KR100973512B1 - Movement System in underwater of offshore fish-cage - Google Patents

Abstract

The present invention relates to an offshore cage structure capable of underwater movement using electric and compressed air, and specifically, a cage net for raising fish; An upper rim for maintaining a mold at the top of the cage net, and a lower rim for maintaining the mold at the bottom of the cage net, the moxibustion part for maintaining a constant shape while floating the cage under water; And an underwater moving means for freely adjusting the position of the cage net by allowing the wire connected to the moxibustion portion to be rolled up and unsealed on the drum driven by the forward and backward driving motor. It is located in the deep water tide and good aquaculture environment and can be moved to shallow water for management, which makes it difficult to manage the current offshore cage system. By adjusting, it is possible to prevent damage from natural disasters such as typhoons and red tide.

Offshore cages, electric, pneumatic, underwater vehicles, rims,

Description

Movement System in underwater of offshore fish-cage

The present invention relates to an offshore cage structure capable of underwater movement, and more particularly, to an apparatus for underwater movement of an offshore cage farm, which is located underwater, and an offshore cage structure having a shape of a cage structure for use thereof.

The fish farming industry in Korea has been mostly demolished under the legal regulations of freshwater fish cage farming, which has been installed in rivers and lakes since the late 1990s. Most of them are produced in marine cage farms or onshore tank tank farms, and more than 60-70% of marine fish are produced in marine cage farms.

It is undeniable that fish farming using sea surface is not only recognized as a pollution pollutant in coastal environment because it is concentrated and dense mainly in the south coast where facilities are easy to maintain in the wind. In addition, it is difficult to maintain aquaculture facilities on the East Coast and Jeju Island, where the environmental self-cleaning power is relatively high. However, aquaculture using offshore cages has the advantage of being able to produce highly competitive high-quality aquatic organisms due to its largely divided into food safety and environmental friendliness. Offshore farming is an aquaculture method that can satisfy both food safety and environmental friendliness as it has the advantage of producing high quality marine products in the clean open sea with a great environmental capacity.

Commonly used surface layer cage forms are tied with a large moxibustion and float on a certain surface with anchors, and the cage net is fixed to the moxibustion frame. In order to prevent the net from tipping or floating, the bottom of the net or a corner is weighted to keep the bottom flat. However, the cage farming facility is mainly wooden raft structure, which is vulnerable to strong waves, and the damage caused by the typhoon damage is repeated every year.

As a conventional technique for preventing damages to natural disasters such as typhoons and red tide, an external sea erosion system is provided with buoyancy means inside the upper frame of Korean Patent No. 10-0796220 to freely control the depth of the cage. A cage farming device is disclosed.

The offshore erosion cage farming apparatus according to the prior art, as shown in Figure 1, is formed along the upper circumference of the cage net 10 and the cage is formed a space for trapping fish 10 In the cage culture apparatus including the upper frame 20, a space portion 22 is formed inside the upper frame 20, the space portion 22 is expanded and expanded in accordance with the supply and discharge operation of compressed air A tube 24 is installed which contracts and generates buoyancy; In the circumferential surface of the upper frame 20, a plurality of through holes 28 for introducing and discharging seawater into the inner space 22 of the upper frame 20 according to the contraction and expansion of the tube 24 are provided. Formed.

However, in the prior art, a separate tube 24 should be installed in order to change the position of the cage net 10, and there is a big problem that all the tubes 24 installed on the water surface may be lost due to the typhoon.

In addition, only by adjusting the buoyancy of the tube 24, it is difficult to accurately adjust the position of the cage net 10, there is a problem that there is no method to check in water.

Accordingly, the present invention has been made to solve the above problems, an object of the present invention to provide an offshore frame structure that can adjust the position of the offshore cage in the water.

Another object of the present invention is to provide an offshore cage structure capable of rapidly moving underwater by combining the electric and air driven system in a hybrid.

In order to achieve the object as described above, the external sea cage structure capable of moving underwater according to an embodiment of the present invention, the cage nets for raising fish; An upper rim for maintaining a mold at the top of the cage net, and a lower rim for maintaining the mold at the bottom of the cage net, the moxibustion part for maintaining a constant shape while floating the cage under water; And an underwater movement means for freely adjusting the position of the cage net by allowing the wire connected to the moxibustion portion to be wound and unwound on a drum driven by a forward and backward driving motor.

