KR102050402B1 - A SquarePotor Multi-stage Incubator - Google Patents

Abstract

The present invention relates to a multistage culturing device for conchospore seeds, which cultures conchospores in order to farm laver. The multistage culturing device for conchospore seeds according to an embodiment of the present invention comprises: a multistate type frame which comprises a plurality of pillars stood on a floor and layer guides connecting the plurality of pillars to divide the plurality of pillars by a plurality of layers; cultivation water tanks which are detachably seated in each of the layer guides, receive oyster shells for culturing conchospores and seawater, and have drain holes for draining the received seawater; lightings which are installed at each layer of the multistage type frame and adjust illuminance for culturing the conchospores at upper parts of the cultivation water tanks; water supplying lines which are installed at each layer of the multistage type frame and spray and supply seawater to the cultivation water tanks; and a draining pillar which is used as one of the plurality of pillars and performs drainage by being in connection with the draining holes of the cultivation water tanks seated in the layer guides. Accordingly, a culturing place is minimized to perform massive production, management can be facilitated, and culturing rate can be improved.

Description

Square spore seedling multi-stage incubator {A SquarePotor Multi-stage Incubator}

The present invention relates to a keratin seedling multi-stage culturing apparatus for cultivating keratin spores for farming laver.

In general, seaweed can be harvested from nature, but since there is not much natural harvest, it is farmed and harvested for mass production.

When farming laver, cultivate spores in shells, and cultivate spores on the same foot as the net and grow them in the farm.

On the other hand, it is also important to cultivate laver when cultivating laver, but it is most important to cultivate the spores because the spores are not easily cultivated at low culture rates.

Conventionally, the method of culturing the spores is to fill the culture water with the shells arranged on the bottom of a shallow low water tank or concrete tank installed with a vinyl type for waterproofing the floor, so that the propagation of the spores implanted in the shells takes place. There are a planar culturing method and a drop cultivation method in which a spore is implanted in a shell in a state in which a plurality of shells are threaded through the holes and threaded through the holes in a tank filled with culture water.

However, the drop culture method is preferred because the culture rate is low because the roughness varies depending on the depth of the planar culture method.

However, in the conventional planar cultivation method, the shells are inverted by the sea water supplied or overlapped with each other, and thus the illumination of the shell is irradiated, and it is difficult to wash the shells. There was a problem that the rate is lowered.

In addition, since the shells are arranged to spread widely in the tank, a large area for culturing spores is required, and due to the large area, management is difficult.

KR 1998-016932 A KR 20-0415851 Y1 KR 10-2017-0090205 A

The present invention has been made to solve the above problems, the problem to be solved by the present invention is to minimize the place for culturing the spores, easy to manage, easy to wash the shell, each The present invention provides a multistage culture apparatus for seedling seedlings with high transplantation rate and culture rate.

According to an embodiment of the present invention for achieving the above object, the spore seedling multistage cultivation apparatus includes a layer guide connecting the plurality of pillars so that the plurality of pillars and the plurality of pillars erected on the floor are divided into a plurality of layers. A culture tank comprising a multi-stage frame including, a slit detachably seated on each layer guide and a oyster shell for culturing each spore and a drainage port for receiving seawater and discharging the received seawater, and the culture tank is installed for each layer of the multi-stage frame. Illumination to adjust the illumination for cultivation of each spore from the upper portion of the multi-stage frame is installed in each layer of the water supply line for spraying and supplying seawater to the culture tank, and used as any one of the plurality of columns And a drain column connected to the drain hole of the culture tank seated on the layer guide to perform drainage. It is.

The drainage column may include a drainage connector for connecting the drainage port of the culture water tank seated in each layer and the drainage column to guide the seawater discharged to the drainage port to the drainage column.

The culture tank may include a culture vessel in which the oyster shell is accommodated and disposed in the culture tank, and a plurality of perforation holes are formed so that seawater and foreign substances are easily discharged into the culture tank.

The culture vessel may include a spaced leg to support the culture vessel spaced apart from the bottom of the culture tank to facilitate the discharge of foreign matter and sea water through the perforation hole.

The culture tank may include a culture network in which the oyster shells are arranged and fixed at a predetermined interval so that the oyster shells accommodated in the culture tank do not overlap each other, and each spores are cultured.

