KR20170002032A - shrimp nursery - Google Patents

Abstract

The present invention relates to a cultivating shrimp fishery management system. The present invention includes: an inspection process displayed in wired manner; a transmission process for wireless transmission; a monitoring process; and a remote control process of monitoring received data in real time and stored data. The present invention enables effective management of cultivating shrimp fishery by securing an optimum management condition.

Description

Shrimp nursery management system of festival shrimp farm

The present invention is to quantitatively inject Korean traditional festival-type aquaculture microorganisms into a farm and quantitatively inject them into a farm to quantitatively measure the environmental condition of the farm in order to maintain the bacterial concentration in the farm, This is a management system of a shrimp farm which overcomes the influence of rainfall.

Most of the shrimp culture suitable for the characteristics of the west coast of Korea is cultivated in open ponds entirely in the sunshine and flourishing algae communities. This is because the shrimp-based feces, myeonji feed, and nitrogenous wastes are purified and oxygen is supplied It has been confirmed that shrimp consume some essential nutrients from algae, and algae purifies pond water.

However, for successful breeding, it is necessary to maintain its breeding status, but this is actually very difficult.

In particular, there is a demand for technology for cultivating prawns, which is highly formal, and bio-floc, and bio-floc systems, The development of a bio-floc system in Korea that is free of water changes in other climatic conditions is urgently required in the shrimp farming industry.

In addition, it is necessary to develop a biofrok system in Korea, and it is necessary to develop a standard process that can popularize aquaculture microorganism, water quality management, biological management and monitoring for a festival shrimp farm, There is a desperate need for a farm management system that notifies the administrator of the office and the remote site, and enables the remote site to deal with the corresponding information.

Korea Patent Registration No. 10-01270631 Korea Patent Registration No. 10-01497119 Korean Patent Registration No. 10-01363623

The present invention aims at constructing an interface app for automatic monitoring and managing a wireless communication sharing platform in order to efficiently manage the management of a festival farm where a Korean biofloat system is applied in a nearby location or a remote place.

In addition, the present invention can monitor shrimp culture microorganism, water quality management, biological control and monitoring system in shrimp farm where Korean type biofloat system is applied, and it is possible to cultivate shrimp economically regardless of the climate of Korea, It is aimed to develop a standard process.

In order to achieve the above-mentioned object, the present invention provides a pond of a shrimp farm, which is installed in a pond of a shrimp farm, and the water quality data obtained through a measurement sensor of a probe for measuring the water quality of the pond and the micro- To be displayed through a wired line; A pouring step of informing the pond water quality data obtained in the pouring step by informing the pond pond members of the pond by wirelessly transmitting the pond water quality data to the management panel, And observes the received water quality environment data and stored shrimp culture environment standard data in real time to display a history of occurrence of abnormality in the presence or absence of abnormality on the monitor of the management server member, A monitoring step of notifying the occurrence of abnormality; A remote control step of allowing an administrator to connect to a management server member at a remote place via a manager communication device pre-inputted to the management server member and to monitor real-time received data and stored data; If the water quality data information received in real time with respect to the monitoring result is input as information that is not in accordance with the shrimp form environment standard data stored in the management server member, the calculated value is calculated from the shrimp form environment standard data of the management server member, Including the operational process of

Further comprising a communication step of controlling the state in which the water quality data of the pond is transmitted in real time from the Pacific panel member, receiving and monitoring the water quality data of the pond in the management server, So that the object is achieved.

In the configuration in which the object of the present invention is achieved, the water quality environment data of the shrimp farming microorganism is characterized by pond water quality information such as water temperature, pH, DO, salinity and the distribution state of useful microorganisms contained in water quality.

In the configuration in which the object of the present invention is achieved, the management server member observes the received water quality environment data and the stored shrimp style environment standard data in real time, and when the abnormality occurs, an alarm sound is sounded in the management server member, And an abnormality presence / absence statement is sent to the input manager communication device by a character and a notification.

In the configuration in which the object of the present invention is achieved, the manager communication device can be automatically monitored based on signals transmitted from the management server member, such as setting an automatic alarm environment, inquiring data by time, remote control commands, And downloading an interface app that can receive all the data.

