CN219608511U - Water quality monitoring device for deep sea - Google Patents

Abstract

The utility model provides a water quality monitoring device for deep sea, which comprises a sealed cabin, a photographing assembly, a sample reserving assembly and a remote control unit, wherein the sealed cabin is provided with a sample collecting unit; the camera can provide good visual field for operators through the transparent spherical cover. The sample reserving components of the device comprise a plurality of sample reserving components which are arranged at the rear end of the sealed cabin; the setting of a plurality of sample reservation subassemblies can reserve the sample to the sea water of different waters different degree of depth, has improved the scope of monitoring, and the water sample is more various, and the testing result is more reliable. The working principle of the sample reserving component is as follows: when the environmental water body needs to be sampled, the control component releases the limit of the tail part of the piston, after the limit of the tail part of the piston is released, the piston moves in the direction away from the sample reserving barrel under the drive of the spring force, the sample reserving barrel is provided with negative pressure, the external water body is sucked into the sample reserving barrel to reserve samples, and the purpose of bringing the water body sample back to the ground for more comprehensive analysis and detection is achieved.

Description

Water quality monitoring device for deep sea

Technical Field

The utility model relates to the technical field of biological research and monitoring, in particular to a water quality monitoring device for deep sea.

Background

The advantages of offshore cultivation in deep sea compared with offshore shallow water cultivation are that the cultivation area is wider; the seawater has high fluidity under the action of ocean currents, and the seawater is more rich in natural foods for cultivating fishes; the larger water depth improves the effective aquaculture water space per water surface. Meanwhile, with the continuous promotion of the ocean national strategy in China, the market demand of the water area monitoring equipment with high cost performance is very large in a long period of time in the future, so that the development of the intelligent water area monitoring equipment with various functions and high cost performance is very necessary. Because the detection sensors carried by the submerged detection equipment are limited, the comprehensive detection of the seawater in different areas of the deep sea is not realized, and therefore, the detection capability of the existing deep sea water quality detection equipment is very limited.

Disclosure of Invention

The technical problems to be solved by the utility model are as follows: the water quality monitoring device for the deep sea provided by the utility model can realize remote control sample retention and carry out depth detection on a road surface.

A water quality monitoring device for deep sea comprises a sealed cabin, a photographing assembly, a sample reserving assembly and a remote control unit;

the remote control unit is arranged in the sealed cabin and is respectively and electrically connected with the photographing assembly and the sample reserving assembly;

the shooting assembly is arranged in the sealed cabin and positioned at the front end;

the shooting assembly comprises a camera and a picture transmission unit; the front end of the sealed cabin is a transparent spherical cover; the camera and the image transmission unit are hermetically arranged in the sealed cabin, and the camera is electrically connected with the image transmission unit; the camera is arranged at one end close to the transparent spherical cover;

the sample reserving components comprise a plurality of sample reserving components, and the sample reserving components are arranged at the rear end of the sealed cabin;

the sample reserving component comprises a control component, a sample reserving cylinder, a piston and a spring; the sample reserving cylinder is fixedly arranged at the rear end of the sealed cabin, and a sampling port of the sample reserving cylinder is communicated with the outside; the piston can be arranged in the sample reserving cylinder in a reciprocating sliding manner; the spring is sleeved on the body of the piston, one end of the spring is abutted against the tail of the piston, and the other end of the spring is abutted against one end of the sample reserving cylinder; the control assembly is arranged outside the sealed cabin and used for limiting the piston.

Further, the control assembly comprises a drive disc, a fixed disc and a plurality of motion stops;

the driving disc is rotatably arranged at the top of the fixed disc; the rotation axis of the driving disc and the virtual axis of the fixed disc are coaxially arranged; the plurality of motion baffles are wound on the fixed disc at equal intervals;

the driving disc drives the motion baffle plate to perform centripetal motion or centrifugal motion relative to the fixed disc.

