the floating adjustable structure or the farm installed on the lower part of the floating structure through the installed detachable cover. In the case of sea level abnormalities including typhoons, tsunamis, abnormal high temperatures, and red tides, the structure of the residential space or the farm may be able to adjust the height of the floating structure composed of the floating control structure or move the residential space or farm. .

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

The farm system can provide an unmanned robot farm based on IoT in the 4th Industrial Revolution, integrated Internet of Things, marine residential tourism. The farm system is equipped with Internet protocols such as MQTT, COAP, 400-900 Hz RFID, Zigbee, ..., 13.56 MHz, beacon, Bluetooth, 5G mobile communication chip, and an artificial intelligence (AI) operating system based on a smart phone and internet server. It can provide a smart farm with a. For example, a farm system can constitute a 5G communication environment.

The aquaculture system has buoyancy to float on the surface of the water, and includes a floating control structure that constitutes an IoT-based floating structure that controls buoyancy by the inflow and outflow of seawater, and a robot worktable is installed and installed on the top of the floating control structure. By using the robot workbench, the robot can be operated and managed under the floating control structure by controlling the robot through the movable robot operation rail that enables the robot to work. In addition, the aquaculture system can be elevated by controlling the inflow and outflow of seawater through the control of the floating structure configured in the floating control structure.

The farm system may acquire sensor information from sensors installed in the farm or around 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 aquaculture environment. In addition, the farm system may be equipped with sensors for detecting fish groups and measuring the environment of the farm, or fish group detection and farm environment may be measured using sensor information obtained using a plurality of sensors. The farm system can periodically store the results of fish detection and measurement of the farm environment, and can analyze the stored results.

For example, a farm system can measure fish through a farm environment measurement sensor, or detect a fish group. Aquaculture systems can screen fish by detecting fish and fish groups. In addition, the farm system can control the farm's breeding environment. For example, the farm system can control the breeding environment by using external environmental information such as temperature, humidity, and wind speed around the farm, and internal environment information including information on the status of fish and fish groups inside the farm.

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

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

Additionally, the farm system can launch drones for farm monitoring around the farm. At this time, the drone for monitoring the farm is for monitoring the farm, and it can monitor the vicinity of the farm and generate an alarm when an abnormality occurs or transmit a message including the abnormality to the farm system. The farm system can determine whether or not the farm is abnormal from the message received from the surveillance drone. In addition, underwater drones may exist around the farm system. The farm system can transmit and receive information related to the underwater drone and the farm system by interlocking 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 produced through the power generation facility to the places where the farm needs it.

The apparatus described above may be implemented as a hardware component, a software component, and/or a combination of a hardware component and a software component. For example, the devices and components described in the embodiments are, 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), a microprocessor, or any other device capable of executing and responding to instructions, such as one or more general purpose computers or special purpose computers. The processing device may execute an operating system (OS) and one or more software applications executed on the operating system. Further, the processing device may access, store, manipulate, process, and generate data in response to the execution of software. For the convenience of understanding, although it is sometimes described that one processing device is used, one of ordinary skill in the art, the processing device is a plurality of processing elements and/or a plurality of types of processing elements. It can be seen that it may include. For example, the processing device may include a plurality of processors or one processor and one controller. In addition, other processing configurations are possible, such as a parallel processor.

The software may include a computer program, code, instructions, or a combination of one or more of these, configuring the processing unit to operate as desired or processed independently or collectively. You can command the device. Software and/or data may be interpreted by a processing device or, to provide instructions or data to a processing device, of any type of machine, component, physical device, virtual equipment, computer storage medium or device. Can be embodyed. The software may be distributed over networked computer systems and stored or executed in a distributed manner. Software and data may be stored on 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 usable to those skilled in computer software. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tapes, optical media such as CD-ROMs and DVDs, and magnetic media such as floptical disks. -A hardware device specially configured to store and execute program instructions such as magneto-optical media, and ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine language codes such as those produced 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 by the limited embodiments and drawings, various modifications and variations are possible from the above description to those of ordinary skill in the art. For example, the described techniques are performed in a different order from the described method, and/or components such as systems, structures, devices, circuits, etc. described are combined or combined in a form different from the described method, or other components Alternatively, even if substituted or substituted by an equivalent, an appropriate result can be achieved.

