KR20230065396A - Intake amount monitoring system for abalone farm - Google Patents

Abstract

The present invention relates to a system for monitoring the feeding amount of food in an abalone farm, and more particularly, by measuring the weight of an abalone farm, the amount of feeding (kelp, etc.) It relates to an abalone farm feeding amount monitoring system that can be supplied.
The present invention is installed in the floating structure (1) forming each aquaculture space of the cage farm and measures the weight of the abalone aquaculture tank (5) provided in the water below the sea level of each aquaculture space (10); A field control unit 20 installed on one side of the floating structure 1 to receive the weight information measured by the weight measuring means 10; A management server 30 that is connected to the field control unit 20 through a wireless communication network, receives and stores the weight information measured by the weight measuring means 10, and transmits the weight information to the connected client PC 35; A portable terminal 40 connected to the management server 30 through a wireless communication network and accessing the management server through an app to check weight information (data and images) generated by the management server 30;

Description

Abalone farm feeding amount monitoring system {Intake amount monitoring system for abalone farm}

The present invention relates to a system for monitoring the feeding amount of food in an abalone farm, and more particularly, by measuring the weight of an abalone farm, the amount of feeding (kelp, etc.) It relates to an abalone farm feeding amount monitoring system that can be supplied.

In general, more than 100 types of abalone are currently known worldwide, and horse abalone, black abalone, and five bunjagi are distributed along the coast of Korea.

Since the production of artificial seedlings began in earnest, abalone farming has gradually become prevalent, and land tank farming and marine abalone cage farming are mainly used.

The onshore tank farming has a disadvantage in that the survival rate of the abalone patch is as high as 60-70%, easy to manage, and less damage from nature such as typhoons, but requires a lot of operating cost.

On the other hand, although the facility cost is low, the marine cage type farming is difficult to manage, there may be natural damage, and it is difficult to select a suitable site for farming.

Here, in the case of offshore cage farming, abalone farming is provided in each aquaculture space and submerged below the sea level using a connecting rope, and in the case of supplying food, a separate lifting facility is used to submerge it below the sea level. The submerged abalone farming tank is salvaged and raised above the sea level to supply food, and after feeding, the abalone farming tank is lowered again.

At this time, since food such as kelp is supplied to the inside of the abalone farming tank, when the abalone farming tank is lowered and submerged in water, there is no way to accurately determine the amount of feed or to check the amount of remaining food.

Of course, it is possible to roughly estimate the amount of food remaining by looking directly into the sea on the floating structure of the cage farm, but as this is also roughly confirmed, the amount of food cannot be accurately known, so it is eventually necessary to use lifting equipment. It is cumbersome and inconvenient to check after lifting the abalone aquaculture tank by using it, and furthermore, there is a problem with the possibility of a safety accident at sea or a problem with fuel costs due to the need to visit the cage farm frequently.

Publication No. 10-2017-0020175 (2017.02.22. Abalone Farm) Registered Patent Publication No. 10-1814288 (2017.12.26. Farm feed feeding system and method using 3D analysis)

The present invention was devised to solve the above problems, by measuring the weight of the abalone farming tank using a load cell, effectively monitoring the feeding amount of abalone in a remote management server to supply food in time, as well as It is to provide an abalone farm food intake monitoring system that can reduce unnecessary sea movement.

The configuration of the present invention for solving the above problems is installed in the floating structure 1 forming each aquaculture space of the cage farm, and the weight of the abalone aquaculture tank 5 provided in the water below the sea level of each aquaculture space Weight measurement means 10 for measuring; An on-site control unit 20 installed on one side of the floating structure 1 to receive the weight information measured by the weight measuring means 10; A management server 30 that is connected to the field control unit 20 through a wireless communication network, receives and stores the weight information measured by the weight measuring means 10, and transmits the weight information to the connected client PC 35; A portable terminal 40 connected to the management server 30 through a wireless communication network and accessing the management server through an app to check weight information (data and images) generated by the management server 30;

Here, the weight measuring means 10 of one embodiment includes a load cell fixing plate 11 coupled to a selected upper portion of the floating structure 1, a load cell 13 having one side coupled to the load cell fixing plate 11, and , It is coupled to the other side of the load cell 13 and consists of a rope link 14 for binding and fixing the connection rope 6 connected to the abalone farming tank 5.