In addition, the upper rim and the lower rim according to the present invention, the air inlet and seawater inlet for the entrance of air and seawater is formed in the rim having a space formed in the partition therein air and seawater through the air inlet and seawater inlet It is preferable to be configured to balance the entire rim structure by adjusting the inflow of the. Here, it is more preferable that the buoyancy of the upper rim is set to be higher than the neutral buoyancy to receive upward force, and the buoyancy of the lower rim is set to be lower than the neutral buoyancy to be forced downward.

In addition, the underwater movement means according to the present invention is freely rotated by a bearing on the shaft driven by the output shaft and the worm gear of the forward and reverse drive motor into the inside of the moxibustion frame holder connected by the wire and the lower rim free rotation by a bearing The drum, which is installed and wound around the wire, is fixed and the corresponding clutch plate is fixed to the shaft and the drum, respectively, so that power switching can be performed according to the selective slide operation of the clutch plate on the shaft. It is preferable to fix the brake drum so that the braking can be arbitrarily adjusted by selective joint operation of the brake shoe.

In addition, the moxibustion holder according to the present invention is preferably provided so that the lower rim and the moxibustion holder is fixed and fixed when the cage is pulled down, a plurality of weights are installed at the bottom More preferably, the frame holder is pulled downward to prevent the flow of the cage net.

On the other hand, the offshore frame structure capable of moving underwater according to another embodiment of the present invention, the control device for injecting compressed air into the moxibustion and controls the operation of the underwater moving means; characterized in that it further comprises do.

In addition, the control device according to the invention, the air inlet hose connected to the air inlet of the upper rim and the lower rim; An underwater cable for electric drive connected to the underwater moving means; And a connector connecting the air inlet hose and the electric drive underwater cable to the buoy for position indication in a floating state.

As described above, according to the present invention, it is possible to minimize the damage to natural disasters such as typhoons and red tide by adjusting the position of the open sea cages in the water, thereby reducing the treasury waste by reducing the cost of revitalization and enormous damage compensation costs. have.

In addition, according to the present invention can be moved to a shallow depth in the case of a good bird communication and a good aquaculture environment in the case of an emergency can be moved to a shallow depth in the case of an emergency to manage the current offshore cage system difficult to compensate for the effect There is.

In addition, according to the present invention to allow the wire connected to the net on the drum driven by the motor can be recommended and unsealed to completely eliminate the workers' injury caused by the fluctuation of the wire during the work to maximize the safety during work It also helps to improve work efficiency, reduce manpower and automate fishing equipment.

In addition, according to the present invention there is an advantage that can be used in both the pneumatic and the electric can be installed in a quick and accurate position farm.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Meanwhile, the offshore cage structure capable of underwater movement according to an embodiment of the present invention to be described later will suggest an underwater movement means that is limited to the offshore cage style, but all the offshore fishing using the bar cage style proposed by the present invention. Applicable to the field equally obvious.

2 is a conceptual view illustrating the installation of an offshore cage structure capable of moving underwater according to a preferred embodiment of the present invention.

As shown in Figure 2, the offshore cage structure that can be moved underwater according to the present invention, the cage net 100 to cultivate large fish and the cage net 100 to maintain a constant shape while floating on the surface or in the water Frame portion 200, the underwater movement means 300 and the moxibustion frame holder 400 is connected to the lower portion of the moxibustion frame 200 by the wire 230 to freely adjust the position of the cage net 100 Is the basic concept.

First, the cage net 100 is to form a block by hitting the net in the sea to raise and breed a variety of fish therein, the cage net 100 to prevent damage due to external shocks and to the current specification of the facility in the current flow Moxibustion portion 200 is provided to maintain and protect.

The moxibustion portion 200 is installed along the upper circumference of the cage net 100 to maintain the shape of the upper end of the cage net 100, and along the lower circumference of the cage net 100 Installed is composed of a lower rim 220 to maintain the shape of the lower end of the cage net 100.

3 is a view showing the shape of the upper rim 210 and the lower rim 220 according to the present invention.

As shown in Figure 3 (a) (b) (c), the upper rim 210 and the lower rim 220 according to the present invention has a constant length and has a rim having a space portion formed therein partition 214 ( 212 and the air inlet 216 and the seawater inlet 218 for accessing air and seawater to the rim 212. The air inlet 216 is designed to open and close the valve to enable the buoyancy control of the rim 212, so that there is no need for a separate buoyancy control device in the open sea cage, and when the offshore cage moves up and down It also serves to relieve the load on the driving method. In addition, the partition wall 214 is erected inside the rim 212 to adjust the inflow of air / sea water even if there is a difference in buoyancy when installing the cage to balance the entire rim structure. Therefore, it is possible to adjust the buoyancy using the internal air pressure control to sink the offshore cages, which can significantly reduce the damage of red tide that causes great damage to fishermen each year.

