KR20190063160A - System for Managing History of producing and collecting growth information for paralichthys olivaceus of sea breeding farm - Google Patents

Abstract

The present invention relates to a system for collecting information on growth of an aquaculture tank and managing a production history capable of simultaneously monitoring an integrated state which can view data to be inputted in real-time on site at a glance, and real-time growth images and states through analysis of overall data on aquafarm growth management and growth information, and production history check through a QR code attached at shipment in accordance with growth data of aquaculture organisms collected in a tank management device for feeding, shipment, mortality, administration and the like which are daily inputted from an aquafarm.

Description

[0001] The present invention relates to a system and method for collecting and organizing food bio-cultures in a farm,

The present invention is based on the data on the growth of the aquaculture farm, the analysis of the overall data on the cultivation information, and the QR code attached at the time of shipment according to the growth data of the aquaculture collected from the tank management unit for daily feeding, shipment, The present invention relates to a system and method for collecting and managing a bio-information on a farm, which can simultaneously monitor real-time growth images and current status of data input in real time through a production history inquiry at a glance.

More particularly, the present invention relates to a system for collecting information on the growth of aquaculture tank, and more specifically, a system for storing a water quality environment information, an activity characteristic of an object, Output of history and providing QR code to consumers to provide information on the production history of fisheries fishes to secure stable production and distribution of fisheries fishes and to efficiently manage the history management of growing, Collection and production management system.

Since the existing farms are not automated, the workers collect the environmental information of the farms in a certain time every day. Therefore, it takes much time and labor to manage the farms. , And there is a real-time monitoring of water temperature, DO, pH, nitrous acid, which is known to cause the death of fish farms, and an emergency alert system. In other words, growth and environmental management in the farm is very important, but most farmers do not manage it because of complexity and difficulty, or fear of PCs, it is a fact that most farms manage by hand.

In the case of handwriting management, it is easy to create, but it is difficult to manage or inquire jointly by many people, and there is a risk of loss, difficulty of data tracking, simple creation and inquiry, It is almost impossible to inquire. Also, it is inconvenient to input daily data even in the case of the farm where the computer system is introduced due to the government subsidy program, and the farm where the computer administration is steadily operated is less than 50%.

On the other hand, in aquaculture, diatomaceous diatoms abundant in seawater are adhered to the attachment plate, and natural diatomic diatoms are used as food for abalone to save money and manpower. However, there are 6,000 to 10,000 species of diatoms in seawater, and it is difficult to control the culture products because the shape and culture characteristics of the gypsum vary widely.

The microalgae, which are currently being produced commercially, are mainly cultured using a photobioreactor capable of culturing at a high density. In a conventional photobioreactor, a culture medium is supplied according to the type of microalgae to be cultivated in a constant volume tank, microalgae are inoculated, and then pure culture is carried out by blocking the infestation of protozoa and molds harmful to the growth of microalgae The culture solution is filtered and sterilized.

A gas containing a carbon source such as carbon dioxide is aerated in the culture solution so that sufficient photosynthesis can be achieved, and the gas and the nutrients in the culture solution are stirred to be uniformly dispersed. For efficient photosynthesis, light of a certain wavelength is irradiated using an LED or the like depending on the characteristics of the microalgae to be cultured.

Particularly, in a photoreactor, it is necessary to maintain a culture liquid at a constant temperature in order to cultivate microalgae in a large amount with a constant growth efficiency. Therefore, a heating apparatus, a heat exchanger, and the like are installed and cultivated according to the season. In particular, there is a problem that large amount of energy is consumed in the mass cultivation of microalgae due to the supply and aeration of the culture medium, the irradiation of light through the light source, and the control of the water temperature. In particular, in the case of the four seasons in Korea, Production has difficulties in energy efficiency.

Therefore, it is possible to inquire data entered in the field through the one-stop management of the water tank status immediately at the site and the management office, to manage the integration by several people, and to the field worker who is afraid of the PC easily because of easy usability We propose an approach to acquire bio-information and production management of the farm.

1. Fish disease diagnosis system (Patent Application No. 10-2010-0137774) 2. Automatic feeding device and its system in the offshore underwater cage farm (Patent Application No. 10-2010-0095817) 3. Aquaculture management system based on changes in water quality information (No. 10-2010-0137858)

The present invention is based on the data on the growth of the aquaculture farm, the analysis of the overall data on the cultivation information, and the QR code attached at the time of shipment according to the growth data of the aquaculture collected from the tank management unit for daily feeding, shipment, The present invention is to provide a system for collecting farm growth information and a production history management system capable of simultaneously monitoring the integrated status and the real-time growth image and the status of real-time input data on the field through the production history inquiry.