The layer guide may be installed to be inclined at a predetermined angle from the plurality of pillars to be seated on the frame so that the frame guide is easily inclined at a predetermined angle toward the drain port of the culture tank.

Except for the drainage column, it may be used as any one of the remaining columns and may include a water supply column for supplying seawater to the water supply line.

The water supply line includes a seawater injector that rotates by the pressure of the seawater supplied through the water supply line and injects seawater toward the culture water tank, and the seawater injector receives seawater from the water supply line and is centered in the water supply line. Rotating injectors are rotatably coupled to the part, and a plurality of the rotatable injectors are coupled along the longitudinal direction of the rotary injector, and the seawater is sprayed in an inclined direction in an opposite direction to rotate the rotary injector. It may include a rotating force providing nozzle to provide.

The lighting may include a seawater cooling passage for cooling by receiving a portion of the seawater supplied to the water supply line.

According to the present invention, by installing a plurality of culture tanks in the multi-stage frame can not only minimize the installation area, but also has the advantage of easy management.

In addition, since water supply and drainage are performed through the column, the pipe that is exposed to the outside can be minimized to minimize the damage of the pipe due to the exposure of the pipe.

In addition, the oyster shells are fixed to the culture network so as not to overlap each other to prevent the oyster shells from shaking due to the movement of seawater, and the oyster shells overlap to prevent a drop in culture rate due to unevenness of illuminance.

In addition, the seawater spray is installed in the water supply line can be sprayed evenly in the culture water tank when injecting nutrients or spores, there is an advantage that can be washed of the oyster shell.

In addition, the water supply line is installed in the water supply line is easy to supply water, there is an advantage that the illumination is easy to adjust the illumination.

Figure 1 is a perspective view showing a keratin seedling multi-stage culture apparatus according to a first embodiment of the present invention.
FIG. 2 is a frontal view showing a keratin seedling multistage culture device according to the first embodiment of the present invention.
Figure 3 is a side cross-sectional view showing a keratin seedling multistage culture apparatus according to a first embodiment of the present invention.
Figure 4 is a plan view showing a multistage seedling seed culture device in accordance with a first embodiment of the present invention.
5 is an exploded perspective view of a culture tank constituting the spore seedling multistage culture apparatus according to the first embodiment of the present invention.
Figure 6 (A) is a perspective view of the drain connector constituting the multistage culture device for seedling spore seedling according to the first embodiment of the present invention.
Figure 6 (B) is a side cross-sectional view of the drain connector constituting the multistage culture apparatus for seedling spore seedling according to the first embodiment of the present invention.
Figure 7 is a side cross-sectional view of the illumination constituting the spore seedling multistage culture apparatus according to the first embodiment of the present invention.
Figure 8 is a perspective view showing a keratin seedling multi-stage culture apparatus according to a second embodiment of the present invention.
9 is a frontal view showing a keratin seedling multi-stage culture apparatus according to a second embodiment of the present invention.

Hereinafter, a first embodiment of the present invention will be described with reference to the accompanying drawings.

As shown in Figure 1 to Figure 3, each spore seedling multi-stage culture apparatus 100 according to a first embodiment of the present invention may include a multi-stage frame (110).

The multi-stage frame 110 can accommodate a plurality of culture tank 120 in a multi-stage form.

The multi-stage frame 110 may include a plurality of pillars 111 and a layer guide 113.

The plurality of pillars 111 may be disposed at each corner of the square in a square shape on a plane, and the plurality of pillars 111 may be embodied as square pipes or circular pipes.

The layer guide 113 may connect and fix the plurality of pillars 111 to each other, and the layer guide 113 may partition the plurality of pillars 111 into a plurality of layers.

On the other hand, the layer guide 113 may be formed to carry in and out the culture tank 120 to be described below to the front of the multi-stage frame 110, the layer guide 113 partitions one layer The layer guides 113 may be spaced apart into a plurality of pillars 111 so as to form a plurality of layers, and the culture tank 120 may be carried in each layer partitioned by the layer guide 113.

In addition, the layer guide 113 forming a layer in the pillar 111 may connect the plurality of pillars 111 in a form of connecting adjacent pillars 111, and the layer guides 113 forming a layer are cultured. The tank 120 may be installed to protrude to the inside of the pillar 111 to be seated.