Therefore, other implementations, other embodiments, and those equivalent to the claims also fall within the scope of the claims to be described later.

Claims (12)

In the IoT-based unmanned robot farm system,
A floating control structure constituting an IoT-based floating structure that has buoyancy so as to float on the surface of the water and controls the buoyancy by inflow and outflow of seawater;
A movable robot operation rail on which a robot worktable is installed on the floating adjustable structure, and the robot can work using the installed robotic worktable; And
A farm that is installed under the floating control structure and is elevated 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 a communication environment configured as a 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. Communicating with
IoT-based unmanned robotic farm system. The method of claim 1,
The farm system,
Controlling the floating structure or the robot by inputting a command for adjusting the buoyancy by the outflow of the seawater based on the monitoring information obtained by monitoring the information generated in the farm system.
IoT-based unmanned robot farm system, characterized in that. The method of claim 1,
The floating adjustable structure,
Including a connection frame for fixedly coupled to the floating structure configured in the floating-adjustable structure, wherein at least one floating structure is configured in a form that is interconnected through the connection frame
IoT-based unmanned robot farm system, characterized in that. The method of claim 3,
The floating adjustable structure,
At least one floating structure configured through the connection frame is formed in a lattice-like structure,
Detachable pillars or walls are installed on the upper and lower portions of the floating structure of the formed grid structure, and by connecting to the installed pillars or walls, it is possible to assemble a structure of a residential space of the same or similar shape as a residential facility.
IoT-based unmanned robot farm system, characterized in that. The method of claim 1,
The robot,
Including that a grid rail is installed on the basis of a robot worktable installed on a floating adjustable structure formed in a grid structure,
The farm system,
As the robot is operated according to the installed lattice network rail, through the control of the robot, operating and managing a farm installed under the floating adjustable structure
IoT-based unmanned robot farm system, characterized in that. The method of claim 2,
The farm system,
As the buoyancy is adjusted through the floating structure, salts of the farm are removed and filtered by desalination, and the filtered desalination is used as a drinking water and aquaculture water including alkaline water, wave water, and hexagonal water using a magnetic and electrolytic method. Generated
IoT-based unmanned robot farm system, characterized in that. The method of claim 2,
The farm system,
Through the robot, it manages the food circulation of the farm installed under the floating control structure, and obtains bioenergy generated by using microalgae existing in the farm or the sea.
IoT-based unmanned robot farm system, characterized in that. The method of claim 1,
The farm system,
A detachable cover is installed on the upper and lower portions of the floating adjustable structure, and opening and closing a structure of a residential space installed on the upper part of the floating control structure or a farm installed under the floating control structure through the installed detachable cover, ,
The structure of the residential space or the farm, when an abnormality of sea level including typhoon, tsunami, abnormal high temperature, and red tide occurs, adjusts the height of the floating structure configured in the floating control structure, or Moveable
IoT-based unmanned robot farm system, characterized in that. The method of claim 1,
The farm system,
A power generation facility including wind power generation or solar power generation facility is installed on the top of the floating control structure, and includes a control device for transmitting power produced by the power generation facility, and using the power produced by the installed power generation facility. Controlling the elevation of the farm installed under the floating adjustable structure
IoT-based unmanned robot farm system, characterized in that. The method of claim 1,
A residential facility that provides a resting shelter on the upper or lower part of the floating adjustable structure is installed
IoT-based unmanned robot farm system, characterized in that. The method of claim 1,
The farm system,
A floating structure in which sensor information is acquired to detect abnormalities inside the farm or outside of the farm, and seawater is automatically adjusted based on abnormal information inside or outside the farm detected using the acquired sensor information. Managed through
IoT-based unmanned robot farm system, characterized in that. The method of claim 1,
The farm system,
Solpeggio waves including 423, 528, 963 Hz generated around the aquaculture system are propagated in water or air.
IoT-based unmanned robot farm system, characterized in that.

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