In order to accomplish the above object, a system for collecting and managing information on the growth of aquaculture tank in accordance with an embodiment of the present invention is provided in a farm site and a side of a fishery environment to provide information on the temperature, wind speed, And the growth environment of the aquaculture environment and the growth environment information of the aquaculture environment can be predicted by observing the water temperature, dissolved oxygen amount, salinity, Ph, turbidity closely related to the growth, measuring the level of the seawater tank, Aquaculture environment device for providing aquaculture environment; It is possible to collectively monitor each water tank for the information on the growth status of each water tank in the farm environment unit, display the real-time sensing information received from each water tank monitoring sensor by location, Display of the radioactive contamination level, warning lamps when the danger level is reached, warning lamps when the water level reaches each water level, display of the sensing data of each sensor installed, display of the growth status of the water intake, A shrimp tank management device for displaying the information of the fishermen; It can measure the water quality information of the farm using the portable measuring instrument or measure the water temperature, DO, salinity and pH information of the aquarium in real time, and collects, stores and analyzes in real time a lot of information in the aquarium A water quality measurement device that grasps the growth status of the farm and displays the growth information in real time; Monitoring of the water used by the radiation measurement sensor in the seawater tank of the farm and installing a radioactive sensor inside the seawater tank to draw and store the seawater to supply water to the aquaculture tank, Radioactivity measuring device; Monitoring of the internal real-time image of the fish tank through the communication network with the integrated control status board, inquiry on the status of growth of the whole fish tank in the aquaculture farm, inquiry of the water quality data and trend graph of each fish tank, Integrated control server for controlling video; A tag created to provide the user with information on production history information of the cultured aquarium, which stores the radioactivity history of the farm, the production information of the aquaculture creature, A QR code attached to the tail of the aquatic organism to record history information on production, movement and sale of aquatic organisms; And monitoring the situation of the farm environment information according to the farm environment, the growth information of the fishery environment and the growth environment information transmitted from the farm environment device, or the history of the radioactivity test of the QR code attached to the history management device, And a user terminal capable of confirming the stored history information of the shipment and the farm through the dedicated application.

In this case, the farm water tank management apparatus collects the production history data inputted from the field at the same time as the work is collected The data input error caused by the dualization of the water tank management personnel and the computer management personnel is eliminated, and the field personnel are input directly on the field, and the computer management personnel provide the management efficiency by confirming the input contents.

In addition, the system for collecting and managing the production information of the aquaculture tank according to the embodiment of the present invention is characterized in that the aquaculture tank management apparatus collects image information of the aquaculture fish in the aquaculture system or measures the state information through the sensor, And transmits the information to the user terminal or displays the water quality sensor and the water level sensor real time measurement information through the water tank management unit and transmits the water quality sensor and the water level sensor real time measurement information transmission .

In addition, the integrated management server of the present invention is capable of real-time video monitoring in the aquaculture tank, information on the growth status of the entire aquaculture tank, Real-time environmental information, and external linkage information, and the history of the radioactivity test of the QR code attached to the history management device, the production of aquatic organisms, the storage and the storage of the aquaculture The history information is configured to be able to inquire the production history through the application of the user terminal (800).

According to the embodiment of the present invention, the system for collecting and managing the production information of the aquaculture tank and the production history management system stores the information of the water quality environment, the activity characteristics of the object, and the information of the growth characteristics in the DB and directly scans the QR code directly And providing QR codes to consumers to provide information on production history of fisheries fishes, thereby securing the production and distribution of stable fishes, and effectively managing the history management of growth, distribution and sales.

In addition, according to another embodiment of the present invention, the system for collecting information on the growth of the aquaculture tank and the system for managing the production history of the aquaculture grows aquaculture according to the growth data of the aquaculture collected from the tank manager for the daily feed, shipment, The comprehensive data analysis of management and growth information, the QR code attached to the factory, the production history can be inquired at once and the real-time data can be viewed at a glance. Effect.