In addition, the weight measuring means 10 of another embodiment includes a fixed frame 15 installed side by side in an 11-shape on the floating structure 1 or installed in a square frame shape, and the fixed frame 15 The load cell 16, one side of which is fixed to the upper surface of the end or corner portion of the load cell 16, is formed as a rectangular frame body to be located on the upper side of the fixing frame 15, and the lower surface of the corner portion is installed to be coupled with the other side of the load cell 16 It is preferable that the connection rope 6 connected to the abalone farming tank 5 is composed of a connection rope support frame 17 coupled to a selected position.

At this time, a camera 50 is installed on one side of the upper portion of the floating structure 1 to photograph the seawater state and transmit it to the field controller 20.

In addition, an acceleration sensor 55 is installed in the cage farm to measure the X, Y, and Z-axis flow and speed of seawater by being installed at sea level or underwater.

On the other hand, in each aquaculture space of the cage farm, a water temperature sensor 60 and an air temperature sensor 65 are installed to measure the temperature of seawater and air temperature and transmit them to the field control unit 20, and the abalone aquaculture tank 5 A dissolved oxygen sensor 70 is installed to measure dissolved oxygen in the water located and deliver it to the field control unit 20, and to measure the pH concentration of the water where the abalone aquaculture tank 5 is located and deliver it to the field control unit 20 A pH sensor 75 is installed.

According to the abalone farm food intake monitoring system of the present invention having the above configuration, the total weight of the abalone farm including food can be measured using a load cell to calculate the feed amount from the outside, thereby supplying food in time. In addition, it reduces the maritime movement that frequently moves to the maritime cage farm, thereby reducing the fuel cost burden due to maritime movement and preventing safety accidents that may occur.

In addition, by lifting the abalone farming tank at the time of feeding, it is possible to solve the problem of reduced efficiency caused by lifting and checking the abalone farming tank from time to time as the amount of conventional food cannot be accurately grasped, and furthermore, the stress of abalone can be reduced. It has the effect of helping growth by reducing it.

1 is a state diagram showing an abalone aquaculture tank located underwater by a connecting rope of an abalone cage farm;
2 is a configuration diagram showing a system for monitoring the amount of abalone feed in an abalone farm according to the present invention;
3 is a plan state view showing the weight measuring means, camera and field control unit of one embodiment installed in the floating structure of the abalone farm according to the present invention;
4 is an installation structure diagram of a weight measuring means of an embodiment installed in a floating structure according to the present invention;
5 is a structural diagram showing another embodiment of the weight measuring means installed in the cage farm according to the present invention;
6 is a photograph of the weight measuring means of FIG. 5 installed in a floating structure;
7 is a block diagram of monitoring the feed amount of abalone cultivated in each aquaculture space of an abalone farm according to the present invention;
8 is a configuration diagram showing sensors installed in an abalone farm (cage farming) in addition to the feeding amount according to the present invention to transmit measurement information to the field control unit;
9 is an exemplary view showing various measurement information of an abalone farm displayed on a client PC according to the present invention;
10 is an exemplary view showing measurement information of an abalone farm displayed on the app screen of a portable terminal according to the present invention.

Hereinafter, an abalone farm feeding amount monitoring system according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown, the abalone farm feeding amount monitoring system according to the present invention includes a weight measuring means 10 for measuring the weight of the abalone farming tank 5, a field control unit 20 that receives the measured weight information, and , It consists of a management server 30 connected to the field controller 20 through a wireless communication network and receiving information, and a portable terminal 40 carried by a manager.

Prior to the description of the feeding amount monitoring system of the present invention, the abalone farm installed on the sea is installed as a cage farm, and the cage farm is formed of a floating structure 1 floating on the sea.

The floating structure 1 is a floating structure frame 2 that forms a form space 4 in each cell by installing frames formed side by side with each other in an approximate grid form for cage farming, and the lower part of the floating structure frame 2 It is composed of a float (3) that is coupled to and floats on the sea.

The upper part of the floating structure frame 2 is used by a manager covering and fixing a pedestal such as a wide panel so that workers can walk around.

