CN214677207U - Water intake device of deep sea culture ship and deep sea culture ship comprising same - Google Patents

Abstract

The utility model discloses a deep sea breed ship's water intake device reaches deep sea breed ship including it, deep sea breed ship's water intake device includes first intake pipe, second intake pipe and buoyancy piece, and the second intake pipe communicates with first intake pipe connection, and the second intake pipe is the flexible pipe, and the one end that the second intake pipe is close to first intake pipe is fixed on the buoyancy piece, and the buoyancy piece can upwards float. The buoyancy block is used for making the second intake pipe be close to the one end of first intake pipe can float upwards to make the second intake pipe can relax, and can not make the second intake pipe be in the state of tightening because of the influence of gravity. In addition, the second water taking pipe connected with the ship body is a flexible pipe, so that acting force generated on the second water taking pipe due to the movement of the ship body can be directly discharged by the second water taking pipe, the influence of the movement of the ship body on the connection part of the first water taking pipe and the second water taking pipe is greatly reduced, and the damage of the water taking pipe caused by the movement of the ship body is avoided.

Description

Water intake device of deep sea culture ship and deep sea culture ship comprising same

Technical Field

The utility model relates to a boats and ships technical field, in particular to deep sea breed ship's water intake device reaches deep sea breed ship including it.

Background

In the prior art, the connection between the ship and the underwater pipeline is usually that the underwater pipeline is directly connected to the main hull of the ship, for example, the connection between the culture ship and the water intake pipe is that the water intake pipe is directly connected to the hull of the culture ship. The connection mode can not avoid the influence of the movement of the ship body on the water taking pipe, and the water taking pipe is easy to be broken due to the movement of the ship body, so that the damage of the water taking pipe is caused, and the normal water taking of the culture ship is influenced.

Moreover, the intake pipe of breed boat at present mainly relies on the loop wheel machine to drop one by one the great hard tube of diameter and places the sea and couple together, and the intake pipe of this kind of structure is though the flow is big, and the rate of water intaking is high, but because the pipeline is harder, receives the influence of hull motion more easily, and hangs and put and retrieve the time limit for a project longer, can't in time retrieve under the situations such as typhoon, receives bad weather influence easily and reduces life.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to provide a water intake device of deep sea breed ship and including its deep sea breed ship in order to overcome among the prior art defect that the hull motion leads to the intake pipe to damage easily.

The utility model discloses an above-mentioned technical problem is solved through following technical scheme:

a water taking device of a deep sea culture ship comprises a first water taking pipe, a second water taking pipe and a buoyancy block, wherein the first water taking pipe extends to the sea bottom and is used for being communicated with seawater on the sea bottom;

the second water taking pipe is connected and communicated with the first water taking pipe, extends to the ship body and is used for being communicated with the culture tank in the ship body;

the second intake pipe is a flexible pipe, one end of the second intake pipe close to the first intake pipe is fixed on the buoyancy block, and the buoyancy block can float upwards.

In this scheme, the buoyancy piece is used for making the second intake pipe be close to the one end of first intake pipe and can upwards float to make the second intake pipe can relax, and can not make the second intake pipe be in the state of tightening because of the influence of gravity. In addition, the second water taking pipe connected with the ship body is a flexible pipe, so that acting force generated on the second water taking pipe due to the movement of the ship body can be directly discharged by the second water taking pipe and cannot be transmitted to the joint of the second water taking pipe and the first water taking pipe through the second water taking pipe, the influence of the movement of the ship body on the joint of the first water taking pipe and the second water taking pipe is greatly reduced, the damage of the water taking pipe due to the movement of the ship body is avoided, and the reliability of water taking is improved.

Preferably, one end of the second water intake pipe close to the ship body is arranged in the middle area of the ship bottom.

In this scheme, the motion range of hull bottom middle part is less, and above-mentioned setting makes because the hull motion and reduces the effort that the second intake pipe produced, and the power that the second intake pipe need be unloaded reduces, and the effort of the hull motion that the second intake pipe received is more difficult to transmit on second intake pipe and the junction of first intake pipe and the first intake pipe, further reduces the influence of hull motion to first intake pipe and second intake pipe junction.

Preferably, the first water taking pipe is a flexible pipe; the water taking device of the deep sea culture ship further comprises a winding and unwinding winch, the winding and unwinding winch is connected with the first water taking pipe, and the winding and unwinding winch is used for recycling and laying the first water taking pipe.