On the other hand, the layer guide 113 is built up from the end of the layer guide 113 to support the circumference of the culture tank 120 to prevent the departure of the culture tank 120 to prevent the departure of the culture tank 120 to the side of the layer guide 113 This may protrude upward.

At this time, the departure prevention jaw 113a formed in the layer guide 113 is formed on the remaining circumferential side except for the layer guide 113 positioned on one side of the pillar 111 erected in a square, and the departure prevention jaw 113a. Sliding movement of the culture tank 120 through the layer guide 113 is not formed may be carried in, or taken out.

In addition, the layer guide 113 in which the separation prevention barrier 113a is not formed, that is, the culture guide 120 into or out of the layer guide 113 into or out of each layer, is opened in the state in which the culture tank 120 is carried in. The clasp 123 may be installed to prevent the separation of the culture water tank 120.

In addition, the separation guide 113a is not formed, the layer guide 113 is installed so as to be rotatable on both sides of the pillars 111 to be connected to each other around the culture tank 120 in the culture tank 120 is brought in When rotated to position, to prevent the separation of the culture tank 120, and when rotated to escape from the circumference of the culture tank 120, may be configured to be separated from the culture tank 120.

In addition, the culture tank 120 may be formed with a locking portion 122 to which the clasp 123 spans when the clasp 123 is rotated so that the culture tank 120 is not separated.

As shown in Figure 2 and 5, the multi-stage seedling seed culture apparatus 100 according to the first embodiment of the present invention may include a culture tank (120).

The culture tank 120 may accommodate the sea water and oyster shell so as to culture each spore.

On the other hand, the culture tank 120 may be formed in the shape of a rectangular container with an open top, the culture tank 120 is to be carried in each layer partitioned by the layer guide 113 of the multi-stage frame 110. A plurality of multi-stage frame 110 may be stacked and installed.

In addition, the culture tank 120 may be installed in the multi-stage frame 110 in a form seated on the layer guide 113, the culture tank 120 is a departure prevention step 113a in the layer guide 113 forming a layer. ) May be carried in or out of the multi-stage frame 110 in a sliding form to the multi-stage frame 110 through the layer guide 113 is not formed.

In addition, the culture tank 120 may be formed with a drain hole for discharging seawater or foreign matter contained in the culture tank 120, the drain hole may be opened and closed by a drain plug.

At this time, the layer guide 113 in which the culture tank 120 is spread is a portion in which the drain port 121 of the culture tank 120 is formed in the state in which the culture tank 120 is loaded into the multi-stage frame 110 toward the bottom. The floor guide 113 may be installed to be inclined at an angle of about 1 ° to about 5 ° to allow easy drainage.

Here, the culture tank 120 is installed inclined by the layer guide 113, so that the culture tank 120 is slid from the layer guide 113 in order to prevent the sliding away from the latch (installed in the multi-stage frame 110) A locking portion 122 may be formed to span 123.

In addition, the culture tank 120 may further include a culture vessel 125 and a culture network 127.

The culture vessel 125 may be formed in a container shape having an upper portion having a smaller circumference than the circumference of the culture tank 120, and the oyster shell is accommodated in the culture vessel 125, so that the culture vessel 125 has a culture tank 120. Oyster shell in the form that is accommodated in) can be accommodated in the culture tank (120).

The circumference of the culture vessel 125 includes a plurality of penetrated through all or part of the culture vessel 125 so that foreign matter or seawater located inside the culture vessel 125 may be easily discharged to the culture water tank 120. Perforation holes may be formed.

Meanwhile, a plurality of culture vessels 125 may be accommodated in the culture tank 120, and a plurality of spaced legs 126 protrude from the bottom of the culture vessel 125 to protrude a culture vessel from the bottom of the culture tank 120. Spaced 125 may be discharged to the culture tank 120 of the foreign matter in the culture vessel (125).

The culture network 127 may be configured in the form of a lattice network, and the culture network 127 may be fixed with an oyster shell (W) for culturing each spore.

On the other hand, the oyster shells installed in the culture network 127 may be fixed and arranged by arranging the oyster shells at predetermined intervals so that the endothelium of the oyster shell does not overlap each other to face the top.