In the configuration in which the object of the present invention is achieved, the communication step may include: a sensor unit for establishing a two-way communication sharing platform in the management server member and connecting the platform to the external environment for measuring the external environment; And a GPS receiver, a main control unit, and a power supply unit are modularized to facilitate maintenance and installation of the wireless data communication unit.

In the configuration in which the object of the present invention is achieved, the wireless communication for data communication between the Pacific panel member and the management server member can be realized by real-time data communication through the radio frequency of the ISM band band A data communication system using CDMA when the communication distance of both is 1 km or more and a communication system using a CDMA modem of 800 MHz band when the distance is about 20 km from the coast and a lighthouse repeater if the distance is up to 50 km .

According to the structure of the present invention as described above, the shrimp farm is not easy to access the form managers due to its geographical characteristics, and it is difficult to provide a uniform farming environment due to its wide management area, By establishing an application and establishing a communication and sharing platform with stability and security, it is possible to maintain the microorganism dominant in the festival farm and to establish the optimum management conditions, so that efficient management can be carried out in the best conditions even in the harsh environment. will be.

In addition, since the festival-style shrimp farm is implemented in a bidirectional ubiquitous base management system, it is possible to select the species with the best maturity of the barley shrimp and P. vannamei, , And P. vannamei can be harvested in the middle of August or early September and can be harvested and cultivated at the beginning of November. Therefore, there is an advantage that the income of the fishermen can be improved and the new shrimp culture technology base is provided.

FIG. 1 is a state diagram for the inspection process in a farm management system to which the present invention is applied.
FIG. 2 is a state diagram for a dispensing process and a monitoring process in a farm management system to which the present invention is applied.
FIG. 3 is a diagram illustrating a state of on-site installation and operation of a two-way communication configuration among the farm management systems to which the present invention is applied.
FIG. 4 is a diagram illustrating a communication process configuration for a remote control and monitoring state among the farm management systems to which the present invention is applied;
5 is a state diagram of a wireless communication process by distance in a farm management system to which the present invention is applied.
FIG. 6 is a state diagram of a Korean biofloat system interlocked with a farm management system to which the present invention is applied.

The following detailed description of the invention refers to the accompanying drawings, which illustrate, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, certain features, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with one embodiment. It is also to be understood that the position or arrangement of the individual components within each disclosed embodiment may be varied without departing from the spirit and scope of the invention.

The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is to be limited only by the appended claims, along with the full scope of equivalents to which such claims are entitled, if properly explained. In the drawings, like reference numerals refer to the same or similar functions throughout the several views, and length and area, thickness, and the like may be exaggerated for convenience.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, so that those skilled in the art can easily carry out the present invention.

FIG. 1 is a state diagram of the inspection process in a farm management system to which the present invention is applied, and is installed in a pond of a shrimp farm where a Korean biofrock system is applied. The water quality of the pond to which EM activated fluid is administered, A water inspecting step A for allowing the water quality data obtained through the measurement sensor 110 of the probe member 100 to be transmitted to the Pacific panel member 200 installed around the pond through a wire is provided.

In the measuring process (A), the measuring sensor 110 is installed in contact with the water surface. The measuring object 110 measures the water environment, and the object to be measured is a water temperature, pH, conductivity, DO, etc., A temperature sensor, a pH sensor, a conductivity sensor, and a DO sensor are provided on the probe member 110.

The EM activated solution is prepared by mixing 600 L of filtered seawater, 400 L of fresh water, 20 L of EM raw solution and 20 Kg of molasses, and culturing the microorganism at 30 ° C for 1 week. The EM activity solution cultured in the microorganism is mixed with Bacillus subtilis , And it is preferable to be administered to the pond in a state in which 1000 L of the EM activated liquid (L) is mixed with 100 L of the photosynthetic bacteria for water quality improvement so as to become the bioflak stock solution.

FIG. 2 is a state diagram for a dispensing process and a monitoring process in a farm management system to which the present invention is applied.

(B) for informing the water quality environment data of the pond obtained in the water inspecting step (A) on the Pacific panel member (200) to be transmitted wirelessly.