In this scheme, the aforesaid is provided with and does benefit to the efficiency that receive and releases that improves first intake pipe, can in time retrieve first intake pipe under the condition of bad weather such as typhoon to improve the life of first intake pipe. Can in time lay out first intake pipe after weather improves to guarantee can in time get water, make the sea water in the breed jar in time change, guarantee fish living environment.

Preferably, the water intake device of the deep sea culture ship further comprises a third water intake pipe, the third water intake pipe is a flexible pipe, and the third water intake pipe is connected between the retraction winch and the first water intake pipe.

In this scheme, the length that first intake pipe stretches into the sea water generally is the definite value, and the aforesaid is provided with and does benefit to the length constancy that guarantees first intake pipe, need not confirm the length of first intake pipe again at every turn the cloth in-process to improve the cloth and put efficiency.

Preferably, the buoyancy block is arranged close to the joint of the first water intake pipe and the third water intake pipe.

In this scheme, above-mentioned setting is favorable to the quick location of buoyancy piece, can improve the efficiency of putting of cloth of first intake pipe.

Preferably, the water intake device of the deep sea culture ship further comprises a correction pipe, the correction pipe is fixed on the buoyancy block and extends towards the seabed direction, and the first water intake pipe penetrates through the correction pipe along the vertical direction.

In this scheme, the orientation that the correction pipe was used for guaranteeing first intake pipe is accurate, can not produce the bending because of the characteristic of flexible pipe, improves the stability of first intake pipe water intaking.

Preferably, the water intaking device of deep sea breed ship still includes the standpipe, the standpipe sets up the inside of hull, the one end of standpipe with the second is got water piping connection and is communicate, the other end of standpipe extend to breed the jar and with breed the jar intercommunication.

In this scheme, the standpipe except can introducing the sea water in the second intake pipe breed the jar, can also be used for saving the sea water to under the state of the unable normal water intaking because the outside intake pipe of hull breaks down, the standpipe can provide emergent water source for breeding the jar.

Preferably, the diameter of the water storage pipe is larger than that of the second water taking pipe.

In this scheme, above-mentioned setting makes the capacity grow in the standpipe, and under emergency condition, the sea water that can provide the breed jar is more.

Preferably, the water storage pipe is connected with the second water taking pipe through a pipe connector, and the diameter of one end, close to the water storage pipe, of the pipe connector is larger than that of one end, close to the second water taking pipe, of the pipe connector.

In this scheme, the pipe connection ware adaptation of above-mentioned structure is connected in the different pipe connection of two diameters, improves the feasibility that second intake pipe and standpipe are connected to improve the leakproofness of junction.

Preferably, an internal thread is arranged at one end of the pipeline connector close to the second water taking pipe, an external thread is arranged at one end of the second water taking pipe close to the pipeline connector, and the pipeline connector is screwed with the second water taking pipe;

an external thread is arranged at one end of the pipeline connector close to the water storage pipe, an internal thread is arranged at one end of the water storage pipe close to the pipeline connector, and the pipeline connector is screwed with the water storage pipe;

the joint of the pipeline connector and the second water taking pipe and the joint of the pipeline connector and the water storage pipe are sealed.

In this aspect, a method for connecting a pipe connector to a second intake pipe and a water storage pipe is provided, which is configured to prevent seawater in the pipe from seeping into the hull.

A deep sea culture ship comprises the water taking device of the deep sea culture ship.

In this scheme, provide a deep sea culture ship's water intake device's place of application, the sea water that takes out among the water intake device is used for supplying the fish survival in the deep sea culture ship.

The utility model discloses an actively advance the effect and lie in: the utility model provides a buoyancy piece is used for making the second intake pipe be close to the one end of first intake pipe and can upwards float to make the second intake pipe can relax, and can not make the second intake pipe be in the state of tightening because of the influence of gravity. In addition, the second water taking pipe connected with the ship body is a flexible pipe, so that acting force generated on the second water taking pipe due to the movement of the ship body can be directly discharged by the second water taking pipe and cannot be transmitted to the joint of the second water taking pipe and the first water taking pipe through the second water taking pipe, the influence of the movement of the ship body on the joint of the first water taking pipe and the second water taking pipe is greatly reduced, the damage of the water taking pipe due to the movement of the ship body is avoided, and the reliability of water taking is improved.

Drawings

Fig. 1 is a schematic plan view of a water intake device of a deep-sea culture ship according to an embodiment of the present invention.