As shown in Figure 4 (a) (b), such a rim 212, it can be made of a polygon or a circle, and the like, in the case of a rim 212 of the polygonal structure has a shape that is connected to eight.

The upper rim 210 and the lower rim 220 according to the present invention having the structure as described above is preferably set as follows. The lower rim 220 is set to receive a slight force downward by setting the buoyancy slightly lower than the neutral buoyancy, the upper rim 210 is set to receive a force upward by setting slightly higher than the neutral buoyancy. The buoyancy of the upper rim 210 is upward, the buoyancy of the lower rim 220 is directed downward, so the cage net 100 is always widened and the upper rim 210 and the lower rim 220, and underwater movement described below Through the wire 230 connecting the means 300 to take the form of the entire outer sea cage, it is possible to adjust the position.

5 is a detailed view of the means for moving underwater according to one preferred embodiment of the present invention.

The underwater moving means 300 is to control the moxibustion frame 200 to the correct position by supplementing the pneumatic using the upper rim 210 and the lower rim 220. For example, if you try to position the farm at a depth of 10m from the surface of the water using the pneumatic equation is approximately between 8 to 12m, while using the electric underwater means of movement 300 to the exact position by the variable resistor There is an advantage to install. In addition, the position can be moved faster than the pneumatic, it is effective to respond appropriately to emergency situations.

As shown in Figure 5, the underwater moving means 300 according to the present invention is first provided with a forward and reverse drive motor 301. Here, the forward and reverse drive motor 301 may have a sufficient torque by using a reduction gear or an induction motor in a general induction motor.

In addition, the output shaft 303 of the forward and reverse drive motor 301 is connected to the drum drive shaft 307 using a worm gear 305, and the drum drive shaft 307 is freely provided with a bearing 309 therein. A drum 311 is rotatably arranged and wound at the other end of the wire 230 connected to the lower rim 220 of the cage net 100.

In addition, a clutch 313 for power switching of the drum 311 is provided. That is, the clutch plate 313a installed at one side of the clutch 313 slides left and right by a predetermined width by using a key (not shown) in the drum driving shaft 307 and simultaneously the drum driving shaft 307 of the drum driving shaft 307. To rotate at the same time to rotate, the corresponding clutch plate 313b is fixed to one side of the drum 311, the clutch plate 313a according to the slide operation of the clutch plate 313a installed on the drum driving shaft 307 , 313b) is to be switched to the rotational power to the drum 311 while being bitten and separated from each other.

In addition, the brake plate 315 is installed on the clutch plate 313b fixed to the drum 311 so as to prevent any rotation of the drum 311. That is, the brake drum 315a is fixed by means of a drum driving shaft 307 and bolting (not shown), and the arc-shaped brake shoe 315b having an open end is attached to the outer circumferential surface of the brake drum 315a. And brake shoe 315b is connected to the piston (not shown) of the hydraulic cylinder so that the braking can be made selectively. At this time, the brake 315 is fixed to the drum driving shaft 307 when the electricity is not supplied using a type of "B" contact as an electromagnetic brake, and the drum driving shaft 307 freely when the electricity is supplied. Make it move.

The part including the forward and reverse driving motor 301, the worm gear 305, the brake 315, the variable resistor 317, the reduction gear 319, etc. of the underwater moving means 300 according to the present invention is an O-ring 321. Watertight in such a case that the water in the case 323 is configured to prevent electrical problems. Other parts should be made of materials that are less corrosive even if they are exposed to sea water for a long time.

On the other hand, the underwater moving means 300 is preferably installed inside the moxibustion frame holder 400 is connected by the lower rim 220 and the wire 230. The moxa frame holder 400 is made of a structure that can be fixed by binding to the lower rim 220 when the cage net 100 is pulled down. In addition, a plurality of weights 410 are installed at the lower end of the moxibustion holder 400 to prevent the flow of the cage net 100 by pulling the moxibustion holder 400 tightly downward.

On the other hand, the underwater moving means 300 according to the present invention as described above may be installed and operated in the form of the following Figure 6 and 7 in the actual sea.