Further, a limiting column is arranged on the bottom surface of the motion baffle;

the top surface of the motion baffle is provided with a guide block;

a limiting slotted hole matched with each limiting column is correspondingly arranged on the driving disc; the bottom surface of the fixed disk is provided with a guide chute matched with the guide block.

Further, the control assembly further comprises a turbine, a worm and a control motor;

the end face of the turbine is fixedly connected with the top of the driving disc, and the turbine and the driving disc are coaxially arranged;

one end of the worm is fixedly connected with an output shaft of the control motor;

the worm is in transmission connection with the turbine;

the driving motor is electrically connected with the remote control unit.

Further, one end of the sample reserving barrel, which is far away from the piston, is provided with a recovery port; a first one-way valve is arranged at the recycling port, and the check direction of the first one-way valve faces towards the sample reserving barrel;

the sampling port is arranged on the side wall of the sample reserving barrel; the sampling port is provided with a second one-way valve, and the check direction of the second one-way valve is far away from the interior of the sample reserving barrel.

Further, the device also comprises a mounting bracket, water pumping and draining equipment and two ballast tanks;

the mounting bracket is fixedly arranged at the bottom of the sealed cabin;

the water pumping and draining equipment is arranged on the mounting bracket;

the two ballast tanks are symmetrically arranged at the bottom of the mounting bracket; the openings of the two ballast tanks are respectively connected with the same port of the water pumping and draining equipment.

Further, the device also comprises a fixed bracket and a plurality of power components;

the fixed support is arranged in the middle of the sealed cabin;

the power components are symmetrically arranged on two sides of the fixed bracket in a left-right mode; the power assembly is arranged at the top of the fixed support, and the power output direction is vertical to the horizontal plane; the power assembly positioned at the bottom of the fixed bracket is horizontally arranged, and the power output direction is parallel to the horizontal plane;

the power components are respectively and electrically connected with the remote control unit.

Further, the system also comprises a GPS positioning module and a water temperature monitoring module;

the GPS positioning module is integrated on the remote control unit;

the water temperature monitoring module is electrically connected with the remote control unit and used for monitoring the water body environment temperature.

The utility model has the beneficial effects that: the utility model provides a water quality monitoring device for deep sea, which comprises a sealed cabin, a photographing assembly, a sample reserving assembly and a remote control unit, wherein the sealed cabin is provided with a sample collecting unit; the camera can provide good visual field for operators through the transparent spherical cover. The sample reserving components of the device comprise a plurality of sample reserving components which are arranged at the rear end of the sealed cabin; the setting of a plurality of sample reservation subassemblies can reserve the sample to the sea water of different waters different degree of depth, has improved the scope of monitoring, and the water sample is more various, and the testing result is more reliable. The working principle of the sample reserving component is as follows: when the environmental water body needs to be sampled, the control component releases the limit of the tail part of the piston, after the limit of the tail part of the piston is released, the piston moves in the direction away from the sample reserving barrel under the drive of the spring force, the sample reserving barrel is provided with negative pressure, the external water body is sucked into the sample reserving barrel to reserve samples, and the purpose of bringing the water body sample back to the ground for more comprehensive analysis and detection is achieved.

Drawings

FIG. 1 is a schematic view of a first construction of a water quality monitoring device for deep sea according to an embodiment of the present utility model;

FIG. 2 is a schematic diagram showing a second construction of a water quality monitoring apparatus for deep sea according to an embodiment of the present utility model;

FIG. 3 is an enlarged view of part of A in FIG. 2;

FIG. 4 is a schematic diagram showing the installation of a sample retention assembly of a water quality monitoring device for deep sea according to an embodiment of the present utility model;

FIG. 5 is a schematic view showing a first structure of a control assembly of a water quality monitoring device for deep sea according to an embodiment of the present utility model;

FIG. 6 is a schematic view showing a second structure of a control assembly of a water quality monitoring device for deep sea according to an embodiment of the present utility model;

FIG. 7 is a schematic view showing a structure of a fixed disk of a control assembly of a water quality monitoring device for deep sea according to an embodiment of the present utility model;