Fig. 2 is a schematic cross-sectional view of a pipe connector according to an embodiment of the present invention.

Description of reference numerals:

hull 11

Culture tank 12

First water intake pipe 21

A second water intake pipe 22

Third water intake pipe 23

Buoyancy block 3

Retractable winch 4

Straightening tube 5

Water storage pipe 6

Pipe connector 7

Sealing structure 73

Mounting handle 74

Detailed Description

The present invention is further illustrated by way of the following examples, which are not intended to limit the scope of the invention.

As shown in fig. 1, the present embodiment provides a deep sea culture ship for performing marine fish culture. The deep sea culture ship comprises a ship body 11 and a culture tank 12 arranged inside the ship body 11, seawater fishes live in the culture tank 12, seawater in the culture tank 12 needs to be replaced at any time, the living environment of the seawater fishes is guaranteed, and the survival rate of the seawater fishes is improved.

The deep sea culture ship comprises a water taking device for replacing seawater in the culture tank 12, and the water taking device of the deep sea culture ship is used for taking seawater in the sea bottom into the culture tank 12. Specifically, as shown in fig. 1, the water intake device includes a first water intake pipe 21, a second water intake pipe 22, and a buoyancy block 3.

One end of the first intake pipe 21 is connected and communicated with one end of the second intake pipe 22, the other end of the first intake pipe 21 extends to the sea bottom and is used for communicating with the sea water at the sea bottom, and the other end of the second intake pipe 22 extends to the hull 11 and is used for communicating with the culture tank 12 inside the hull 11. The seawater in the sea bottom enters from the first water intake pipe 21, flows into the second water intake pipe 22 through the communication part of the first water intake pipe 21 and the second water intake pipe 22, and then flows into the culture tank 12 through the communication part of the second water intake pipe 22 and the culture tank 12, so that the seawater in the sea bottom is taken into the culture tank 12. How the first intake pipe 21 obtains seawater from the sea bottom, how the seawater in the first intake pipe 21 flows into the second intake pipe 22, and the culture tank 12 belong to the prior art in the field, and are not described herein again, and those skilled in the art may adopt power elements, such as a water pump, etc., capable of achieving the above functions.

The second intake pipe 22 is a flexible pipe, one end of the second intake pipe 22 close to the first intake pipe 21 is fixed on the buoyancy block 3, and the buoyancy block 3 can float upwards. The buoyancy block 3 is used to enable the end of the second water intake pipe 22 close to the first water intake pipe 21 to float upwards, so that the second water intake pipe 22 can be loosened without the second water intake pipe 22 being in a tightened state due to the influence of gravity. In addition, the second water taking pipe 22 connected with the ship body 11 is a flexible pipe, so that acting force generated on the second water taking pipe 22 due to movement of the ship body 11 can be directly discharged from the second water taking pipe 22, and cannot be transmitted to the joint of the second water taking pipe 22 and the first water taking pipe 21 through the second water taking pipe 22, the influence of the movement of the ship body 11 on the joint of the first water taking pipe 21 and the second water taking pipe 22 is greatly reduced, the damage of the water taking pipe due to the movement of the ship body 11 is avoided, and the reliability of water taking is improved.

The buoyancy block 3 floating upward in this embodiment does not necessarily mean that the buoyancy block 3 can float on the sea surface, and it is only necessary to ensure that the second water intake pipe 22 is always in a relaxed state by the upward floating distance of the buoyancy block 3. The embodiment has no specific requirements on the structure, material and size of the buoyancy block 3, and can achieve the effect to be achieved by the middle buoyancy block 3.

As shown in fig. 1, in the present embodiment, one end of the second water intake pipe 22 close to the hull 11 is disposed in the middle area of the bottom of the ship, and because the motion amplitude of the middle of the bottom of the ship is small, the acting force generated by the motion of the hull 11 on the second water intake pipe 22 can be reduced, the force required to be discharged by the second water intake pipe 22 is reduced, and the acting force of the motion of the hull 11 received by the second water intake pipe 22 is less likely to be transmitted to the joint between the second water intake pipe 22 and the first water intake pipe 21, so as to further reduce the influence of the motion of the hull 11 on the joint between the first water intake pipe 21 and the second water intake pipe 22, avoid the damage of the water intake pipe caused by the motion of the hull 11, and improve the reliability of water taking.