In this case, the oyster shell W is fixed to the culture network 127 so as not to move to the culture network 127 by a fixing means such as an adhesive or a cable tie, or both ends of each oyster shell W are provided to the culture network 127. After forming a fixing groove that can be fixed across, the oyster shell (W) can be fixed in the form of fitting into the fixing groove, the size of the culture network 127 culture vessel 125 in the culture network 127 unfolded state It may be formed to a size that can be accommodated inside the.

In addition, a plurality of culture networks 127 may be arranged and accommodated in the culture vessel 125, and a plurality of culture vessels 125 in which the culture network 127 is accommodated may also be accommodated in the culture tank 120.

As shown in Figure 1 and 7, the spore seedling multi-stage culture apparatus 100 according to the first embodiment of the present invention may include an illumination (150).

This illumination 150 may provide light for cultivation of each spore.

On the other hand, the illumination 150 may irradiate light toward the culture tank 120 from the upper portion of each culture tank 120 seated in the multi-layer frame, installed in each layer partitioned by the layer guide 113 of the multi-layer frame Can be.

On the other hand, the lighting 150 may include a light source 153 that provides light, the light source 153 may be used to irradiate various types of light, such as fluorescent, incandescent, LED, etc., the first embodiment In the example, the light source 153 is implemented as an LED bar in which a plurality of LEDs are arranged.

(In the drawings, the illustration of the power line for supplying power to the lighting 150 is omitted.)

In addition, the lighting 150 may include a heat sink when the light source 153 of the lighting 150 is implemented as an LED bar.

The heat sink may be installed on the bottom of the light source 153, the center of the heat sink may be a seawater supply passage for supplying seawater, the seawater supply passage to the water supply line 140 to be described below As part of is supplied, the LED can be dissipated by cooling the heat sink.

On the other hand, the heat sink is formed of a semi-circular tube cross-section, the LED bar may be configured in the form of a plurality of arranged on the flat surface of the semi-circle, the LED bar is installed in the portion is installed semi-circular floodlight cover 155 Can be installed to protect the LED bar.

Then, one end of the seawater supply passage is connected to the branch line (140a) branched from the water supply line 140 to be described below, the other end of the seawater supply passage is connected to the drainage column (111a) is supplied to the seawater supply passage heat exchange A drainage line 140b for draining one seawater through the drainage pillar 111a may be connected.

On the other hand, the illumination 150 may be rotatably installed to provide a uniform illumination as a whole in the culture tank (120).

As shown in Figure 1 to Figure 4, each spore seedling multi-stage culture apparatus 100 according to a first embodiment of the present invention may include a water supply line (140).

The water supply line 140 may be supplied to the culture water tank 120 by mixing the spores or nutrients in seawater or seawater.

On the other hand, the water supply line 140 is arranged in parallel with the lighting 150, like the lighting 150 to be supplied in the form of spraying toward the culture tank 120 from the top of each culture tank 120 seated on the multi-layer frame. It may be installed in each layer partitioned by the layer guide 113 of the multi-layer frame.

The water supply line 140 may be provided with a sea water supply valve 143 for supplying or blocking seawater from the water supply column 111b to be described below.

The seawater supply valve 143 controls the water supply line 140 provided for each floor of the multi-stage frame 110 in the water supply column 111b to the culture water tank 120 located in each floor. The seawater may be supplied or blocked through 145.

In addition, the water supply line 140 may be implemented as a pipe for transporting a fluid, and the water supply line 140 may include a seawater injector 145 for injecting seawater.

Meanwhile, a branch line 140a connected to the lighting 150 may be installed at a portion where the seawater is supplied to the water supply line 140 to supply a portion of the supplied seawater to the seawater cooling flow path of the lighting 150.

The seawater injector 145 may rotate in the water supply line 140 to supply the seawater so that the seawater supplied through the water supply line 140 may be uniformly supplied to the culture water tank 120.

Meanwhile, a plurality of seawater sprayers 145 may be installed in the water supply line 140, and the seawater sprayers 145 may include a rotary spraying table 146 and a rotating force providing nozzle 147.

The rotary spray table 146 may be formed in an empty bar shape, and the rotary spray table 146 may have a central portion of the rotary spray table 146 in a state where the rotary spray table 146 is located in parallel with the water supply line 140. 140 may be rotatably coupled.