A corresponding value measured through each sensor provided in the probing member 110 of the gating step (A) is transmitted to the Pacific panel 200 through the probe member 110.

Therefore, in the Pacific panel 200, the water quality data of the pond 500 is displayed. As described above, the water quality environment data displayed on the Pacific panel 200 is transmitted to the management server member 300 side of the management office in a state of being informed by the Pacific panel 200.

The water quality environment data sent from the Pacific panel member 200 is stored in the management server member 300 storing the shrimp culture environment standard data and is displayed on the monitor 320 of the management server member 300 .

The management server unit 300 is configured to receive the water quality data to be transmitted in real time from the dispenser panel 200 and display the same on the monitor 320 in order to compare the shrimp form environment standard data with the stored shrimp form environment standard data.

The management server member 300 is provided with a monitoring step C for displaying abnormality occurrence details on the monitor 320 and notifying the administrator communication device 500 of the abnormality in advance.

In the monitoring step (C), an interface app is constructed so as to enable automatic monitoring and is mounted on the management server member (300). This web interface includes various functions to enable automatic monitoring such as automatic alarm configuration, time-based data retrieval, remote control command, and basic information management based on signals transmitted from a farm monitoring hardware device.

FIG. 3 is a diagram illustrating a state of on-site installation and operation of a two-way communication configuration among the farm management systems to which the present invention is applied. FIG. 4 is a diagram illustrating a communication process configuration for a remote control and monitoring state among the farm management systems to which the present invention is applied,

The interface application of the monitoring process C can be downloaded to the manager communication device 500 of the information pre-inputted to the management server member 300 and the display status of the management server member 300 can be automatically monitored.

In a state in which the interface app is downloaded to the manager communication device 500, the manager connects to the management server member 300 at a remote location through the communication step (F) and monitors the water quality environment data and stored data received in real time A remote control process (D) is performed.

The interface application to be downloaded to the manager communication device 500 includes a selection item such as an automatic alarm environment setting, a time data inquiry, a remote control command, and a basic information management on the basis of a signal transmitted from the management server member 300 So that all the data is transmitted to the manager communication device 500 and can be automatically monitored.

If the water quality environment data information received in real time with respect to the monitoring result is input as information that is less than the shrimp culture environment standard data stored in the management server member 300, And a stable value is displayed on the monitor 320.

In the process in which the received water quality data and the stored shrimp aquarium environment standard data are compared, the shrimp aquarium environment standard data is determined as an anomaly with respect to a measurement value that is not compared with a measurement value that is less than the reference value, 300), and an operation process (E) for notifying the management communication device (500) side by letter or notification is provided.

The management server member 300 is provided with a communication process F for establishing a communication sharing platform having stability and security between the Pacific panel member 200, the management server member 300 and the manager communication device 500 .

 The communication process (F) is integrated with the sensor unit, the wireless data communication unit, the GPS receiving unit, the main control unit, and the power supply unit so as to facilitate maintenance and installation.

In the communication step (F), it is preferable to develop user-oriented application software by applying a quality control (QC) algorithm capable of wirelessly transmitting environmental data of a farm site to a user by developing GUI-based application software.

FIG. 5 shows a state of a wireless communication process according to distance in a farm management system to which the present invention is applied, in which water quality environment data of the pond is transmitted in real time from the Pacific panel member 200, A communication process (F) for controlling the state of receiving and monitoring the water quality data of the pond in the pond and controlling the state of being linked with the manager communication device 500 at a remote site includes wireless communication hardware and communication; When the distance from the measuring station where the receiver is installed is close to several hundred meters, real-time data transmission through radio frequency is possible, so the communication method of the ISM band band is applied,

second ; When a communication distance of 1 km or more is required in the farm, data communication method using CDMA is applied.

third; When a communication distance of about 20 km or more is required in a farm, a communication method utilizing a CDMA modem of 800 MHz band is applied,

fourth; If a communication distance of 20 km or more is required in a farm, recently, a communication method using a lighthouse repeater is applied to extend the communication distance. In this case, communication can be performed up to 50 km.