In alternative embodiments, the second water intake pipe 22 may be located in other areas of the hull 11, such as on both sides of the hull 11, and the position should be selected to ensure that the forces generated by the motion of the hull 11 on the second water intake pipe 22 are discharged by the second water intake pipe 22 and are not transmitted to the connection of the second water intake pipe 22 to the first water intake pipe 21 and the first water intake pipe 21.

The first water taking pipe 21 is a flexible pipe, the water taking device further comprises a retracting winch 4, the retracting winch 4 is fixed on the ship body 11, and the retracting winch 4 is connected with the first water taking pipe 21 and used for recycling and distributing the first water taking pipe 21, so that the retracting efficiency of the first water taking pipe 21 is improved. Can in time retrieve first intake pipe 21 under the condition of bad weather such as typhoon, place first intake pipe 21 and expose under the adverse circumstances for a long time to improve first intake pipe 21's life. The first water intake pipe 21 can be timely arranged after the weather is improved, so that water can be timely taken, the seawater in the culture tank 12 can be timely replaced, and the living environment of fishes is guaranteed.

The water taking device further comprises a third water taking pipe 23, the third water taking pipe 23 is a flexible pipe, the third water taking pipe 23 is connected between the winding and unwinding winch 4 and the first water taking pipe 21, one end of the third water taking pipe 23 is connected with the winding and unwinding winch 4, and the other end of the third water taking pipe 23 is connected with and communicated with the first water taking pipe 21. Because the length that first intake pipe 21 stretched into the sea water generally is the definite value, add between receive and release capstan winch 4 and first intake pipe 21 and set up a section third intake pipe 23, be favorable to guaranteeing that the length of first intake pipe 21 is invariable, need not confirm the length of first intake pipe 21 again in the in-process of laying at every turn to improve the efficiency of laying.

In other alternative embodiments, the third water intake pipe 23 may also be embodied as a flexible member in a non-pipe form, such as a rope or the like.

In the present embodiment, the first intake pipe 21, the second intake pipe 22, and the third intake pipe 23 are connected and communicated with each other, but substantially all of the seawater in the first intake pipe 21 flows into the culture tanks 12 via the second intake pipe 22, and does not flow from the third intake pipe 23 onto the deck of the hull 11. The buoyancy piece 3 card is established in the junction of first intake pipe 21, second intake pipe 22 and third intake pipe 23, and buoyancy piece 3 is all worn to locate by first intake pipe 21, second intake pipe 22 and third intake pipe 23 to make things convenient for the quick location of buoyancy piece, thereby improve the efficiency of laying of first intake pipe 21. The specific connection mode between the buoyancy block 3 and the first water intake pipe 21, the second water intake pipe 22, and the third water intake pipe 23 belongs to the prior art in the field, and is not described herein.

The connection and communication mode of the first water intake pipe 21, the second water intake pipe 22 and the third water intake pipe 23 is not specifically discussed in this embodiment, and those skilled in the art may select a three-way valve or other structures capable of implementing the above functions to implement the connection and communication among the three pipes.

In other alternative embodiments, if the third water intake pipe 23 is configured in a non-pipe form, it is only necessary to ensure that the first water intake pipe 21 and the second water intake pipe 22 are directly connected to each other. Further, even if the third intake pipe 23 has a pipe structure, it may be implemented so as not to communicate with the first intake pipe 21 and the second intake pipe 22. The first water intake pipe 21, the second water intake pipe 22 and the third water intake pipe 23 are connected and communicated with each other in the embodiment, so as to prevent the seawater in the first water intake pipe 21 from not flowing into the second water intake pipe 22 in time and causing overlarge pressure in the first water intake pipe 21, and avoid the damage of the first water intake pipe 21. The redundant seawater in the first intake pipe 21 can be stored in the third intake pipe 23, and then flows into the second intake pipe 22 through the third outlet pipe.

In other alternative embodiments, the connection between the first water intake pipe 21 and the second water intake pipe 22, and the connection between the second water intake pipe 22 and the third water intake pipe 23 may be the same or different. The buoyancy block may not be completely disposed at a specific connection position, but may be disposed near a connection position of the first water intake pipe 21 and the second water intake pipe 22, and a connection position of the second water intake pipe 22 and the third water intake pipe 23.

In other alternative embodiments, the first water withdrawal line 21 may also be hard piped if the first water withdrawal line 21 is not to be recycled. The first intake pipe 21 in this embodiment is a flexible pipe, and on the one hand, the first intake pipe 21 can be recovered and distributed by retracting and releasing the winch 4, and on the other hand, even if the acting force generated by the movement of the hull 11 on the second intake pipe 22 is transmitted to the joint of the second intake pipe 22 and the first intake pipe 21, the remaining force can be discharged by the characteristics of the flexible pipe of the first intake pipe 21, thereby further reducing the damage of the intake pipe caused by the movement of the hull 11, and improving the reliability of water intake.