FIG. 8 is a schematic view of a motion barrier of a control assembly of a water quality monitoring device for deep sea according to an embodiment of the present utility model;

FIG. 9 is a schematic diagram of a sample retention assembly of a water quality monitoring device for deep sea according to an embodiment of the present utility model;

FIG. 10 is a cross-sectional view of a sample retention assembly for a deep sea water quality monitoring device according to an embodiment of the present utility model;

description of the reference numerals:

1. sealing the cabin; 2. a transparent spherical cover; 3. reserving a sample barrel; 4, a piston; 5. a spring; 6. a drive plate; 7. a fixed plate; 8. a motion baffle; 9. a limit column; 10. a guide block; 11. limiting slot holes; 12. a guide chute; 13. a turbine; 14. a worm; 15. controlling a motor; 16. recovering the mouth; 17. a sampling port; 18. a first one-way valve; 19. a second one-way valve; 20. a mounting bracket; 21. a water extraction and drainage device; 22. a ballast tank; 23. a power assembly; 24. and (5) fixing the bracket.

Detailed Description

In order to describe the technical contents, the achieved objects and effects of the present utility model in detail, the following description will be made with reference to the embodiments in conjunction with the accompanying drawings.

Referring to fig. 1 to 10, a water quality monitoring device for deep sea includes a sealed cabin, a photographing assembly, a sample reserving assembly and a remote control unit;

the remote control unit is arranged in the sealed cabin and is respectively and electrically connected with the photographing assembly and the sample reserving assembly;

the shooting assembly is arranged in the sealed cabin and positioned at the front end;

the shooting assembly comprises a camera and a picture transmission unit; the front end of the sealed cabin is a transparent spherical cover; the camera and the image transmission unit are hermetically arranged in the sealed cabin, and the camera is electrically connected with the image transmission unit; the camera is arranged at one end close to the transparent spherical cover;

the sample reserving components comprise a plurality of sample reserving components, and the sample reserving components are arranged at the rear end of the sealed cabin;

the sample reserving component comprises a control component, a sample reserving cylinder, a piston and a spring; the sample reserving cylinder is fixedly arranged at the rear end of the sealed cabin, and a sampling port of the sample reserving cylinder is communicated with the outside; the piston can be arranged in the sample reserving cylinder in a reciprocating sliding manner; the spring is sleeved on the body of the piston, one end of the spring is abutted against the tail of the piston, and the other end of the spring is abutted against one end of the sample reserving cylinder; the control assembly is arranged outside the sealed cabin and used for limiting the piston.

As can be seen from the above description, the water quality monitoring device for deep sea provided by the present utility model comprises a sealed cabin, a photographing assembly, a sample reserving assembly and a remote control unit; the camera can provide good visual field for operators through the transparent spherical cover. The sample reserving components of the device comprise a plurality of sample reserving components which are arranged at the rear end of the sealed cabin; the setting of a plurality of sample reservation subassemblies can reserve the sample to the sea water of different waters different degree of depth, has improved the scope of monitoring, and the water sample is more various, and the testing result is more reliable. The working principle of the sample reserving component is as follows: when the environmental water body needs to be sampled, the control component releases the limit of the tail part of the piston, after the limit of the tail part of the piston is released, the piston moves in the direction away from the sample reserving barrel under the drive of the spring force, the sample reserving barrel is provided with negative pressure, the external water body is sucked into the sample reserving barrel to reserve samples, and the purpose of bringing the water body sample back to the ground for more comprehensive analysis and detection is achieved.

Further, the control assembly comprises a drive disc, a fixed disc and a plurality of motion stops;

the driving disc is rotatably arranged at the top of the fixed disc; the rotation axis of the driving disc and the virtual axis of the fixed disc are coaxially arranged; the plurality of motion baffles are wound on the fixed disc at equal intervals;

the driving disc drives the motion baffle plate to perform centripetal motion or centrifugal motion relative to the fixed disc.

