KR102478888B1 - Device for picking laver farming - Google Patents

Abstract

The present invention relates to an overground laver seedling collection device. The overground laver seedling collection device, according to the present invention, comprises: a seedling room (10); a brine tank (20); a rotating frame (30); a temperature control space part (40); a first cooling pipe (50); a cooling means (55); an underwater photographing means (60); a seedling collection state photographing means (65); and a control unit (70). According to the present invention, it is possible to increase a growth rate of spores as well as a seedling rate.

Description

Laver land seeding device {Device for picking laver farming}

The present invention relates to an onshore seaweed seedling device that is disconnected from the outside and can provide an optimal seedling environment within a set temperature.

Seaweed contains a large amount of taurine, which is essential for cholesterol lowering, liver protection, and growth, vitamin B12, which is closely related to brain development, and EPA, which is very effective in preventing adult diseases such as arteriosclerosis, cholesterol accumulation, and high blood pressure. It is an excellent food.

In the process of aquaculture of seaweed, zoospores cultivated in a test tube grow over fall, winter and spring, generating carpospores through sexual reproduction, and carpospores epiphyte on shells, etc., germination begins, and mycelial filaments are created, and the filaments produces spores in the fall through the summer, and the spores germinate and go through the process of growing into normal seaweed.

Seaweed farming is largely divided into marine seedlings, which are naturally drawn in the sea, and land-based seedlings, which are artificially created on land in an environment similar to the sea.

The maritime seedlings are a method in which spores are naturally implanted in the seaweed net thrown into the sea, and although it has the characteristic of being natural, it is impossible to obtain seedlings on the desired date because the breeder cannot secure the desired variety in time. There is a problem in that the number of sporangia attached to the spore net is not controlled, which causes dog disease due to overcrowding.

In order to solve the problem of seedlings at sea, seedlings are collected on land, and the land-seeding method can reliably harvest the varieties desired by the farmer, and can prevent overcrowding by controlling the number of sporangia attached to the gimbal. It has the advantage of being able to mass-produce high-quality seaweed.

As examples of on-land seedling devices, Registered Utility Model Publication No. 20-0412543 (artificial laver seedling machine), Registered Patent Publication No. 10-0762389 (seaweed land-seeding device and method), No. 10-2034354 (seaweed seedling for farming) A spore sorting system from a device and a sorting method thereof) are disclosed.

The Utility Model No. 20-0412543 includes a salt water tank for storing salt water containing shells in which spores are cultured; It is installed in the brine tank and consists of a rotating frame that rotates by power of a hydraulic motor, and the spores floating in the salt water are seeded on the hatchet net by winding the loose net on the rotating frame.

In addition, Patent No. 10-0762389 is configured to further include a temperature control means for adjusting the temperature of brine in the brine tank in a known seedling apparatus, and promotes the growth of spores and increases the efficiency of seedlings through temperature control. .

Both the utility model and the patent are made to draw seedlings in a state exposed to the outside, and accordingly, even if the shell filaments are managed in the same place, the degree of maturity of the shell varies depending on the environmental conditions such as water temperature and air as well as illuminance, and the adhesion rate of spores Of course, the growth also changes, resulting in a decrease in seedling efficiency.

Therefore, in order to increase the efficiency of seedlings, while being disconnected from the external environment, environmental conditions such as internal air temperature and salt water temperature are appropriately controlled, and the temperature is maintained using minimum energy without wasting energy. It is necessary to develop a device that enables this.