As shown in fig. 1, the water intake device further includes a rectifying pipe 5, and the rectifying pipe 5 is fixed to the buoyancy block 3 and extends in the seabed direction. The diameter of the straightening tube 5 is larger than the diameter of the first water intake tube 21, and the first water intake tube 21 penetrates through the straightening tube 5 in the vertical direction. The rectifying pipe 5 is used for ensuring the accurate orientation of the first water intake pipe 21, and the first water intake pipe 21 is not bent due to the characteristics of the flexible pipe, so that the stability of taking water from the first water intake pipe 21 is improved. The term "along the vertical direction" in the present embodiment does not only mean parallel to the vertical direction, but also includes substantially parallel to the vertical direction.

The water taking device further comprises a water storage pipe 6, the water storage pipe 6 is arranged inside the ship body 11, one end of the water storage pipe 6 is connected and communicated with the second water taking pipe 22, and the other end of the water storage pipe 6 extends to the culture tank 12 and is communicated with the culture tank 12. The water storage pipe 6 can be used for storing seawater in addition to the seawater in the second intake pipe 22 to be introduced into the culture tank 12, so that the water storage pipe 6 can provide an emergency water source for the culture tank 12 in a state where normal intake of water is impossible due to a malfunction of the intake pipe outside the hull 11.

The diameter of the water storage pipe 6 in this embodiment is larger than the diameter of the second intake pipe 22, so that the capacity in the water storage pipe 6 becomes large, and more seawater can be supplied to the culture tank 12 in an emergency state. In other alternative embodiments, the diameter of the water storage pipe 6 is not particularly limited, and may be greater than, less than, or equal to the diameter of the second water intake pipe 22.

The water storage pipe 6 is connected with the second water taking pipe 22 through the pipe connector 7, as shown in fig. 2, the diameter of one end, close to the water storage pipe 6, of the pipe connector 7 is larger than that of one end, close to the second water taking pipe 22, of the pipe connector 7, the pipe connector 7 of the structure is adaptive to pipe connection with two different diameters, and therefore the feasibility of connection of the second water taking pipe 22 and the water storage pipe 6 is improved, and the sealing performance of the connection position is improved.

As shown in fig. 2, an internal thread is provided on the inner wall surface of the pipe connector 7 near one end of the second water intake pipe 22, an external thread is provided on the outer wall surface of the second water intake pipe 22 near one end of the pipe connector 7, and the internal thread of the pipe connector 7 is screwed with the external thread of the second water intake pipe 22. An external thread is arranged on the outer wall surface of the pipeline connector 7 close to the water storage pipe 6, an internal thread is arranged on the inner wall surface of the water storage pipe 6 close to the pipeline connector 7, and the external thread of the pipeline connector 7 is screwed with the internal thread of the water storage pipe 6. The connection between the pipe connector 7 and the second intake pipe 22 and the connection between the pipe connector 7 and the water storage pipe 6 are sealed to prevent seawater in the pipes from seeping into the hull 11.

In other alternative embodiments, the connection among the second intake pipe 22, the pipe connector 7 and the water storage pipe 6 is not limited to the above connection, and other connection methods such as fastening by fasteners, etc. may be selected.

Generally, the second water intake pipe 22, the pipe connector 7 and the water storage pipe 6 are sealed by screw connection, as shown in figure 2,

a sealing strip 73 can be arranged between the second water taking pipe 22 and the pipe connector 7 for sealing, and the pipe connector 7 and the water storage pipe 6 can also be sealed by the sealing strip 73.

In other alternative embodiments, in order to further enhance the sealing effect at the connection between the pipe connector 7 and the second water intake pipe 22 and at the connection between the pipe connector 7 and the water storage pipe 6, other sealing structures, such as a sealing ring, a sealant, etc., may be further disposed at the connection.

In other alternative embodiments, the second water intake pipe 22 and the water storage pipe 6 may be connected directly or through a pipe connector 7 of other structure. In the case of direct connection or connection by the pipe connector 7, it is preferable to perform watertight treatment at the connection to prevent seawater in the pipe from seeping into the hull 11 from the connection and to ensure the sealing of the hull 11.