In addition, the seawater supplied to the water supply line 140 may be supplied to the rotation spray table 146, and a plurality of rotation force providing nozzles 147 may be installed on the rotation spray table 146.

The rotational force providing nozzle 147 may inject the seawater supplied to the rotational injection table 146, and rotates the rotational injection table 146 by the pressure to inject the rotational force providing nozzle 147 into the rotational injection table ( 146 may rotate to spray seawater.

On the other hand, the rotational force providing nozzle 147 has a rotational force providing nozzle 147 located on one side of the rotary shaft and the rotational force providing nozzle 147 located on the other side with respect to the rotation axis rotated by the rotational injection table 146 when spraying seawater It may be installed on the rotary jet stage 146 to inject the seawater inclined downward in the opposite direction to rotate the rotary jet zone 146.

When the seawater sprayer 145 configured as described above is sprayed by mixing the spores or nutrients in the seawater because the rotary spraying table 146 rotates and sprays the seawater when the seawater is sprayed, the spraying of the culture water tank 120 is spread evenly throughout. can do.

As shown in Figure 1 to Figure 3, each spore seedling multi-stage culture apparatus 100 according to a first embodiment of the present invention may include a drain pillar (111a).

The drainage column 111a may drain the seawater accommodated in the culture water tank 120.

Meanwhile, the drainage pillar 111a may be used as any one of the pillars 111 of the plurality of pillars 111, and the drainage pillar 111a may have a hollow pipe shape to perform drainage.

At this time, it is preferable that the drainage pillar 111a uses the pillar 111 closest to the drainage hole 121 among the plurality of pillars 111 as the drainage pillar 111a.

In addition, a drainage hole drained by the drainage pillar 111a may be formed at a lower portion or the bottom of the drainage pillar 111a, and the drainage hole may be drained through a drainage drain or a drainage drainage drainage drainage or drainage. .

And, as shown in Figure 6 (A) and 6 (B), the drain pillar (111a) may include a drain connector (130).

Drainage connector 130 may be installed at each position of each layer in which the culture tank 120 of the multi-stage frame 110 is inserted, drain connector 130 is formed in the shape of the hopper with an open top, drainage connector The side end of the 130 is connected to the drain column (111a) is discharged to the drainage port 121 of the culture tank 120 may be drained by moving to the drain column (111a) through the drain connector (130).

At this time, the portion formed in the hopper shape in the drain connector 130 is located in the lower portion corresponding to the drain port 121 of the culture tank 120 seated in the multi-stage frame 110 to drain the sea water drained to the drain port 121 Can be guided to the pillar (111a), the portion formed in the hopper shape of the drain connector 130 in the state in which the culture tank 120 is seated on the multi-stage frame 110 is in close contact with the lower portion of the culture tank 120 Can be.

In addition, a portion facing the drain port 121 in the drain connector 130 or a portion where the drain connector 130 and the drain column 111a are connected to the drain column 111a from the drain port 121 of the culture water tank 120. Drainage control valve 135 for adjusting the amount of sea water to be drained may be installed.

Then, the upper circumference of the portion formed in the hopper shape of the drain connector 130 is an airtight seal having an elastic force that is airtight between the culture tank 120 and the drain connector 130 is installed drain port 121 and the drain connector 130 Water leakage can be prevented between

Drainage connector 130 is rotatably coupled to the hopper portion around the drainage column (111a) in the drainage column (111a) to position the hopper portion of the drainage connector 130 in the lower portion of the drainage opening 121, or Rotating so as to be separated from the lower portion of 121) to bring in or take out the culture tank 120, or to separate and clean the culture vessel 125 in the culture tank 120, to minimize the work is disturbed by the drain connector 130 can do.

As shown in Figure 1 to Figure 4, each spore seedling multi-stage culture apparatus 100 according to a first embodiment of the present invention may include a water supply column (111b).

The water supply column 111b may supply seawater to the water supply line 140 installed for each floor of the multi-stage frame 110.

On the other hand, the water supply column 111b may be used as any one of the pillars 111 except for the drainage column 111a among the plurality of pillars 111, and the water supply pillar 111b may have a hollow pipe shape.