Registered Patent Publication No. 10-0762389 (2007.09.20. Apparatus and method for harvesting seaweed on land) Registered Patent Publication No. 10-0594729 (2006.06.22. Drooping type seedling device and method for seaweed farming) Registered Utility Model Publication No. 20-0412543 (2006.03.21. Seaweed artificial harvester) Registered Patent Publication No. 10-2034354 (2019.10.14. System for sorting spores from seedlings for seaweed farming and its sorting method)

The present invention is to solve the above problems, by constructing a seedling working space in a form completely disconnected from the outside, the optimum seedling environment in which the brine temperature can always be maintained at the set temperature regardless of external temperature or wind. It is possible to increase the growth rate of spores as well as to increase the efficiency of seedlings. In particular, when the brine tank is cooled, the cooling air maintains the internal temperature of the seedling work space at a constant temperature without a separate temperature control device. It is possible to minimize energy consumption due to temperature control and maintenance, as well as to provide a seaweed onshore seedling device that can reduce or eliminate unnecessary energy waste.

The solution of the present invention for solving the above problems is a seedling room (10) provided with an entrance door (13) on one side or both sides, and a seedling work space (11) formed indoors so as not to be exposed to the outside by being disconnected from the outside. ); A brine tank 20 installed on one side of the seedling work space 11 of the seedling chamber 10, and having an open upper side and a brine storage space 21 for storing brine therein; a rotating frame 30 installed on the upper part of the brine tank 20 to be rotated by a driving force of a motor, and having a lower part immersed in salt water to collect spores on the rolled gimbal; It is provided to form a certain space at the edge of the brine tank 20, the inner side is provided to contact the brine storage space 21 and the outer side is provided to contact the seedling work space 11 ( 40); A first cooling pipe 50 installed in the temperature control space 40 to lower the temperature of the seedling working space 11 while lowering the temperature of the brine stored in the brine storage space 21; a cooling means 55 installed in the seedling work space 11 to be connected to the first cooling pipe 50; an underwater photographing means 60 installed in the salt water storage space of the salt water tank 20 to check the amount of spores present in the salt water through underwater photographing; Seedling condition photographing means 65 installed on the upper side of one side of the brine tank 20 to check the seedling state of the spores drawn on the gimbal wound around the rotating frame 30; Controls the on/off operation of the cooling means 55, the underwater photographing means 60, and the seedling state photographing means 65, and displays the amount of spores in the salt water and seedling state information on the display unit The control unit 70; consists of.

Here, a second cooling pipe 51 is installed at one side of the brine storage space 21 to be connected to the first cooling pipe 50, and a brine storage space 21 at one side of the second cooling pipe 51. ) A salt water spray pipe 80 equipped with a plurality of spray nozzles 81 is installed to receive the salt water stored in the water and spray it to the surface of the second cooling pipe 51, and inside the salt water storage space 21 A salt water pump 83 is installed to pump the stored salt water and move it to the salt water injection pipe 80.

At this time, the inner surface of the brine tank 20 facing the brine storage space 21 is bent in a pattern set to increase the contact area with the brine, so that the bent portion 22 is formed.

In addition, a plurality of cooling pieces 23 may be protruded and formed at set intervals on the inner surface of the brine tank 20 facing the brine storage space 21 .

On the other hand, an indoor temperature sensor 15 is installed inside the seedling chamber 10 to measure the indoor temperature of the seedling working space 11, and a brine temperature sensor 15 to measure the brine temperature in the brine storage space 21 ( 16) is installed, and a first temperature indicator 17 is installed at a selected part of the inner wall of the seedling work space 11 to display the temperature measured by the indoor temperature sensor 15 and the salt water temperature sensor 16, , It is preferable that a second temperature indicator 18 is installed on the outer wall of the seedling chamber 10 to be interlocked with the first temperature indicator 17 so that the indoor temperature and the salt water temperature can be checked outdoors.

In addition, an agitator 85 is installed at the center of the inner bottom surface of the salt water tank 20 to mix the salt water, and the inner bottom surface of the salt water tank 20 is upward from the center where the agitator 85 is installed to the edge. The guide surface 24 may be formed to be inclined or curved.

On the other side of the seedling work space 11 inside the seedling room 10 of the present invention, a spore curing tank 25 provided adjacent to the brine tank 20 and storing salt water therein is installed, and the spore curing The temperature control space part 40 is formed in a certain space at the rim of the tank 25, and the temperature control space part 40 has a first connection to the cooling means 55 to cool the air in the inner space. It is preferable that the cooling pipe 50 is installed.