The pipe connector 7 is provided at both sides thereof with mounting handles 74 to facilitate mounting and dismounting of the pipe connector 7 to and from the second intake pipe 22 and the storage pipe 6.

In the embodiment, the materials of the first water intake pipe 21, the second water intake pipe 22, the third water intake pipe 23 and the water storage pipe 6 are not specifically discussed, and those skilled in the art can select the materials of the pipes that can be used for taking and storing water in deep sea to manufacture the first water intake pipe 21, the second water intake pipe 22, the third water intake pipe 23 and the water storage pipe 6. The first water intake pipe 21, the second water intake pipe 22 and the water storage pipe 6 are preferably made of heat insulating materials so as to ensure that the temperature of the seawater in the pipes is not increased by the influence of the environmental temperature, so that the temperature of the seawater obtained from the seabed is more suitable for the survival of seawater fishes, and the storage rate of the seawater fishes is improved.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like are used in an orientation or positional relationship indicated based on the orientation or positional relationship of the device or component as it is normally used, merely for convenience of description and simplicity of description, and do not indicate or imply that the device or component in question must have a particular orientation, be constructed and operated in a particular orientation at any time, unless otherwise specified herein.

Although specific embodiments of the present invention have been described above, it will be understood by those skilled in the art that this is by way of example only and that the scope of the invention is defined by the appended claims. Various changes and modifications to these embodiments may be made by those skilled in the art without departing from the spirit and the principles of the present invention, and these changes and modifications are all within the scope of the present invention.

Claims (11)

1. A water intake device of a deep sea culture ship comprises a first water intake pipe, wherein the first water intake pipe extends to the sea bottom and is used for being communicated with seawater on the sea bottom;

the second water taking pipe is connected and communicated with the first water taking pipe, extends to the ship body and is used for being communicated with the culture tank in the ship body;

the second intake pipe is a flexible pipe, one end of the second intake pipe close to the first intake pipe is fixed on the buoyancy block, and the buoyancy block can float upwards.

2. The water intake apparatus for a deep sea aquaculture vessel of claim 1, wherein said second water intake pipe is provided at a middle region of the bottom of the vessel near one end of the hull.

3. The water intake apparatus for a deep sea aquaculture vessel of claim 1, wherein said first water intake pipe is a flexible pipe; the water taking device of the deep sea culture ship further comprises a winding and unwinding winch, the winding and unwinding winch is connected with the first water taking pipe, and the winding and unwinding winch is used for recycling and laying the first water taking pipe.

4. The deep sea utility vessel water intake device of claim 3, further comprising a third water intake pipe, the third water intake pipe being a flexible pipe, the third water intake pipe being connected between the retraction winch and the first water intake pipe.

5. The water intake apparatus for a deep sea aquaculture vessel of claim 4 wherein said buoyancy block is disposed proximate to the junction of said first water intake pipe and said third water intake pipe.

6. The deep sea culturing ship water intake device according to claim 3, further comprising a rectifying pipe fixed to the buoyancy block and extending in the seabed direction, wherein the first water intake pipe passes through the rectifying pipe in the vertical direction.

7. The water intake apparatus for a deep sea culturing vessel according to claim 1, further comprising a water storage pipe provided inside the hull, one end of the water storage pipe being connected to and communicating with the second water intake pipe, and the other end of the water storage pipe extending to and communicating with the culturing tank.

8. The deep sea culture vessel water intake device of claim 7, wherein the diameter of the water storage pipe is larger than the diameter of the second water intake pipe.

9. The water intake apparatus for a deep sea aquaculture vessel of claim 8, wherein said water storage pipe is connected to said second water intake pipe by a pipe connector, and wherein the diameter of the end of said pipe connector near said water storage pipe is larger than the diameter of the end of said pipe connector near said second water intake pipe.

10. The deep sea culture vessel water intake device according to claim 9, wherein the pipe connector is provided with an internal thread at an end thereof adjacent to the second intake pipe, and an external thread at an end thereof adjacent to the pipe connector, the pipe connector being screwed with the second intake pipe;

an external thread is arranged at one end of the pipeline connector close to the water storage pipe, an internal thread is arranged at one end of the water storage pipe close to the pipeline connector, and the pipeline connector is screwed with the water storage pipe;

the joint of the pipeline connector and the second water taking pipe and the joint of the pipeline connector and the water storage pipe are sealed.

11. A deep sea culture vessel comprising the water intake device of the deep sea culture vessel according to any one of claims 1 to 10.

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