On the other hand, the water supply column (111b) is connected to the sea water supply facility may be supplied with sea water, the water supply 141 for supplying seawater to the culture water tank 120 in the portion corresponding to each layer of the water supply column (111b) Can be installed.

Here, in the seawater supply facility, not only seawater but also nutrients may be mixed and supplied to seawater, or each spore may be mixed and supplied to each water supply column 111b.

Unlike the seawater injector 145, the water supply unit 141 does not spray and supply seawater, but may rapidly supply a large amount of seawater to the culture water tank 120.

The water supply 141 may be implemented as a faucet to supply seawater to the culture water tank 120 or cut off the supply as the handle of the faucet is opened and closed.

On the other hand, the water supply 141 is rotatably coupled around the water supply column (111b) in the water supply column (111b) so that the end of the water supply 141, the sea water is supplied from the water supply 141 is located in the culture water tank 120 , May be configured to be separated from the culture tank 120.

In addition, the water supply column 111b or the drainage column 111a may include a controller 160 for supplying power to the lighting or cutting off the supply, and the controller 160 may include a water supply column 111b from an external seawater supply facility. A water supply valve may be installed to supply or block seawater.

In this case, the water supply valve may be an electromagnetic valve opened and closed by electronic control of the controller 160.

The operation and effects between the components described above will be described.

Each spore seedling multi-stage culture apparatus 100 according to the first embodiment of the present invention seats the culture vessel 125 inside the culture tank 120, the culture network in which the oyster shell (W) is installed in the culture vessel 125 In a state in which 127 is accommodated, the culture water tank 120 is loaded into each layer of the multi-stage frame 110.

At this time, the oyster shell (W) is installed in the culture vessel 127 so that the culture vessel 125 is located above the culture vessel 125, the culture tank 120 is the prevention of separation from the layer guide 113 of each layer ( 113a) is inserted in the form of slidingly moving the culture tank 120 to the top of the layer guide 113 is not installed.

On the other hand, when the culture tank 120 is inserted into each layer of the multi-stage frame 110, the latch 123 is installed on the pillar 111 to prevent the culture tank 120 is separated from the open layer guide 113. Rotating) is fixed over the engaging portion 122 formed in the culture tank (120).

When the culture tank 120 is seated in the multi-stage frame 110, the drain connector 130 may be located in the lower portion of the drain port 121 of the culture tank 120 and the drain plug is installed in the drain port 121 Remove drain plug.

Then, in order to supply the seawater to the culture water tank 120, the seawater supply valve 143 and the water supply valve are opened to supply the seawater from the seawater supply facility to the water supply column 111b.

The seawater supplied from the seawater supply facility is supplied to the water supply line 140 located at each layer through each water supply column 111b, and the seawater supplied to the water supply line 140 is cultured through the seawater sprayer 145. 120 is supplied in the form of spraying sea water.

At this time, before discharging the seawater to the seawater sprayer 145 and then discharging the seawater washed by the oyster shell (W) by the seawater injected by opening the drainage control valve 135, the drainage control valve 135 By blocking the culture water tank 120, the sea water can be supplied in a form that is confined.

Here, the washing of the oyster shell (W) by the seawater sprayer 145 may be performed periodically, and when the seawater is filled in the culture water tank 120, the water supply 141 may be used instead of the seawater sprayer 143.

When the seawater is sprayed from the seawater injector 145, the seawater may be supplied from the seawater supply facility in a state in which nutrients are included in the seawater or in a state in which spores are included in the seawater.

On the other hand, when the seawater sprayer 145 sprays seawater, the rotational force providing nozzle 147 injects seawater in a direction opposite to each other about the rotation axis of the rotary spraying table 146, and the rotary spraying table 146 supplies water by the spraying force. Rotating in the line 140 and spraying the seawater, so as to wash the oyster shell (W), if the seawater contains nutrients or spores, it is possible to uniformly spray the spores and nutrients.

In addition, when seawater is supplied to the culture tank 120, the illumination 150 may be revealed to provide illumination that is good for each spore to cultivate, and the illumination 150 may adjust illumination according to the culture period differently.

Here, the seawater supplied through the water supply line 140 to the lighting 150 is supplied to the seawater cooling passage through the branch line 140a to cool the lighting 150 and heat-exchange with the lighting 150 in the seawater cooling passage. The heat dissipation of the lighting 150 in the form of being drained to the drain pillar (111a) through the drain line (140b).