According to the on-land seaweed seedling device of the present invention having the above configuration, it is possible to increase the growth rate of spores as well as the seedling rate regardless of the external environment (temperature, wind, etc.) by providing an optimal seedling working environment disconnected from the outside. By supplying cooling air to the brine tank, the internal temperature of the seedling work space where the brine tank is installed maintains a constant temperature without a separate temperature control device, thereby minimizing energy consumption due to the control and maintenance of the brine temperature in the future. This can provide excellent energy efficiency economically.

1 is a state diagram showing a seaweed onshore seedling device in a form disconnected from the outside according to the present invention;
Figure 2 is a cross-sectional structure of a seaweed onshore seeding device according to the present invention;
3 is a partial cutaway perspective view showing a salt water tank and a temperature control space in which a rotating frame according to the present invention is installed;
4 is a schematic structural diagram showing a photographing means moving member according to the present invention;
5 is a state diagram in which a second cooling pipe installed on one side of the inside of a salt water tank according to the present invention and a spray nozzle for spraying salt water are installed in the second cooling pipe;
6 is a state in which the side wall surface of the brine tank according to the present invention is bent in a zigzag shape;
7 is a state in which a plurality of cooling pieces are formed on the inner surface of the brine tank according to the present invention;
8 is a cross-sectional state diagram in which an agitator and an induction surface are formed inside the brine tank according to the present invention;
9 is a control configuration diagram of a seaweed onshore seedling device according to the present invention.

Hereinafter, with reference to the accompanying drawings, a seaweed onshore seedling device according to a preferred embodiment of the present invention will be described in detail.

As shown, the seaweed onshore seedling apparatus according to the present invention has a container or box-shaped structure in which the inside is disconnected from the outside, and access to the inside is possible.

The present invention is a seedling chamber 10, a brine tank 20, a rotating frame 30, a temperature control space 40, a first cooling pipe 50, a cooling means 55, It consists of a photographing means 60, a seedling state photographing means 65, and a controller 70.

The seedling room 10 has a seedling work space 11 formed therein for seedling, and is formed in a container structure so that the seedling work space 11, which is indoor, is disconnected from the outside and not exposed to the outside.

An entrance door 13 is formed on one side or both sides of the chamber 10 for access to the inside.

The brine tank 20 is a tank for allowing spores to implant and seedlings on gimbals, and has a brine storage space 21 in which brine containing spores is stored.

The brine tank 20 is installed on one side of the seedling work space 11 of the seedling chamber 10, and is formed in a substantially rectangular cylinder with an upper side open.

The spores contained in the brine of the brine tank 20 float in the brine, and there is a method of culturing the spores in the shells in advance and then allowing the shells to be directly accommodated in the brine tank, and the tank in which the shells are accommodated It is possible to use a method of bringing brine that has been cultured for a certain period of time and putting it in a brine tank.

One or more rotating frames 30 may be installed on the upper part of the salt water tank 20, and a lower part thereof is provided to be submerged in salt water.

At this time, the rotating frame is installed to be rotated by the driving force of the motor so that only the lower portion of the gimbal is immersed in salt water and the saline water contacts the entire rolled gimbal so that the spores can be effectively attached and seeded as the gimbal is exposed to the saline water.

The temperature control space 40 is provided to form a certain space at the rim of the brine tank 20, the inner side is provided to contact the brine storage space 21, and the outer side is provided to the seedling work space 11 It is provided to come into contact with

The temperature control space 40 may be formed as a certain space not only at the rim of the brine tank 20 but also at the bottom forming the bottom.

In the accompanying drawings, it is shown that the temperature control space is formed only at the edge of the brine tank 20.

The first cooling pipe 50 is installed in the temperature control space 40 and is connected to a cooling means to cool the internal air of the temperature control space to a set temperature by the cooling means.