In each aquaculture space 4 of the floating structure 1, an abalone aquaculture tank 5 is installed so as to be positioned underwater below the sea level via a plurality of connecting ropes 6.

The abalone farming tank 5 is composed of a aquaculture structure such as a wave plate structure or a shelter for abalone culture inside, and a case or net made of a net to surround the aquaculture structure.

If the case is provided to cover the aquaculture structure, the connection rope 6 can be connected to the upper corner of the case, and if the case is provided to cover the aquaculture structure using a net, connect the connection rope to the four corners of the net. do.

In the present invention, the weight measuring means 10 is installed in the floating structure 1 forming each aquaculture space of the cage farm, and is connected to the abalone aquaculture tank 5 provided in the water below the sea level of each aquaculture space The weight of the abalone aquaculture tank is measured and the measurement information is transmitted to the field control unit 20.

The weight measuring means 10 constantly measures the weight of the abalone aquaculture tank in a state in which food such as backwater is supplied to the inside of the abalone aquaculture tank 5. At this time, the total weight of the abalone aquaculture tank is reduced due to feeding And based on this reduced weight, it is possible to accurately determine the supply time of food to be supplied later by checking the amount of abalone feeding.

Therefore, it is not necessary to visually check the feeding amount of food by visiting the cage farming from time to time for the supply of conventional food, it is possible to reduce the fuel cost burden of the ship due to frequent visits, and safety accidents at sea that may occur It has the advantage of being able to prevent it in advance.

The weight measuring means 10 is an embodiment, as shown in FIGS. 3 and 4, the load cell fixing plate 11 coupled to the upper selected position of the floating structure 1 and the load cell fixing plate 11 It consists of a load cell 13 to which one side is coupled and a rope link 14 for binding and fixing a connection rope 6 coupled to the other side of the load cell 13 and connected to the abalone farming tank 5. .

The connecting rope (6) connected to the abalone farming tank (5) is bound to the rope link (14), and the load is transmitted to the load cell (13), and the weight of the abalone farming tank (5) is measured by the load cell installed in multiple locations. It can be done.

In the attached FIGS. 3 and 4, the load cell fixing plate and the load cell were installed in a total of four places.

At this time, the weight measuring means of one embodiment is formed individually, and since the connecting rope is connected to each load cell, there is a limit to accurately detecting the weight of the abalone farming tank transmitted through the connecting rope. In order to solve this problem, it can be configured as a weight measuring means of another embodiment below.

As shown in FIGS. 5 and 6, the weight measuring means 10 of another embodiment is a fixed frame 15 installed side by side in an 11-shape or square frame on the upper part of the floating structure 1 And, the load cell 16, one side of which is fixedly installed on the upper surface of the end or corner portion of the fixed frame 15, and the load cell 16 formed in a rectangular frame body positioned on the upper side of the fixed frame 15 so that the lower surface of the corner portion is the load cell ( It consists of a connecting rope support frame 17 installed to be coupled with the other side of 16).

The connection rope 6 connected to the abalone farming tank 5 is coupled to the selected position of the connection rope support frame 17. At this time, a separate rope connecting rod 18 may be further provided inside the corner of the connecting rope support frame 17 to which the load cell 16 is coupled to install the connecting rope, so as to be integrally formed.

As the connecting rope 6 is bound and fixed to the connecting rope support frame 17, the connecting rope support frame supports the abalone farming tank, and all load cells 16 installed on the fixed frame are connected to the connecting rope support frame 17 ), it is possible to accurately measure the weight of the abalone farming tank transmitted through the connecting rope support frame.

In the accompanying drawings, the fixed frame 15 is formed of a rectangular frame body, the load cell 16 is installed on the upper surface of the corner of the fixed frame 15, and the connection rope support frame 17 has a stable connection rope 6. In order to accurately measure the load as well as the installation, it was formed to be equipped with a rope connection (18).

As described above, the weight measuring means can be configured in two embodiments, and as described above, the structure of one embodiment accurately measures the weight of the abalone aquaculture tank as the weight of the abalone aquaculture tank is not accurately transmitted to each of the individually installed load cells There is a disadvantage of low accuracy as errors occur in the measured weight information due to difficulties or limitations.

Therefore, it would be more preferable to measure the weight of the abalone farming tank with a structure using a fixed frame made of a square frame and a connecting rope support frame rather than the structure of one embodiment.