FIG. 6 is a state diagram of a Korean biofloat system interlocked with a farm management system to which the present invention is applied. FIG. 6 illustrates an example in which a shrimp farm management system of the present invention is installed in association with a farm where a culture facility driven by a biofrock system is installed. However,

It is possible to observe the sleeping environment data in real time in the farm and control the concentration of bacteria injected into the pond in response to the judgment result, thereby achieving the aquaculture environment overcoming the influence of the daytime difference, temperature difference, seasonal change and rainfall.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is to be understood that the invention may be embodied in many other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

100: probe member 110: measurement sensor 200:
300: management server member 320: monitor 500: manager communication device

Claims (8)

The water quality of the pond in which the EM activated fluid is administered and the water quality environment data obtained through the measurement sensor 110 of the probe member 100 for measuring the microbial state are installed in the pond of the shrimp farm, (A) which causes the panel member (200) to be displayed through a wire;
A feeding step (B) of informing the water quality environment data of the pond obtained in the measuring step (A) on the Pacific panel member (200) so as to be wirelessly transmitted;
The water quality environment data sent from the Pacific panel member 200 is received and stored in the management server member member 300 storing the shrimp farm environment standard data, and the received water quality environment data and the stored shrimp farm environment standard data are transmitted in real time A monitoring step C for notifying the occurrence of abnormality to the manager communication device 500 which has been input in advance and for notifying the occurrence of abnormality in the monitor 320 of the management server member 300, );
A remote control step (D) for allowing an administrator to connect to the management server member (300) at a remote place through the manager communication device (500) pre-inputted to the management server member (300) and monitoring real time data and stored data;
When the water quality data information received in real time with respect to the monitoring result is input as information that is less than the shrimp farm environment standard data stored in the management server member 300, the data is calculated from the shrimp farm environment standard data of the management server member 300 (E) for displaying a stable value on the monitor (320)
The water quality environment data of the pond is transmitted in real time from the Pacific panel member 200 and the state of receiving and monitoring the water quality data of the pond in the management server member 300 and interlocking with the manager communication device 500 at a remote place (F) for controlling the shrimp farm.
The method according to claim 1,
The water environment data on the shrimp farming microorganism is,
Wherein the system comprises the pond water quality information such as water temperature, pH, DO, and salinity, and distribution status of beneficial microorganisms contained in the water quality.
The method according to claim 1,
The management server member (300)
The received water quality environment data and stored shrimp style environment standard data are compared with each other in real time, and when an abnormality occurs, the management server member 300 sounds an audible alarm. At the same time, Wherein the shrimp farm management system comprises a shrimp farm management system and a shrimp farm management system.
The method of claim 3,
In the manager communication device 500,
Downloading an interface app that can receive all the data to enable automatic monitoring based on signals transmitted from the management server member 300, such as automatic alarm configuration, time data inquiry, remote control command, business basic information management A shrimp farm management system.
The method according to claim 1,
The communication step (F)
A sensor unit for establishing a two-way communication sharing platform in the management server member 300, a platform for connecting to the platform for measuring an external environment, a wireless data communication unit for inputting and outputting input data, and a GPS receiver for receiving the data, The management system of the festival shrimp farm where the main control part and the power part are modularized to facilitate maintenance and installation.
6. The method of claim 5,
The wireless communication for data communication between the Pacific panel member 200 and the management server member 300 can be realized by a real-time data communication system through the radio frequency of the ISM band band if the communication distances of both are close to several hundred meters, A communication method using a CDMA modem in an 800 MHz band if the communication distance is about 20 km from the coast, and a lighthouse repeater if the communication distance is up to 50 km. Shrimp farm management system.
The method according to claim 1,
The EM activating liquid may contain,
Filtration seawater 600 L and fresh water 400 L, 20 L of EM raw solution and 20 Kg of molasses are mixed and cultured at 30 캜 for 1 week to become an EM activity liquid.
8. The method of claim 7,
The EM activated liquid (L)
(L) 1000 L of the EM activity liquid (L) is mixed with 100 L of photosynthetic bacteria for improving the quality of water to be bioflavon stock solution.

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