In addition, according to another embodiment of the present invention, the system for collecting and managing production information of aquaculture tank and the production history management system of the present invention can increase productivity by decreasing the mortality rate and growth efficiency through the management efficiency of aquaculture fish, To reduce the cost of social management to solve problems such as employment creation, excessive feed supply, destruction of marine environment due to the use of chemicals, and ecosystem instability, and automatic input processing By improving the efficiency of work and establishing all requirements for the introduction of the production history system, it is possible to reduce the dosage of antibiotics and medicines, thereby providing the effect of securing quality competitiveness through production of safe aquatic organisms.

In addition, according to another embodiment of the present invention, the system for collecting and managing production information of the aquaculture tank can apply the production history system to the other aquaculture industry, thereby enhancing the domestic sales volume, We can expect to see the strengthening of the competitiveness of marine products sold to other countries where regulation is strengthened.

1 is a state diagram of a system for collecting information on the growth of aquaculture tank in a paddy field according to the present invention and a production history management system
FIG. 2 is a block diagram of a system for collecting and growing production information on a pond in a pond in accordance with the present invention shown in FIG. 1; FIG.
FIG. 3 is a diagram showing a hardware state of a farm management system for collecting and growing production water in aquaculture tank according to the present invention
Fig. 4 is a diagram showing the state of the farm management system of the farm in the farm management system
FIG. 5 is a diagram showing a state diagram of tags for aquaculture of a history management apparatus for collecting information on the growth of aquaculture tank in the present invention and a production history management system according to the present invention.
FIG. 6 is a state diagram showing an interlocked state of the radiation measuring device and the integrated control server of the farming water tank collecting information and production history management system according to the present invention
FIG. 7 is a diagram showing a state diagram of a comprehensive status board of a farm management system of an integrated control server of a farm management system
8 is a perspective view of an adherent diatom culture apparatus according to the present invention.
9 is a view showing a culture unit of an adherent diatomous culture apparatus according to the present invention.
10 is a perspective view showing the fastening method of the culture unit.
11 is a perspective view showing the structure of the upper part of the culture unit frame.
12 is an exploded perspective view showing an embodiment of the configuration of the culture unit frame.
13 is a perspective view showing a configuration of a gas supply unit.
FIG. 14 is a photograph showing an application of an adhesive diatom culturing apparatus according to the present invention to an outdoor water tank.

In the present specification, when any one element 'transmits' data or signals to another element, the element can transmit the data or signal directly to the other element, and through at least one other element Data or signal can be transmitted to another component.

FIG. 1 is a state diagram of a system for collecting and culturing biological culture information of aquaculture food according to the present invention, and FIG. 2 is a diagram showing the constitution of a system for collecting and growing production information on aquaculture tank in accordance with the present invention shown in FIG. 1 and 2, the detailed description of the system for collecting and managing the production history information of the aquaculture tank in accordance with the present invention will be described with reference to FIG. 1 and FIG. 2. Referring to FIG. 1 and FIG. 2, A sage water tank management device s200, a water quality environment device s300, a radiation measurement device s400, a communication network s500, an integrated control server s600, a history management device s700, a user terminal s800, (s900).

The aquaculture environment device (s100) is installed at one side of a farm and a fishery environment. The aquaculture environment device (s100) is installed at one side of a farm and a fishery environment and has a water temperature, dissolved oxygen amount, salinity, Ph and turbidity closely related to growth based on temperature, wind speed, And to provide information on growth and growth environment of aquaculture environment and fishery environment by predicting the growth environment of aquaculture through sea level measurement and sea water supply.

The pond water tank management device s200 can collectively collect the water pond status information for each pond water condition information of the pond water environment device s100 and can collect the real time sensing information received through each water tank monitoring sensor by location It is also possible to display the radioactive contamination and display warning lamp when the danger level is reached, to display the warning lamp when the danger level reaches each water level, to display sensed data of sensor installed by each city, It displays the current status of the growing, the weight, the weight, and displays the information about the death of the worker on that day.

In addition, the shrimp basin management apparatus s200 collects the production history data inputted from the field at the same time as the work, through the integrated control server (s600) in cooperation with the communication network (s500) And data management errors caused by the dualization of the computer management personnel, and the field personnel directly input in the field, and the computer management personnel provide the management efficiency by confirming the input contents.

In addition, the pond water tank management device s200 is capable of managing the entire area and location through the communication network in cooperation with the water tank management and growth management module, the water tank comprehensive status display module, and the integrated management status module, Sensor interface, communication module, sensing data transmission module, image information transmission module, alarm module (alert to the manager in case of abnormality of water quality environment information) can be input immediately.