The first cooling pipe 50 indirectly lowers the temperature of the brine stored in the brine storage space 21 by cooling the air inside the temperature control space 40, and together with this, the seedling working space 11 ) will also decrease the temperature.

A cooling means 55 connected to the first cooling pipe 50 is installed inside the seedling chamber 10, that is, in the seedling working space 11.

The cooling means 55 consists of a cooling device that cools air using a normal cooling cycle.

In the present invention, when the first cooling pipe cools the air in the temperature control space 40 to a set temperature by the cooling means, the salt water storage space 21 of the salt water tank installed adjacent to the temperature control space and the inside The temperature of the brine stored in is lowered, and the temperature of the seedling work space 11 installed adjacent to the temperature control space and the outside is lowered.

That is, the brine storage space and the seedling work space are installed adjacently with the temperature control space 40 interposed therebetween, so that when the air temperature in the temperature control space 40 is lowered, the stored in the brine storage space together with it The salt water temperature and the internal temperature of the seedling working space are lowered.

At this time, as the temperature of the seedling working space is lowered to a certain temperature, even in summer and when the outdoor temperature of the seedling room is quite high, the temperature of the seedling working space, which is disconnected from the outside, does not rise easily, and moreover, the brine storage space The temperature of the stored brine is less affected by the outdoor temperature due to the low temperature of the seedling working space, so it is easy to maintain the set temperature and, as there is no sudden temperature change, it can create an environment suitable for the growth of spores. Significantly lowers the mortality rate of spores or prevents death, and furthermore, it is possible to increase the maturity of spores along with the growth of spores.

In particular, as the seedling operation can be performed under the set temperature conditions, the mortality of implanted spores can be prevented and the efficiency of seedlings can be increased, and the growth and maturity of implanted spores can also increase the efficiency of nori farming due to spores with high growth and maturity. there will be

In the present invention, the temperature of the brine stored in the brine storage space is cooled to maintain 18 to 23 ° C., which is a temperature suitable for culturing and growing spores.

Therefore, the air in the temperature control space 40 should be cooled to have a temperature lower than that of salt water by about 5 to 10 °C.

Here, a second cooling pipe 51 is installed at one side of the brine storage space 21 to be connected to the first cooling pipe 50, and a brine storage space 21 at one side of the second cooling pipe 51. ) A salt water spray pipe 80 equipped with a plurality of spray nozzles 81 is installed to receive the salt water stored in the water and spray it to the surface of the second cooling pipe 51, and inside the salt water storage space 21 A salt water pump 83 may be installed to pump the stored salt water and move it to the salt water injection pipe 80.

This is to inject the salt water stored in the salt water storage space to the surface of the second cooling pipe through the salt water injection pipe, thereby effectively lowering the temperature of the salt water in a shorter time.

That is, the present invention is configured to indirectly lower the brine stored in the brine storage space using the cooling air in a state in which the internal air of the temperature control space formed at the rim of the brine tank 20 is cooled. There may be a problem in that it takes a considerable amount of time to lower the temperature to a desired temperature.

In order to solve this problem, a second cooling pipe 51 is provided, and by directly spraying salt water to the second cooling pipe 51, the salt water can be lowered to a set temperature in a shorter time.

At this time, it may be installed so that the second cooling pipe 51 is immersed in salt water rather than spraying salt water, but in this case, only the salt water around the second cooling pipe 51 is cooled, and the temperature of the entire salt water cannot be lowered in a short time. Therefore, it is preferable to install it in a structure that sprays the pumped salt water in a state not to be submerged in the salt water.

On the other hand, in order to effectively lower the temperature of the brine and maintain the set temperature, the inner surface of the brine tank 20 facing the brine storage space 21 may be formed as a curved portion 22 to be curved in a set pattern. This is to increase the contact area with the salt water by the bent portion, so that the salt water temperature can be effectively lowered and maintained at the set temperature.