6 is a schematic installation state diagram of an offshore cage structure capable of moving underwater according to the present invention, Figure 7 is a block diagram of a control device according to the present invention.

As shown in Figure 6 and 7, the present invention is to make a separate control device 500 for controlling the underwater movement means 300 to be mounted on a ship or the like.

The control device 500 can be operated manually and automatically and to control a variety of accessories such as a large-scale Shanghaidong motor control and brake control using a plurality of magnetic contactors and relays. In addition, the control device 500 is provided with a display window 510 that can be visually displayed in a 7-segment or LCD so as to know the depth of the current cage by measuring the value of the variable resistance and the like shown in FIG. do. In addition, the control device 500 is extended to the position display buoy 540 in the floating state using the air inlet hose 520 and the electric drive underwater cable 530 is installed on the marine vessel control The connector 550 of the device 500 is used to facilitate connection.

Hereinafter, the operation of the offshore cage structure capable of moving underwater according to the present invention will be described in detail.

First, in order to adjust the position of the cage net 100 by the air injection of the moxibustion 200 according to the present invention, the control device 500 is installed in the marine vessel is connected to the connector 550 Connect the air inlet hose 520 to the air inlet 216 formed in the upper rim 210 or the lower rim 220.

Next, when the cage net 100 is to be submerged in the water and the discharge of the compressed air supplied to the air inlet 216 of the upper rim 210 or lower rim 220 to the outside seawater is the upper rim 210 or Through the seawater inlet 218 formed in the lower rim 220 is introduced into the rim, due to the weight of the incoming seawater, the cage net 100 is settled down and placed on the seabed to form fish do.

When the cage net 100 is to be floated on the surface of the water, compressed air is supplied through the air inlets 216 formed in the upper rim 210 or the lower rim 220, and the seawater introduced into the rim. Is discharged to the outside through the sea water inlet 218 by the pressure of the compressed air is to reduce the weight of the upper rim 210 or lower rim 220 is to be able to float the cage net 100 above the water surface.

On the other hand, when you want to quickly adjust the position of the cage net 100 in an emergency such as typhoon or red tide can be used underwater moving means (300).

The underwater moving means 300, first, the output shaft 303 of the forward and reverse drive motor 301 and the drum 311 on the drum drive shaft 307 that is axially coupled to the worm gear is switched to the idling state. That is, the drum driving shaft 307 and the clutch plate 313a of the drum driving shaft 307 of the clutch 313 respectively provided on the drum driving shaft 307 and the drum 311 are separated from the clutch plate 313b of the drum 311 side. 311 is switched to the idling state, the cage net 100 is meshed underwater by self-weight and water pressure, the wire 230, which is recommended in the drum 311 is made in the sea area, where the sea speed of the wire 230, That is, the net speed of the net needs to be properly adjusted as necessary. For the purpose of adjusting the net speed, the brake speed 315 and the brake shoe 315b installed on the drum 311 are adjusted by a variable resistor to reduce the speed of the net. Will be able to adjust arbitrarily. The adjustment of the brake shoe 315b of the brake 315 can also be performed through the expansion and contraction operation of the hydraulic cylinder.

On the other hand, when the meshing of the cage net 100 is completed, the drum 311 switches the brake 315 to a complete braking state so as not to rotate arbitrarily. This braking operation is to use a hydraulic cylinder as described above.

In addition, when winding up the meshed cage 100, the drum 311 is rotated in the opposite direction to the sea-sealed wire 230 to be wound on the drum 311, in this case the forward and reverse drive motor 301 The clutch plate 313a on the drum drive shaft 307 which is shaft-joined by coupling with the output shaft 303 of the When the forward and reverse drive motor 301 is driven by the clutch connection, the drum 311 is rotated in the winding direction of the wire 230 so that the cage net 100 is wound, and the wire 230 as needed during the hoisting operation. There is also a case of temporarily opening the bar, in this case, if the forward and reverse drive motor 301 is driven in the reverse direction, the drum 311 is also connected to the drive in the reverse direction can easily perform the desired hoisting work.

So far we looked at one embodiment according to the present invention in detail. The scope of the present invention is not limited to the above-exemplified embodiments, and if the technical spirit of the present invention is applied, all will be said to belong to the scope of the present invention.

1 is a view showing the offshore edible cage farming apparatus according to the prior art.