On the other hand, the pond water tank management apparatus (s200) collects image information of a water tank in the farm or monitors the water quality information (water temperature, DO, salinity, pH) , The information is transmitted to the user terminal or the water quality sensor and the water level sensor real time measurement information are displayed through the water tank manager and the water quality sensor and the water level sensor real time measurement information transmission are transmitted.

The sake tank management apparatus s200 can be used for the following adhered diatom culturing apparatus. FIG. 8 is a perspective view of an adherent diatomous culture device used in the device (s200) for aquaculture tank of the present invention. The present invention relates to a method for preparing a culture medium, comprising a culture frame (100) in which a transverse member, a longitudinal member and a column are connected to form a certain space therein, and an attachment substrate (220) for attaching diatoms to an internal space formed by the culture frame And a gas supply unit 300 formed below the culture unit 200 and formed in parallel with the ground to supply gas to the culture unit 200. The gas supply unit 300 includes: The present invention provides an apparatus for culturing an adhering strain.

The culture frame 100 is preferably formed of a rigid material such as SUS (Steel Use Stainless), and is manufactured considering the size of the culture unit so that the culture unit 200 can be accommodated in the culture frame. In addition, a rope can be installed on the upper edge of the culture frame so that it can be lifted and moved by a crane.

In the embodiment of the present invention, the width, length and height are 1.75 m * 2 m * 1.5 m, and the width wing 310, the connection pipe 330 and the gas supply pipe 340 are bundled and fixed along the frame. And a part of the incubation unit can be bundled and fixed. In addition, a frame foot 110 may be formed on the lower part of the culture frame 100 such that the adherent tyrosine flow culture apparatus is spaced apart from the bottom of the water tank. In the space separated by the frame foot 110, the wing organ 310 may be disposed, and the culture unit may contact the bottom of the water tank to prevent the feeding and drinking water from being hindered, thereby preventing the growth of the attached microalgae from being hindered .

9 is a diagram showing the configuration of a culture unit of an adhesive diatom culturing apparatus according to the present invention. The culture unit 200 is constructed by wrapping the culture unit frame 210 with the attachment substrate 220 and fixing the attachment substrate to the culture unit frame using a fixing unit such as the fixing bar 230. That is, the culture unit 200 includes a culture unit frame 210 formed with a polygonal column or a cylinder, which has a through hole formed therein and on each side and is easy to feed and drink in up and down and left and right directions and a culture unit frame 210 surrounding the culture unit frame 210 An attachment substrate 220 for providing an attachment or positive spatial surface of sticky diatoms in the breeding water and a fixing unit for fastening the culture unit frame 210 and the attachment substrate 220 to each other.

As shown in FIG. 10, the fixing part of the embodiment of the present invention is composed of the fixing bar 230 and the fixing groove 211. That is, in the culture unit frame 210, the fixing groove 211 is formed and the edge of the attachment substrate 220 is inserted therein. Then, the fixing bar 230 is pressed onto the fixing groove 211 on the attachment substrate 220 Thereby fixing the attachment substrate 220 to the culture unit frame 210.

11 is a perspective view showing the fastening method of the culture unit. One of the pillars of the culture unit frame is formed to have a thickness of 10 mm or more so that the fixing groove 211 can be formed in the culture unit frame 210 and the fixing bar 230 having a thickness of 1.5 mm is inserted thereinto. (211) are formed one or two. It is preferable that the columns of the three culture unit frames in which the fixing grooves are not formed are formed to have a smaller size, for example, a thickness of 5 mm for smooth communication of the breeding water. The fixing bar 230 may be made of plastic, rubber, silicon, or the like, and may fix the attachment substrate 220 on one or both sides of the culture unit frame 210. Such a fixing method facilitates the attachment and detachment of the attachment substrate to the culture unit frame, so that it is easy to replace the attachment substrate and to clean the culture unit frame. Preferably, the attachment substrate is formed of any one of nylon, polypropylene, and polyethylene, and the size of the mesh is 0.1 to 0.3 탆.