In addition, a plurality of cooling pieces 23 may be protruded and formed at set intervals on the inner surface of the brine tank 20 facing the brine storage space 21 . Even in the case of the cooling piece, it is intended to increase the contact area with salt water, and it is possible to effectively lower the salt water temperature and maintain it at the set temperature.

In addition, an agitator 85 may be installed at the center of the inner bottom surface of the brine tank 20 to mix the salt water, and an agitator 85 is installed on the inner bottom surface of the brine tank 20 to increase stirring efficiency. The guide surface 24 may be formed to be inclined upward or curved toward the edge from the center where is installed.

In addition, since the brine tank 20 is formed in a rectangular cylinder, the inner corner of the brine tank is rounded so that the water flows smoothly during stirring, so that the entire brine is uniformly mixed and the stirring efficiency is improved. this is preferable

Here, the stirrer 85 also plays a role of inducing the spores floating in the salt water to be more effectively attached to the gimbal and implanted as the salt water fluctuates or flows in the process of mixing the salt water.

In addition, the internal brine storage space of the brine tank 20 is provided with a submersible pump to generate waves, thereby increasing the movement of spores present in the brine so that the spores can more effectively implant on the surface of the gimbal.

The underwater photographing unit 60 is installed in the salt water storage space of the salt water tank 20 and is provided to check the amount of spores present in the salt water through underwater photography. The image captured by the underwater photographing unit is transmitted to the control unit.

As an example, the underwater photographing unit 60 may be configured as an underwater camera.

Based on the image taken by the underwater photographing means 60, it is possible to check the amount of spores present in the salt water, and depending on the amount of spores, additional spores are introduced or more salt water is supplied so that an appropriate amount of spores is Let it float in salt water.

If the amount of spores floating in salt water is small, even if the gimbal is immersed in salt water for a long time and the seedling work is performed, the amount of spores implanted in the gimbal is inevitably small, so the implantation rate is very low. The amount of spores floating in the salt water It is essential to check, and it is desirable to take images from time to time during the seedling work, as well as to analyze the captured images to check the amount of spores.

The seedling state photographing means 65 is installed on one side of the upper portion of the brine tank 20 and is configured to check the seedling state of the spores drawn on the gimbal wound around the rotating frame 30.

Check the amount of spores drawn through the image taken by the seedling state photographing means, and if the amount of spores is less than the set amount, rotate the rotating frame 30 to additionally implant spores. If it has reached, stop the seedling operation and unwind the gimbal wrapped around the rotating frame.

The gimbal released from the rotating frame is transferred to a separately prepared spore curing tank 25 and subjected to a curing process while being immersed in salt water for a certain period of time.

Curing is not only to increase the rate of spores attached to the gimbal, but also to allow the spores to grow without dying.

In the present invention, the sporulation tank 25 is preferably provided adjacent to the brine tank 20 on the other side of the inner side of the seedling chamber 10, and salt water is stored therein to the extent that the gimbal can be submerged.

Here, the temperature control space part 40 is formed in a certain space like the temperature control space part installed on the edge part of the brine tank 20 at the edge part of the spore curing tank 25, and the temperature control space part A first cooling pipe 50 connected to the cooling means 55 is installed in 40 to cool the air in the inner space.

In the present invention, the gimbal introduced into the spore curing tank and immersed in salt water is not affected by the external temperature as the indoor temperature of the seedling work space is maintained at an appropriate temperature and the salt water temperature is maintained at the set temperature. This will enable effective curing of spores.

In addition, since the spore curing tank 25 is installed adjacent to one side of the brine tank 20, the gimbal wound around the rotation frame of the brine tank can be easily moved to the spore curing tank 25 while unwinding, so the work efficiency is very high. There are good advantages.

The seedling state photographing means 65 may be configured as, for example, a camera, and may be installed in a fixed or movable manner. lose

As an example, as shown in the accompanying drawings, the photographing means moving member 66 is installed side by side with a guide rail 67 installed in the longitudinal or width direction of the brine tank 20 and one side of the guide rail 67 It may be composed of a movement guide shaft 68 having a spiral on its outer circumferential surface and a forward/reverse motor 69 installed at an end of the movement guide shaft 68 to rotate the movement guide shaft in the normal and reverse direction.