As can be seen from the above description, the piston tail is limited by using the driving disc to drive the plurality of moving baffles to perform centripetal movement or centrifugal movement simultaneously; when a plurality of motion baffles do centrifugal motion simultaneously, the limit of the tail part of the piston is released, water body adoption is completed, and the executing mechanism is stable and reliable.

Further, a limiting column is arranged on the bottom surface of the motion baffle;

the top surface of the motion baffle is provided with a guide block;

a limiting slotted hole matched with each limiting column is correspondingly arranged on the driving disc; the bottom surface of the fixed disk is provided with a guide chute matched with the guide block.

From the above description, the driving disc rotates, and the motion baffle is driven to move through the cooperation of the limiting slotted hole and the limiting column, and the motion baffle makes centripetal or centrifugal motion relative to the fixed disc along the guiding chute due to the guiding effect of the guiding block on the guiding chute. When each motion baffle plate makes centripetal motion, the motion of the piston is just blocked, and the limiting effect is achieved; when each motion baffle plate performs centrifugal motion, the limit of the piston is released, the piston slides under the action of the elastic force of the spring, and the water body sample reserving is completed.

Further, the control assembly further comprises a turbine, a worm and a control motor;

the end face of the turbine is fixedly connected with the top of the driving disc, and the turbine and the driving disc are coaxially arranged;

one end of the worm is fixedly connected with an output shaft of the control motor;

the worm is in transmission connection with the turbine;

the driving motor is electrically connected with the remote control unit.

From the above description, it is known that the worm drive is equivalent to a screw drive, is a multi-tooth meshing drive, and has advantages of stable drive, low noise, and the like.

Further, one end of the sample reserving barrel, which is far away from the piston, is provided with a recovery port; a first one-way valve is arranged at the recycling port, and the check direction of the first one-way valve faces towards the sample reserving barrel;

the sampling port is arranged on the side wall of the sample reserving barrel; the sampling port is provided with a second one-way valve, and the check direction of the second one-way valve is far away from the interior of the sample reserving barrel.

From the above description, the purpose of the recovery port is to facilitate collection of the collected water body sample, when the piston moves away from the sample reserving barrel, negative pressure is formed in the sample reserving barrel, the second one-way valve is opened, the first one-way valve is closed, and water body is collected into the sample reserving barrel from the sampling port; when the device returns to the ground, a technician manually extrudes the piston into the sample reserving barrel, at the moment, the first one-way valve is opened, the second one-way valve is closed, and a sample in the sample reserving barrel flows from the recovery port, so that the sample collecting work is completed.

Further, the device also comprises a mounting bracket, water pumping and draining equipment and two ballast tanks;

the mounting bracket is fixedly arranged at the bottom of the sealed cabin;

the water pumping and draining equipment is arranged on the mounting bracket;

the two ballast tanks are symmetrically arranged at the bottom of the mounting bracket; the openings of the two ballast tanks are respectively connected with the same port of the water pumping and draining equipment.

From the above description, the ballast tank is designed to assist the device in floating and sinking; when the water pumping and draining equipment performs water injection operation in the ballast tank, the submergence is completed; when the water pumping and draining equipment pumps water in the ballast tank, the floating action is completed.

Further, the device also comprises a fixed bracket and a plurality of power components;

the fixed support is arranged in the middle of the sealed cabin;

the power components are symmetrically arranged on two sides of the fixed bracket in a left-right mode; the power assembly is arranged at the top of the fixed support, and the power output direction is vertical to the horizontal plane; the power assembly positioned at the bottom of the fixed bracket is horizontally arranged, and the power output direction is parallel to the horizontal plane;

the power components are respectively and electrically connected with the remote control unit.

From the above description, it is clear that the arrangement of a plurality of power assemblies can provide flexible steering for the device.

Further, the system also comprises a GPS positioning module and a water temperature monitoring module;

the GPS positioning module is integrated on the remote control unit;

the water temperature monitoring module is electrically connected with the remote control unit and used for monitoring the water body environment temperature.