In the present invention, a plurality of incubation units (200) are placed upright at regular intervals to maximize the adhering surface to which sticky diatoms can be attached. As shown in FIG. 3, the culture unit is formed long in one direction, and is arranged vertically with respect to the ground so that more diatomaceous attachment surfaces can be formed in a limited space. In order to complete such a structure, a plurality of incubation units 200 should be arranged vertically in the space formed inside the culture frame 100 so that the attachment substrates do not touch each other at a constant interval. In this case, the self-shading problem can be solved while maximizing the adhering surface capable of adhering the sticky-tidal algae, and the breeding can be smoothly performed by the lower aeration.

For this purpose, a spacer 213 is formed between the culture units 200. The spacers 213 may be formed by extruding the culture unit frame 210 in the form of a rod with the culture unit frame and may be inserted into the connection through holes 212 formed in the adjacent culture unit frames, . The connection between the spacer and the connection hole is maintained at a constant distance between the culture units, and the culture units are connected to each other in the culture frame 100 so as to be fixed so as not to collapse. The spacer may be formed separately from the culture unit frame. Alternatively, only a through hole may be formed in the culture unit frame, and a bead-shaped spacer may be separately inserted between the culture units while passing through a wire or the like (not shown). In any form, it maintains a constant spacing between incubation units and supports and supports the incubation unit.

The culture unit frame may be formed of any one of polyvinyl chloride, polypropylene, polyethylene, wood, rubber, or steel use stainless steel. The frame may be formed by injection molding in an upper or lower or left and right assembling unit made of polyethylene or polypropylene Thereby reducing manufacturing cost and facilitating assembly and management. In an embodiment of the present invention, the culture unit frame a (a) and the culture unit frame b (b) are fabricated and assembled to form a culture unit frame. And the manufacturing cost.

12 is a perspective view showing the configuration of the gas supply unit. The adhered diatom culturing apparatus according to the present invention can sufficiently supply the feed water and the gas to the adhered substrate arranged densely vertically by uniformly supplying the gas from the bottom. A bottom frame foot 110 is attached to the lower part of the culture frame 100 to form a space by separating the culture frame from the bottom of the tank, and the gas supply part 300 is positioned there. The culture unit 200 is disposed above the gas supply unit 300 and is provided with a support bar (not shown) on the lower part of the culture frame 100 to stably raise the culture unit and reduce the load due to the culture unit to the gas supply unit 300 Time) can be installed. However, since the incubation unit is slightly floated by the bubbles during the supply of the gas, the gas supply part is not damaged by the incubation unit.

The gas supply unit 300 includes a plurality of wide openings 310 arranged at regular intervals along the lower portion of the culture frame 100 and connected to the gas supply pipe in a 'T' 'shape at the distal end of the wide openings 310 A connection pipe 330 and a gas supply pipe 340 connected to the connection pipe. The gas supply pipe 340 is connected to an air pump or an air tank installed outside the water tank.

A gas through hole 320 is formed at an upper portion of the width organ 310 at regular intervals so that the air bubbles rise evenly from the bottom surface of the water tank to the top. The diameter and number of gas holes can be adjusted differently depending on the gas pressure. 13 is a photograph showing the application of the adhesive diatom culturing apparatus according to the present invention to an outdoor water tank. A culture unit 210 is installed in the culture frame 100 and a gas supply unit 300 is installed in the lower part. Depending on the size of the water tank, a plurality of culture apparatuses can be installed to increase the efficiency of attachment and growth. The adhesive diatom culturing apparatus of the present invention can also be applied to an indoor water tank. In this case, a lighting apparatus, a heating apparatus, and the like can be further installed.

Aquatic environment measurement system (s300) that constitutes the collection and production management system of aquaculture food bio-culture information can measure the water environment information of a farm using portable measuring instruments or measure water temperature, DO, salinity and pH information of aquaculture tank in real time In the event of an anomaly, early warning will be collected, and a lot of information in the aquarium will be collected, stored and analyzed in real time to understand the growth status of the farm and display the growth information in real time.

The radiation measuring apparatus (s400) monitors the use water through a radiation measuring sensor provided in the seawater tank of the farm, and installs a radiation sensor inside the seawater tank to draw and store the seawater to supply water to the aquarium, Determine whether radioactive contamination of water is present.

On the other hand, the information corresponding to the radioactivity contamination inside the seawater tank measured by the radiation measuring apparatus (s400) is transmitted to the pond tank managing apparatus s200, or the communication network s500 is transmitted to the integrated control server s600, The situation will be dealt with.