A connecting member such as a bracket is coupled to the seedling state photographing means 65, and this connecting member penetrates the movement guide shaft 68 and is installed so as to be spirally coupled. This is to move the seedling state photographing means in the left or right direction along the guide rail.

In the present invention, the seedling state photographing means is preferably installed rotatably so as to adjust the shooting range and direction, and the rotation control of the seedling state photographing means and the operation of the photographing means moving member 66 are controlled by the control unit 70. installed as possible

The controller 70 controls the on/off operation of the cooling means 55, the underwater photographing means 60, and the seedling state photographing means 65, and may be installed inside or outside the seedling chamber.

The control unit 70 may be installed inside the control box so as not to be exposed to the outside, and a display unit may be formed so that a worker can check drawing information.

The display unit can display information on the temperature of the internal working space of the seedling room and the salt water temperature, as well as the amount of spores present in the salt water and seedling state information, and can output images captured by the underwater photographing means and the seedling state photographing means. may be

On the other hand, an indoor temperature sensor 15 is installed inside the seedling chamber 10 to measure the indoor temperature of the seedling working space 11, and a brine temperature sensor 15 to measure the brine temperature in the brine storage space 21 ( 16) is installed, and a first temperature indicator 17 is installed at a selected portion of the inner wall of the seedling work space 11 to display the temperatures measured by the indoor temperature sensor 15 and the brine temperature sensor 16. .

As the first temperature indicator 17 is installed, the manager or operator can easily check the temperature of the seedling working space as well as the salt water temperature, so the room temperature and salt water temperature can be deliberately measured or the control box is opened to display the temperature. Temperature information can be recognized without checking the displayed temperature information.

At this time, a second temperature indicator 18 is installed on the outer wall of the seedling chamber 10 to interlock with the first temperature indicator 17. Due to the installation of the second temperature indicator (18), the manager or worker can check the indoor temperature and the salt water temperature of the seedling chamber from the outside without entering the room, enabling convenient management. It has the advantage of reducing energy consumption as the indoor temperature of the seedling work space does not change as it does not enter the seedlings, and energy waste caused by the inflow of outside air can be reduced as much as the frequent opening and closing of the door is reduced. .

In addition, the present invention can be configured so that a manager or an operator can check seedling information without going directly to the place where the seedling apparatus is installed.

To this end, the control unit 70 is provided with a communication module to transmit drawing information to an external manager server 90 .

The manager server 90 can be installed in a separately prepared manager office or office or a fisherman's house that performs seedling work, and is installed to communicate with the control unit 70 to receive and store information transmitted from the control unit.

When a monitor is separately connected, information received from the control unit through the monitor can be displayed on the screen.

The manager server 90 may sound an alarm or display problem occurrence information on the screen when abnormal state information is received due to a problem occurring in the drawing device through the control unit.

In addition, the manager terminal 91 carried by the manager or worker is connected to the manager server 90, and the information transmitted to the manager terminal is transmitted to the manager or worker through the information displayed on the screen of the manager terminal. You may also be able to verify information.

The manager terminal 91 may be a dedicated terminal that communicates with the manager server 90, 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 like a tablet and has portability. Alternatively, a terminal having mobility may be used.