From the above description, the GPS positioning module can well provide water depth information for the device; and the acquired seawater samples are required to be encoded to provide position information, so that the corresponding water areas of a plurality of water samples can be accurately recorded. The water temperature monitoring module can monitor the water temperature, and the parameter cannot return to ground detection.

Referring to fig. 1 to 10, a first embodiment of the present utility model is as follows:

a water quality monitoring device for deep sea comprises a sealed cabin 1, a photographing assembly, a sample reserving assembly and a remote control unit; the remote control unit is arranged in the sealed cabin 1 and is respectively and electrically connected with the photographing assembly and the sample reserving assembly; the sealed cabin 1 can provide a water-free environment for electrical equipment and ensure the working safety of electrical components.

The shooting component is arranged in the sealed cabin 1 and positioned at the front end; the shooting component comprises a camera and a picture transmission unit; the front end of the sealed cabin 1 is provided with a transparent spherical cover 2; the camera shoots outwards through the transparent spherical cover 2 to provide a good visual field for the operating technician; the setting of a plurality of sample reservation subassemblies can reserve the sample to the sea water of different waters different degree of depth, has improved the scope of monitoring, and the water sample is more various, and the testing result is more reliable. The working principle of the sample reserving component is as follows: when the environmental water body is required to be sampled, the control component releases the limit of the tail part of the piston, and after the limit of the tail part of the piston is released, the piston is arranged on the spring 4; 5 the direction that the sample reserving barrel 3 was kept away from under the drive of elasticity removes, and sample reserving barrel 3 forms the negative pressure, inhales external water body and reserves the appearance in the sample reserving barrel, realizes bringing the water body sample back to ground and carries out more comprehensive analysis and detection purpose.

Referring to fig. 5 to 8, specifically, the control assembly includes a driving disc 6, a fixed disc 7, and a plurality of moving baffles 8; the driving disc 6 is rotatably arranged on the top of the fixed disc 7; the rotation axis of the driving disk 6 is coaxially arranged with the virtual axis of the fixed disk 7; a plurality of motion baffles 8 are wound on the fixed disc 7 at equal intervals; the driving disk 6 drives the movement baffle 8 to perform centripetal movement or centrifugal movement relative to the fixed disk 7. The specific working process is as follows: the driving disc 6 rotates, and the motion baffle plate 8 is driven to move through the cooperation of the limit slotted hole 11 and the limit column 9, and the motion baffle plate 8 performs centripetal or centrifugal motion relative to the fixed disc 7 along the guide chute 12 due to the guiding effect of the guide block 10 on the guide chute 12. When each motion baffle plate 8 makes centripetal motion, the motion of the piston is just blocked, and the limiting effect is achieved; when each motion baffle plate 8 performs centrifugal motion, the limit of the piston is released, and the piston is positioned on the piston of the spring 4; 5, sliding under the action of elasticity to finish water sample retention.

Referring to fig. 5 and 6, specifically, the control assembly further includes a turbine 13, a worm 14, and a control motor 15; the end face of the turbine 13 is fixedly connected with the top of the driving disc 6, and the turbine 13 and the driving disc 6 are coaxially arranged; one end of the worm 14 is fixedly connected with an output shaft of the control motor 15; the worm 14 is in transmission connection with the turbine 13; the driving motor is electrically connected with the remote control unit.

Specifically, the control motor 15 needs to be waterproof wrapped, and specific waterproof measures are not described herein.

Referring to fig. 9 and 10, specifically, a recovery port 16 is provided at an end of the sample barrel 3 away from the piston; the recovery port 16 is provided with a first one-way valve 18, and the non-return direction of the first one-way valve 18 faces into the sample reserving barrel 3; the sampling port 17 is arranged on the side wall of the sample reserving barrel 3; the sampling port 17 is provided with a second one-way valve 19, and the check direction of the second one-way valve 19 is far away from the interior of the sample reserving barrel 3. The recovery port 16 is arranged to be convenient for collecting the collected water body sample, when the piston moves far away from the sample reserving barrel 3, negative pressure is formed in the sample reserving barrel 3, the second one-way valve 19 is opened at the moment, the first one-way valve 18 is closed, and the water body is collected into the sample reserving barrel 3 from the sampling port 17; when the device returns to the ground, a technician manually extrudes the piston into the sample reserving barrel 3, at the moment, the first one-way valve 18 is opened, the second one-way valve 19 is closed, and the sample in the sample reserving barrel 3 flows from the recovery port 16, so that the sample collecting work is completed.