The communication network s500 is interlocked with the aquaculture environment unit s100, the aquaculture water tank management unit s200, the water quality environment unit s300, the radiation measurement unit s400, and the integrated control server s600, And provide a communication network for collection and production history management.

The communication network s500 may be a next generation wired and wireless network for providing Internet or high-speed multimedia service. The communication network s500 is a high-speed network of a large communication network capable of large-capacity, long-distance voice and data services. When the communication network s500 is a mobile communication network, it may be a synchronous mobile communication network or an asynchronous mobile communication network.

As an embodiment of the asynchronous mobile communication network, a WCDMA (Wideband Code Division Multiple Access) communication network is exemplified. In this case, although not shown in the drawing, the communication network s300 may include a Radio Network Controller (RNC). On the other hand, although the WCDMA network has been exemplified, it can be a next generation communication network such as a 3G LTE network and a 4G network, or an IP network based on other IP. The communication network s500 includes the aquaculture environment device 100, the aquaculture water tank management device s200, the water quality environment device s300, the radiation measurement device s400, the integrated control server s600, the history management device s700, Terminals, and other systems to each other.

The integrated control server (s600) is provided with an integrated control status board to monitor the internal real-time image of each of the aquarium tanks transmitted through the communication network (s500), inquire the status information of the aquarium before the aquarium, , Water tank growth status, water quality sensor measurement information, and growth image.

At this time, the integrated control server (s600) is equipped with integrated control software algorithm to monitor real time video in the aquaculture tank, information on the growth status of the entire aquaculture tank, information on the growth information of each group, information on the status of water level by each water tank, , Real-time environment information and external linkage information are displayed.

The history management apparatus s700 stores the history of the radioactivity test history of the aquaculture use water, the production information of the aquaculture organism, the information on the incoming and outgoing shipments, and the farm field information transmitted through the communication network s600, A tag designed to provide an information inquiry is attached to the tail of the aquatic organism as a QR code to record historical information on the production, movement and sale of aquaculture. At this time, the radioactivity test history of the QR code attached to the history management device (s700), the production history of the aquaculture creature, the input / output, and the history information of the farm are configured to enable the production history inquiry through the application of the user terminal s800.

The user terminal s800 may monitor the status of the farm environment information according to the farm, farming environment, and growth environment information transmitted from the farm environment device s100, You can check the history of radioactivity of the code, the production of aquaculture, the history of the incoming and outgoing fisheries, and the information of the stored history of the farm through a dedicated application. FIG. 3 is a block diagram showing the hardware state of a farm management system for collecting and managing information on the growth of aquaculture tank in accordance with the present invention, wherein the farm management system s200 comprises materials (SUS, PE, etc.) , It is constructed to be able to manage the whole in indoor by linking with the growth management SW, the water tank comprehensive status display unit, and the integrated control status board as well as the water tank management unit so that the input can be easily inputted considering the input convenience of the operator. It is possible to immediately collect the production history data at the same time as the work is inputted directly on the field, and it is possible to solve the data input error due to the dualization of the water tank management personnel and the computer management personnel. Personnel can provide management efficiency by checking input.

The water quality device (s300) measures and collects water quality information through the water temperature, DO, salinity, and pH sensor of the farm in order to monitor the water tank of the farm, monitors the water level information of the farm through the sensor, And transmits the water quality sensor and the water level sensor real time measurement information through the water tank management unit and transmits the water quality sensor and the water level sensor real time measured information through the transmission module.

The integrated control server (s600) is provided so that the integrated status of the pond water tank is displayed so that the pond status of each pond can be seen at a glance. The information on the pond status inputted through the pond water tank management device (s200) And the real-time sensing information received through the monitoring sensor of the water quality environment device s300 is displayed for each position, and is displayed in association with the radioactive contamination degree measuring sensor through the radioactivity measuring device s400 to inquire whether the radioactivity is contaminated .

In addition, the integrated control server 600 monitors the inside of the aquaculture tank in real time to display a graph of the current state of the aquaculture growth status information, the water quality sensing data of each aquaculture group, Water quality sensor measurement information, and growth image, and it is provided with an integrated control software algorithm so as to efficiently share work and simplify tasks.

FIG. 4 shows a state diagram of a shrimp tank management apparatus of a shrimp aquarium tank growth management system and a production history management system according to the present invention. The shrimp tank management apparatus s200 includes an input dial or a keypad It will alert the administrator in case of abnormality of water quality measurement sensor interface, RJ45, RS485 communication module, sensing data transmission module, video information transmission and water quality environment information to prevent mass death.