Figure 2 is a conceptual diagram of the installation of an offshore cage structure capable of moving underwater according to an embodiment of the present invention.

Figure 3 is a view showing the shape of the upper and lower rim according to the present invention.

4 is a cross-sectional view of the rim of FIG. 3.

5 is a detailed view of the means for underwater transport according to one preferred embodiment of the present invention.

Figure 6 is a schematic installation state of the offshore cage structure capable of moving underwater according to the present invention.

7 is a block diagram of a control device according to the present invention.

* Explanation of symbols on main parts of the drawings *

100. cage net 200.

210. Upper Rim 212. Rim

214. Bulkhead 216. Air Inlet

218. Seawater inlet 220. Lower rim

230. Wire 300. Underwater Vehicles

301. Forward and reverse drive motor 303. Output shaft

305. Worm gear 307. Drum drive shaft

309.Bearings 311.Drums

313. Clutch 313a, 313b. Clutch plate

315. Brake 315a. Break drum

315b. Brake Shoe 317. Variable resistance

319. Reduction Gear 321. O-Ring

323. Case 400. Moxa frame holder

410. Weight 412. Wire

500. Controller 510. Display

520. Air inlet hoses 530. Underwater cables for electric drive

540. Buoy for Position Marking 550. Connector

Claims (11)

Cage net (100) for raising fish; The upper rim 210 for maintaining the mold of the upper end of the cage net 100, and the lower rim 220 for maintaining the mold of the lower end of the cage net 100 is configured to the cage net 100 A moxibustion portion 200 which maintains a constant mold while floating on water or in water; Underwater movement to freely adjust the position of the cage net 100 by allowing the wire 230 connected to the moxibustion 200 to be wound and unwound on the drum 311 driven by the forward and reverse drive motor 301. Means 300; And Control device 500 for injecting compressed air into the moxibustion unit 200 and controls the operation of the underwater movement means 300; The method of claim 1, wherein the upper rim 210 and the lower rim 220, An air inlet 216 and a seawater inlet 218 are formed in the rim 212 having a space portion in which a partition wall 214 is formed, thereby forming the air inlet 216 and the seawater inlet 218. An offshore cage structure capable of moving underwater, characterized in that it is configured to balance the entire rim structure by adjusting the inflow of air and seawater through. The method according to claim 1 or 2, The buoyancy of the upper rim 210 is set to receive a force upward by setting higher than the neutral buoyancy, The buoyancy of the lower rim 220 is set to be lower than the neutral buoyancy, the external sea cage structure that can be moved underwater, characterized in that set to receive a force. The method of claim 1, wherein the underwater moving means 300, The drum 230 is axially coupled by the output shaft 303 and the worm gear 305 of the forward / reverse drive motor 301 to be rotated to be driven. Underwater moving structure that can move underwater, characterized in that the shaft is fixed to the wound drum (311). The method of claim 4, wherein the underwater moving means 300, The clutch drive 313a and 313b corresponding to the drum drive shaft 307 and the drum 311 are respectively fixed, so that power switching is performed in accordance with the selective slide operation of the clutch plate 313b on the drum drive shaft 307. An offshore cage structure capable of moving underwater, characterized in that it can be made. The method of claim 4 or 5, wherein the underwater moving means 300, The offshore cage structure, which can move underwater, characterized in that the braking drum (315a) is fixed to the drum drive shaft (307) so that the braking can be arbitrarily adjusted by selective joint operation of the brake shoe (315b). The method of claim 1, wherein the underwater moving means 300, The offshore frame structure that can be moved underwater, characterized in that installed on the moxibustion frame holder 400 is connected by the lower rim 220 and the wire 230. According to claim 7, The moxibustion frame holder 400 is, Underwater moving frame structure that can be moved underwater, characterized in that is provided to be fixed by binding with the lower rim 220 when pulled down the cage net (100). 9. The method according to claim 7 or 8, A plurality of heavy objects 410 are installed at the lower end of the mould frame holder 400 to pull the mould frame holder 400 taut downward to prevent the flow of the cage net 100, the external sea is possible Cage structures. delete The method of claim 1, wherein the control device 500, An air inlet hose 520 connected to the air inlet 216 of the upper rim 210 and the lower rim 220; An electric drive underwater cable 530 connected to the underwater moving means 300; And Underwater movement is configured to include; the air inlet hose 520 and the electric drive underwater cable 530 extends to the floating position display buoy 540 to connect; Possible offshore cage structures.

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