On the other hand, when the seawater in which the spores or nutrients are mixed in the rotational force providing nozzle 147 is injected, the spores are implanted in the oyster shell (W) and the transplanted spores are cultured for a predetermined period of time.

During the culturing period, foreign matters may be introduced, and the seawater may be continuously or periodically supplied to the culture water tank 120 through the water supply 141 or the seawater sprayer 145 to minimize decay in stagnant seawater.

Of course, even if the seawater is supplied to the culture tank 120, by adjusting the opening degree of the drainage control valve 135 to maintain the water level of the seawater accommodated in the culture tank 120, the amount of seawater drained to the drainage pillar (111a) Adjust

When the fixation is released, the culture tank 120 is taken out from the multi-stage frame 110, or the culture vessel 125 is separated from the culture tank 120, and the culture net 127 is moved to the nursery to grow the spores. Can be drawn.

Therefore, the seedling spore seedling multi-stage culture apparatus 100 according to the first embodiment of the present invention by culturing the spores in the multi-stage frame 110 in the form of a multi-stage, it is possible to minimize the place required for cultivation, narrow room The spores can be cultured in large quantities at the place, and there is an advantage that it is easy to manage.

In addition, the water supply line 140 and the lighting 150 are installed in the multi-stage frame 110 can provide the optimal environmental conditions that can be cultivated spores, rotation water sprayer is installed in the water supply line 140 The spore spores and nutrients can be sprayed together with sea water to evenly distribute the engraftment efficiency and nutrients of the spores, as well as to wash foreign substances adhering to the oyster shell (W).

In addition, drainage and water supply is performed through the drainage function and the water supply column (111b) to perform the function of the pillar 111 can not only continuously supply fresh sea water, but also has the advantage of easy replacement of sea water, By minimizing the external exposure of the pipe, it is possible to minimize the occurrence of breakage of the pipe caused by leakage of the pipe and the jamming of the pipe.

In addition, a plurality of oyster shells (W) is fixed to be spaced apart at regular intervals in the culture network 127 to minimize the non-uniform implantation of each spore due to the overlap of the oyster shells (W) to improve the culture efficiency of each spores.

Hereinafter, a second embodiment of the present invention will be described. In the second embodiment of the present invention, the same configuration as the first embodiment has the same reference numerals and the same configuration has the same effect and effect, and thus the detailed description is omitted.

The second embodiment is the same as the first embodiment, and does not mount the culture network 127 in the culture tank 120 to the bottom, there is a difference in the mounting method so as to stand vertically in the form of dropping.

As shown in Figure 8 and 9, the multi-stage seedling seed culture apparatus 100 according to the second embodiment of the present invention may include a mounting rod (128).

The mounting rod 128 may be formed in a rod shape so that a plurality of rods may be mounted between the side walls facing the culture tank 120 so as to be spaced apart from the culture tank 120 at predetermined intervals.

At this time, in the culture tank 120, a mounting groove 120a for mounting the mounting rod 128 may be formed on the upper portion of the culture tank 120, and the culture tank 120 vertically supports the culture network 127. It may be formed to have a depth that can be locked in the culture tank 120 in the upright state.

In addition, a plurality of culture tanks 120 may be installed in the multi-stage frame 110 in the height direction.

On the other hand, the mounting rod 128 may be provided with a mounting ring 129 for detachably hanging the culture network 127, the culture network 127 in the mounting ring 129 installed on the mounting rod 128 The culture network 127 in the form of hanging can be mounted.

Here, a pair of culture nets 127 may be overlapped and mounted on a single rod 128, and a pair of culture nets 127 are positioned so that the oyster shells W face each other. It can be mounted on the mounting rod 128 in the state.

In addition, the culture network 127 installed on the mounting rod 128 changes the position of the upper and lower in the state mounted on the culture tank 120 for a predetermined time, and then removes the culture network 127 from the mounting ring 129, It can be remounted by changing its position.

On the other hand, although the culture vessel 125 is shown in the drawing in the second embodiment, in the second embodiment, because the culture network 127 is in a standing state, the culture network 127 may be spaced apart from the bottom of the culture tank 120. Since there is no need, the culture network 127 may be directly installed in the culture water tank 120 without the culture vessel 125.