FIG. 5 is a state diagram of a bio-tag for a biohazard system of a biohazard information collection system and a production history management system according to the present invention, in which a QR code tag is produced so as to minimize aquatic organism skin damage and sequential QR code generation and shipment And can be confirmed through the production history inquiry application of the user terminal 800 and the information of the radiation inspection result is stored in the tag of the history management device.

FIG. 6 is a state diagram showing the interlocked state of the radiation measuring device and the integrated control server of the farming water tank collecting information and production history management system according to the present invention, and a radiation measuring sensor is installed considering the optimal installation location and fixing method By implementing a radiation sensor measurement module, it is configured to be a wireless transmission of measurement information and an interface for each sensor.

FIG. 7 is a view showing the state of the comprehensive status board of a pond water tank of the integrated control server of the farm water tank collecting information and production history management system according to the present invention, displaying the radioactive contamination level, displaying a warning light when the risk value is reached, Display of warning data, display of sensed data of sensor installed in each tank of the water tank, display of the growth status (acceptance, acceptance, flatness, weight, etc.)

100: Aquaculture environment device 200: Aquaculture tank management device
300: Water quality device 400: Radiation measuring device
500: Network 600: Integrated control server
700: history management device 800: user terminal
900: Sales device

Claims (2)

It is installed in one side of a farm and fishery environment and observes water temperature, dissolved oxygen amount, salinity, Ph, turbidity closely related to growth based on temperature, wind speed, direction, humidity, , A farm environment device (100) for predicting the growth environment of aquaculture through sea water supply and providing information on growth and growth environment of a farm environment, a fishery environment and growth environment information;
The monitoring information of each fish tank can be collectively monitored for the fishery status information of each fish farm in the farm environment device 100. The real-time sensing information received through each of the water tank monitoring sensors is displayed for each location, Display of radioactive contamination, display of radioactive contamination level, warning lamp when danger level is reached, warning lamp when water level reaches by each water tank, display of sensed data of sensor installed by each city, display of current status of weight gain, flatness, weight A shrimp basin management device 200 for displaying on-the-same-day habitat information;
Measures the water environment information of aquaculture farm using portable meter or measures water temperature, DO, salinity and pH information of aquaculture tank in real time, and makes early warning when abnormality occurs or collects, stores, A water quality environment measuring device 300 for analyzing the state of the growing of the farm, analyzing the growth information in real time, and displaying the information;
Monitoring of the water used by the radiation measurement sensor in the seawater tank of the farm and installing a radioactive sensor inside the seawater tank to draw and store the seawater to supply water to the aquaculture tank, A radiation measuring device 400;
Monitoring the internal real-time image of each pond tank through the communication network 500, displaying the status information of the pond before the pond, analyzing the water quality data and the trend graph of each pond, An integrated control server 600 for controlling information and a growing image;
A record of the radioactivity test history, aquaculture production information, incoming and outgoing information, and aquaculture information transmitted through the communication network 600, and a tag created to provide the user with a production history information inquiry about the produced aquarium A history management device 700 for attaching the QR code to the tail portion of the aquaculture to record history information on production, movement, and sale of aquaculture; And
Monitoring the situation of the farm environment information according to the farm site, the growth information of the fishery environment and the growth environment information transmitted from the farm site environment device 100, or monitoring the history of the farm site environment information, the history of the radioactivity of the QR code attached to the history management device 700, And a user terminal (800) for confirming stored history information of the production, input, output, and farming of a living creature through a dedicated application.
The apparatus for managing aquaculture water tank according to claim 1, wherein the aquaculture tank management apparatus (200) collects image information of aquarium fish in aquaculture farm or measures water quality of DO, salt, pH, And transmits the information to the user terminal when the danger level is reached or displays the water quality sensor and the water level sensor real time measurement information through the water tank management unit and transmits the water quality sensor and the water level sensor real time measurement information transmission,
The culture tank has a culture frame in which a transverse member, a longitudinal member and a column are connected to form a certain space therein; A plurality of culture units having an attachment substrate capable of attaching diatoms to an inner space formed by the culture frame and disposed perpendicularly to the ground surface; And a gas supply unit formed below the culture unit in parallel with the ground to supply gas to the culture unit.

Images