The field control unit 20 may be installed on one side of the floating structure 1 constituting the cage farm, and receives the weight information measured by the weight measuring means 10.

At this time, since power must be supplied to the load cell 16 as well as the field controller 20, a power generation device using natural energy such as sunlight or wind power can be installed in the floating structure 1, and the convenience of construction and It would be desirable to install a solar power generation device for high efficiency.

The field control unit 20 is preferably installed inside the control box, and a communication module is installed for communication with the management server.

The field control unit may be provided with a display device so that the operator or manager can check the weight information of the abalone farming tank. In addition, the display device includes a camera's photographed image, the flow of seawater by an acceleration sensor, the water temperature by a water temperature sensor, the air temperature by an air temperature sensor, the surface temperature of a floating structure by a structure temperature sensor, and the amount of dissolved oxygen by a dissolved oxygen sensor. , the pH value by the pH sensor can be displayed.

In addition, it would be desirable for the display device to display an abnormal state when an operation failure occurs due to damage or breakage of each sensor.

In addition, a warning light may be installed in the on-site control unit 20 so as to sound an alarm or turn on lights so that an abnormal state can be immediately recognized.

The management server 30 is a server installed in an external remote location, and is connected to the field control unit 20 through a wireless communication network to receive and store weight information measured by the weight measuring means 10, and a monitor is separately connected. If there is, the information transmitted from the field control unit through the monitor is displayed on the screen.

Of course, when the client PC 35 is connected to the management server 30, the weight information is delivered to the client PC with the same contents as the information displayed on the monitor.

The management server 30 compares the received weight information with a pre-set standard weight value to determine the feeding time, and basically, the manager checks the weight information displayed on the screen and supplies the food in time.

On the other hand, in addition to the method of direct confirmation by the manager, if the management server itself determines that the supply of food is necessary, it may be configured to inform the manager through the occurrence of an alarm or the like. In addition, in this case, the manager may send a text message to the portable terminal 40 carried by the manager as an app text so that the manager can confirm it.

The portable terminal 40 is connected to the management server 30 through a wireless communication network, downloads the app, and then accesses the management server through the app to check the weight information (data and image) generated by the management server 30. do.

The portable terminal 40 may be a dedicated terminal that communicates with the management server 30, and in addition, a normal smartphone carried by a manager or worker may be used as a manager terminal, and it is possible to access the Internet, such as a tablet, and has portability or A terminal having mobility may be used.

On the other hand, a camera 50 is installed on one side of the upper portion of the floating structure 1 to photograph the seawater state and transmit it to the field controller 20.

In the management server 30, it is possible to check whether a problem has occurred in the seawater, such as turbidity of the seawater and green algae, through the state of the seawater photographed by the camera 50. there is.

In addition, an acceleration sensor 55 may be installed in the cage farm to measure the X, Y, and Z-axis flow and speed of seawater by being installed at sea level or underwater.

The acceleration sensor 55 can measure the flow and speed of seawater, so that if abalone excrement or food debris sticks to the net in the cage farm, it can immediately check if there is a problem with the seawater flow, as well as cleaning Through this, it is possible to prevent or minimize the mortality of farmed abalone by removing obstacles more quickly.

In addition, a water temperature sensor 60 and an air temperature sensor 65 may be respectively installed in each aquaculture space of the cage farm to measure the temperature of the seawater and the air temperature and transmit the measured temperature to the field controller 20 .

By measuring the water temperature and air temperature, if the water temperature is relatively high even though the air temperature is not high, the cause is found and the problem is solved to prevent the growth deterioration of abalone or the death of abalone that may occur due to the rise in water temperature. can increase efficiency.

In addition, a dissolved oxygen sensor 70 is installed in the cage farm to measure dissolved oxygen in the water where the abalone farming tank 5 is located and deliver it to the field controller 20.

By installing the dissolved oxygen detection sensor 70, when the dissolved oxygen goes down below a set value, the cause can be found and resolved or oxygen can be supplied directly to prevent mass death of abalone that may occur due to a decrease in dissolved oxygen. there will be

In addition, a pH sensor 75 may be installed in the cage farm to measure the pH concentration of the water where the abalone aquaculture tank 5 is located and transmit it to the field control unit 20.