The spore seedling multi-stage culture apparatus 100 according to the second embodiment of the present invention configured as described above can grow a greater amount of laver than the first embodiment by installing the culture network 120 in the form of a dropping type. There is an advantage to that.

Although the embodiments of the present invention have been described above, the scope of the present invention is not limited thereto, and the present invention is easily changed and equivalent to those of ordinary skill in the art to which the present invention pertains. Includes all changes and modifications to the scope of the matter.

100: square spore seedling multistage culture apparatus 110: multi-stage frame
111: pillar 111a: drainage column
111b: water column 113: layer guide
113a: release prevention jaw 120: culture tank
120a: mounting groove 121: drain hole
122: latching portion 123: latch
125: culture vessel 126: spaced leg
127: culture network 128: rod
129: hook ring 130: drain connector
135: drainage control valve 140: water supply line
140a: branch line 140b: drain line
141: water supply 145: seawater spray
146: rotating jet 147: torque providing nozzle
150: illumination 151: seawater cooling flow path
153: light source 155: floodlight cover
160: controller 161: spore supply port
163: nutritional supply

Claims (9)

A multi-stage frame including a plurality of pillars erected from a floor and a plurality of layer guides connecting the plurality of pillars up and down so that the plurality of pillars are divided into a plurality of layers,
The cultivation tank includes a drainage port for oyster shell for culturing each spore and the sea water is accommodated and detachable seated for each layer guide and discharge the received sea water,
Illumination is provided for each layer of the multi-stage frame to adjust the illuminance for cultivation of each spore from the top of the culture tank,
A water supply line installed at each floor of the multi-stage frame and spraying and supplying seawater to the culture tank;
Is used as any one of the pillars of the plurality of pillars is connected to the drain hole of the culture tank seated on the layer guide includes a drain column for performing drainage,
The drainage column includes a drainage connector for connecting the drainage port of the culture tank and the drainage column seated for each layer to guide the seawater discharged to the drainage port to the drainage column,
The culture tank is accommodated in the oyster shell is disposed inside the culture tank, and includes a culture vessel formed with a plurality of perforation holes so that seawater and foreign matter easily discharged to the culture tank,
Is formed in the layer guide is a separation prevention jaw to prevent the separation of the culture tank from the layer guide,
A clasp for preventing the culture tank from leaving in the state brought into the layer guide,
A catch portion formed in the culture tank so that the clasp is spread, and
The spore seedling multi-stage culture apparatus comprising a drainage control valve for adjusting the drainage of the seawater drained to the drainage column so that the water level of the seawater accommodated in the culture tank can be maintained. delete delete The method of claim 1,
The culture vessel
The spore seedling multi-stage culture apparatus, characterized in that it comprises a separation leg for supporting the culture vessel spaced apart from the bottom of the culture tank to facilitate the discharge of foreign matter and sea water through the perforation hole. The method of claim 1,
The culture tank
The spore seedling multi-stage culture apparatus comprising a culture network for arranging and fixing the oyster shell at a predetermined interval so that the oyster shell received in the culture tank does not overlap each other. The method of claim 1,
The layer guide
The spore seedling multi-stage culture apparatus, characterized in that installed inclined at a predetermined angle from the plurality of pillars to be seated in the frame to be easily drained inclined at a predetermined angle toward the drain port of the culture tank. The method of claim 1,
Except for the drainage column, each spore seedling multi-stage culture apparatus, characterized in that it is used as any one of the pillars and comprises a water supply column for supplying seawater to the water supply line. The method of claim 1,
The water supply line
Rotating by the pressure of the sea water supplied through the water supply line and includes a seawater injector for injecting seawater toward the culture tank,
The seawater jet
A rotary spraying table receiving sea water from the water supply line and rotatably coupled to a central portion of the water supply line;
A plurality of rotational injection unit is coupled along the longitudinal direction, and comprises a rotational force providing nozzle for providing a rotational force to the rotational injection injecting seawater in the inclined direction of the opposite direction to rotate the rotational injection Square spore seedling multistage incubator. The method of claim 1,
The lights are
The spore seedling multi-stage culture apparatus, characterized in that it comprises a sea water cooling passage for cooling by receiving a portion of the sea water supplied to the water supply line.

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