10: Seedling room 11: Seedling workspace
13: door 15: room temperature sensor
16: salt water temperature sensor 17: first temperature indicator
18: second temperature indicator 20: salt water tank
21: salt water storage space 22: bend
23: cooling piece 24: guide surface
25: sporulation tank 30: rotating frame
40: temperature control space 50: first cooling pipe
51: second cooling pipe 55: cooling means
60: underwater shooting means 65: seedling state shooting means
66: photographing means moving member 67: guide rail
68: movement guide shaft 69: forward and reverse motor
70: control unit 80: salt water injection pipe
81: injection nozzle 83: salt water pump
85: stirrer 90: manager server
91: manager terminal

Claims (7)

A seedling chamber 10 having an entrance door 13 on one side or both sides and a seedling work space 11 formed indoors so as not to be exposed to the outside by being disconnected from the outside;
A brine tank 20 installed on one side of the seedling work space 11 of the seedling chamber 10, and having an open upper side and a brine storage space 21 for storing brine therein;
Rotating frame 30 installed on the upper part of the brine tank 20 to be rotated by the driving force of the motor and having a lower part immersed in salt water so that the spores are landed on the gimbal wound and seeded;
It is provided to form a certain space at the edge of the brine tank 20, the inner side is provided to contact the brine storage space 21 and the outer side is provided to contact the seedling work space 11 ( 40);
A first cooling pipe 50 installed in the temperature control space 40 to lower the temperature of the seedling working space 11 while lowering the temperature of the brine stored in the brine storage space 21;
a cooling means 55 installed in the seedling work space 11 to be connected to the first cooling pipe 50;
an underwater photographing means 60 installed in the salt water storage space of the salt water tank 20 to check the amount of spores present in the salt water through underwater photographing;
Seedling condition photographing means 65 installed on one side of the brine tank 20 and checking the seedling state of the spores drawn on the gimbal wound around the rotating frame 30;
Controls the on/off operation of the cooling means 55, the underwater photographing means 60, and the seedling state photographing means 65, and displays the amount of spores in the salt water and seedling state information on the display unit Seaweed onshore seeding device, characterized in that consisting of; control unit (70).
According to claim 1,
A second cooling pipe 51 is installed at one side of the brine storage space 21 to be connected to the first cooling pipe 50,
At one side of the second cooling pipe 51, a salt water injection pipe equipped with a plurality of spray nozzles 81 to receive the salt water stored in the salt water storage space 21 and spray it to the surface of the second cooling pipe 51 ( 80) is installed,
Seaweed seedling apparatus, characterized in that a salt water pump (83) is installed inside the salt water storage space (21) to pump the stored salt water and move it to the salt water injection pipe (80).
According to claim 1,
The seaweed land-seeding device, characterized in that the inner surface of the salt water tank 20 facing the salt water storage space 21 is curved in a pattern set to increase the contact area with salt water to form a curved portion 22.
According to claim 1,
A seaweed seedling device, characterized in that a plurality of cooling pieces 23 are protruded and formed at set intervals on the inner surface of the brine tank 20 facing the brine storage space 21.
According to claim 1,
An indoor temperature sensor 15 is installed inside the seedling chamber 10 to measure the indoor temperature of the seedling working space 11, and a brine temperature sensor 16 to measure the temperature of the brine water in the brine storage space 21 is installed, and a first temperature indicator 17 is installed at a selected portion of the inner wall of the seedling work space 11 to display the temperatures measured by the indoor temperature sensor 15 and the brine temperature sensor 16,
On the outer wall of the seedling room 10, a second temperature indicator 18 is installed to interlock with the first temperature indicator 17 so that the indoor temperature and the salt water temperature can be checked outdoors. Device.
According to claim 1,
On the other side of the seedling work space 11 inside the seedling chamber 10, a spore curing tank 25 provided adjacent to the brine tank 20 and storing salt water therein is installed,
The temperature control space part 40 is formed in a certain space at the edge of the spore culture tank 25, and the temperature control space part 40 is connected to the cooling means 55 to cool the air in the internal space. Seaweed onshore seeding device, characterized in that the first cooling pipe 50 is installed.
According to any one of claims 1 to 6,
An agitator 85 is installed at the center of the inner bottom surface of the brine tank 20 to mix the brine,
On the inner bottom surface of the brine tank 20, a guide surface 24 is formed so as to be inclined upward or curved toward the edge from the center where the agitator 85 is installed.

Images