By installing the pH sensor, it is possible to check the pH value reduced by carbon dioxide emitted by the metabolism of abalone, and when it goes down below the set value, the cause is found and the problem is solved, which can be caused by the decrease in pH value. It has the advantage of being able to prevent the mortality of abalone.

1: floating structure 2: floating structure frame
3: Bougu 4: Aquaculture space
5: Abalone farming tank 6: Connecting rope
10: weight measuring means 11: load cell fixing plate
13: load cell 14: rope link
15: fixed frame 16: load cell
17: connecting rope support frame 18: rope connecting rod
20: field control unit 30: management server
35: client PC 40: mobile terminal
50: camera 55: acceleration sensor
60: water temperature sensor 65: air temperature sensor
66: structure temperature sensor 70: dissolved oxygen sensor
75: pH sensor

Claims (10)

Weight measuring means (10) for measuring the weight of the abalone farming tank (5) installed in the floating structure (1) forming each aquaculture space of the cage farm and provided in the water below the sea level in each aquaculture space;
A field control unit 20 installed on one side of the floating structure 1 to receive the weight information measured by the weight measuring means 10;
A management server 30 that is connected to the field control unit 20 through a wireless communication network, receives and stores the weight information measured by the weight measuring means 10, and transmits the weight information to the connected client PC 35;
A portable terminal 40 connected to the management server 30 through a wireless communication network and accessing the management server through an app to check weight information (data and images) generated by the management server 30;
Abalone farm food intake monitoring system, characterized in that consisting of.
According to claim 1,
The weight measuring means 10,
The load cell fixing plate 11 coupled to the upper selected position of the floating structure 1,
A load cell 13 having one side coupled to the load cell fixing plate 11;
Abalone farm feed monitoring system, characterized in that it is composed of a rope connecting ring 14 for binding and fixing the connecting rope 6 coupled to the other side of the load cell 13 and connected to the abalone farming tank 5 .
According to claim 1,
The weight measuring means 10,
A fixed frame 15 installed side by side with each other in an 11-shape or in a square frame shape on the upper part of the floating structure 1;
A load cell 16 having one side fixedly installed on the upper surface of the end or corner of the fixing frame 15;
It is formed as a square frame body to be located on the upper side of the fixing frame 15, and the lower surface of the corner is installed to be coupled with the other side of the load cell 16, and the connection rope 6 connected to the abalone farming tank 5 is located at the selected position Abalone farm feeding amount monitoring system, characterized in that composed of a coupled connecting rope support frame (17).
According to claim 3,
Abalone farm food feeding, characterized in that a rope connecting rod 18 is formed parallel to each other so as to bind and couple the connecting rope 3 to the inside of the corner of the connecting rope support frame 17 to which the load cell 16 is coupled. volume monitoring system.
According to any one of claims 1 to 4,
Abalone farm feeding amount monitoring system, characterized in that a camera 50 is installed on one side of the upper part of the floating structure (1) to photograph the seawater state and transmit it to the field control unit (20).
According to any one of claims 1 to 4,
The abalone farm feeding amount monitoring system, characterized in that the acceleration sensor 55 is installed to measure the X, Y, Z-axis flow and speed of seawater by being installed at the sea level or underwater in the cage farm.
According to any one of claims 1 to 4,
Abalone farm food intake monitoring system, characterized in that a water temperature sensor (60) is installed in each aquaculture space of the cage farm to measure the temperature of seawater and transmit it to the field control unit (20).
According to any one of claims 1 to 4,
An abalone farm feeding amount monitoring system, characterized in that an air temperature sensor (65) is installed in each aquaculture space of the cage farm to measure the air temperature and transmit it to the field control unit (20).
According to any one of claims 1 to 4,
The abalone farm feeding amount monitoring system, characterized in that the dissolved oxygen sensor 70 is installed in the cage farm to measure the dissolved oxygen in the water where the abalone aquaculture tank 5 is located and transmit it to the field control unit 20. System.
According to any one of claims 1 to 4,
Abalone farm food intake monitoring system, characterized in that the pH sensor 75 is installed in the cage farm to measure the pH concentration of the water where the abalone farm 5 is located and transmit it to the field control unit 20.

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