Referring to fig. 1 and 2, the ballast water pump specifically further comprises a mounting bracket 20, a water pumping and draining device 21 and two ballast tanks 22;

the mounting bracket 20 is fixedly arranged at the bottom of the sealed cabin 1; the water pumping and draining equipment 21 is arranged on the mounting bracket 20; the two ballast tanks 22 are symmetrically arranged at the bottom of the mounting bracket 20; the openings of the two ballast tanks 22 are connected to the same port of the water pumping and draining equipment 21, respectively.

Specifically, the waterproofing measures of the water drawing and draining apparatus 21 will not be described in detail herein.

Referring to fig. 1 and 2, the device specifically further includes a fixing bracket 24 and a plurality of power assemblies 23;

the fixed bracket 24 is arranged in the middle of the sealed cabin 1; the power components 23 are symmetrically arranged on two sides of the fixed bracket 24; the power assembly 23 is arranged vertically at the top of the fixed bracket 24, and the power output direction is vertical to the horizontal plane; the power assembly 23 positioned at the bottom of the fixed bracket 24 is horizontally arranged, and the power output direction is parallel to the horizontal plane; the plurality of power assemblies 23 are electrically connected to the remote control unit, respectively.

Preferably, the fixing bracket 24 adopts a triangular wing-shaped structure, so that better stability is achieved.

Specifically, the system also comprises a GPS positioning module and a water temperature monitoring module; the GPS positioning module is integrated on the remote control unit; the water temperature monitoring module is electrically connected with the remote control unit and is used for monitoring the water body environment temperature. Specifically, the electrical connection between the GPS positioning module and the control unit is a relatively mature prior art, so that no further description is given here.

Specifically, the water temperature monitoring module belongs to a relatively mature prior art, so that redundant description is omitted here.

In summary, the water quality monitoring device for deep sea provided by the utility model has the following advantages:

1. the sample reserving components of the device comprise a plurality of sample reserving components which are arranged at the rear end of the sealed cabin; the setting of a plurality of sample reservation subassemblies can reserve the sample to the sea water of different waters different degree of depth, has improved the scope of monitoring, and the water sample is more various, and the testing result is more reliable. The working principle of the sample reserving component is as follows: when the environmental water body is required to be sampled, the control component releases the limit of the tail part of the piston, after the limit of the tail part of the piston is released, the piston moves to a direction away from the sample reserving barrel under the drive of the spring force, the sample reserving barrel is driven to form negative pressure, the external water body is sucked into the sample reserving barrel to reserve samples, and the purpose of bringing the water body sample back to the ground for more comprehensive analysis and detection is achieved;

2. the control assembly rotates by using the driving disc, and drives the motion baffle to move through the cooperation of the limiting slotted hole and the limiting column, and the motion baffle makes centripetal or centrifugal motion relative to the fixed disc along the guiding chute due to the guiding effect of the guiding block on the guiding chute. When each motion baffle plate makes centripetal motion, the motion of the piston is just blocked, and the limiting effect is achieved; when each motion baffle plate performs centrifugal motion, the limit of the piston is released, the piston slides under the action of the elastic force of the spring, water sample retention is completed, and the actuating mechanism is stable and reliable and compact in structure.

The foregoing description is only illustrative of the present utility model and is not intended to limit the scope of the utility model, and all equivalent changes made by the specification and drawings of the present utility model, or direct or indirect application in the relevant art, are included in the scope of the present utility model.

Claims (8)

1. The water quality monitoring device for the deep sea is characterized by comprising a sealed cabin, a photographing assembly, a sample reserving assembly and a remote control unit;

the remote control unit is arranged in the sealed cabin and is respectively and electrically connected with the photographing assembly and the sample reserving assembly;

the shooting assembly is arranged in the sealed cabin and positioned at the front end;

the shooting assembly comprises a camera and a picture transmission unit; the front end of the sealed cabin is a transparent spherical cover; the camera and the image transmission unit are hermetically arranged in the sealed cabin, and the camera is electrically connected with the image transmission unit; the camera is arranged at one end close to the transparent spherical cover;

the sample reserving components comprise a plurality of sample reserving components, and the sample reserving components are arranged at the rear end of the sealed cabin;

the sample reserving component comprises a control component, a sample reserving cylinder, a piston and a spring; the sample reserving cylinder is fixedly arranged at the rear end of the sealed cabin, and a sampling port of the sample reserving cylinder is communicated with the outside; the piston can be arranged in the sample reserving cylinder in a reciprocating sliding manner; the spring is sleeved on the body of the piston, one end of the spring is abutted against the tail of the piston, and the other end of the spring is abutted against one end of the sample reserving cylinder; the control assembly is arranged outside the sealed cabin and used for limiting the piston.

2. The water quality monitoring device for deep sea according to claim 1, wherein the control assembly comprises a drive plate, a fixed plate and a plurality of moving baffles;

the driving disc is rotatably arranged at the top of the fixed disc; the rotation axis of the driving disc and the virtual axis of the fixed disc are coaxially arranged; the plurality of motion baffles are wound on the fixed disc at equal intervals;

the driving disc drives the motion baffle plate to perform centripetal motion or centrifugal motion relative to the fixed disc.

3. The water quality monitoring device for deep sea according to claim 2, wherein the bottom surface of the moving baffle is provided with a limit column;

the top surface of the motion baffle is provided with a guide block;

a limiting slotted hole matched with each limiting column is correspondingly arranged on the driving disc; the bottom surface of the fixed disk is provided with a guide chute matched with the guide block.

4. A water quality monitoring device for deep sea according to claim 3, wherein the control assembly further comprises a turbine, a worm and a control motor;

the end face of the turbine is fixedly connected with the top of the driving disc, and the turbine and the driving disc are coaxially arranged;

one end of the worm is fixedly connected with an output shaft of the control motor;

the worm is in transmission connection with the turbine;

the control motor is electrically connected with the remote control unit.

5. The water quality monitoring device for deep sea according to claim 1, wherein one end of the sample reserving barrel far away from the piston is provided with a recovery port; a first one-way valve is arranged at the recycling port, and the check direction of the first one-way valve faces towards the sample reserving barrel;

the sampling port is arranged on the side wall of the sample reserving barrel; the sampling port is provided with a second one-way valve, and the check direction of the second one-way valve is far away from the interior of the sample reserving barrel.

6. The water quality monitoring device for deep sea according to claim 1, further comprising a mounting bracket, a water pumping and draining facility, and two ballast tanks;

the mounting bracket is fixedly arranged at the bottom of the sealed cabin;

the water pumping and draining equipment is arranged on the mounting bracket;

the two ballast tanks are symmetrically arranged at the bottom of the mounting bracket; the openings of the two ballast tanks are respectively connected with the same port of the water pumping and draining equipment.

7. The water quality monitoring device for deep sea of claim 1, further comprising a stationary support and a plurality of power components;

the fixed support is arranged in the middle of the sealed cabin;

the power components are symmetrically arranged on two sides of the fixed bracket in a left-right mode; the power assembly is arranged at the top of the fixed support, and the power output direction is vertical to the horizontal plane; the power assembly positioned at the bottom of the fixed bracket is horizontally arranged, and the power output direction is parallel to the horizontal plane;

the power components are respectively and electrically connected with the remote control unit.

8. The water quality monitoring device for deep sea according to claim 1, further comprising a GPS positioning module and a water temperature monitoring module;

the GPS positioning module is integrated on the remote control unit;

the water temperature monitoring module is electrically connected with the remote control unit and used for monitoring the water body environment temperature.