CN112078731A

CN112078731A - Ecological information identification equipment based on network

Info

Publication number: CN112078731A
Application number: CN202011025352.4A
Authority: CN
Inventors: 徐军红
Original assignee: Guangzhou Mutual Media Yingdong Culture Media Technology Co ltd
Current assignee: Liaocheng Aizhi Information Technology Co.,Ltd.
Priority date: 2020-09-25
Filing date: 2020-09-25
Publication date: 2020-12-15
Anticipated expiration: 2040-09-25
Also published as: CN112078731B

Abstract

The invention discloses a network-based ecological information identification device, which comprises a movable shell, wherein a water pressure cavity with an upward opening is arranged in the movable shell, a sliding plate is arranged in the water pressure cavity in a sliding manner, a movable cavity is communicated with the inner side of the lower end wall of the water pressure cavity, a movable thread block is arranged in the movable cavity in a sliding manner, a connecting spring is fixedly arranged on the upper end surface of the movable thread block, and a pushing block which is arranged in the movable cavity in a sliding manner is fixedly arranged at the upper end of the connecting spring; the invention can realize the automatic up-and-down movement by the deep sea water pressure to recognize and record the ecological information of the fixed-point sea, and transmit the recorded ecological information to the ground through the network for analysis and maintenance.

Description

Ecological information identification equipment based on network

Technical Field

The invention relates to the field of information identification, in particular to ecological information identification equipment based on a network.

Background

The identification and recording of the ecological information of the ocean is very important, which can play a great role and inspiration in the development of human beings and is very important for helping people to know the ocean, and many devices at the present stage need to identify and record the ecological information of the ocean through high-power motors and power devices, so that long-term human intervention is needed, a large amount of energy is needed, the cost is high, and the technology is difficult.

Disclosure of Invention

The invention aims to provide ecological information identification equipment based on a network, and solves the problems of low detection efficiency and low accuracy of vacuum packaging bags.

The invention is realized by the following technical scheme.

The invention relates to a network-based ecological information identification device, which comprises a movable shell, wherein a water pressure cavity with an upward opening is arranged in the movable shell, a sliding plate is arranged in the water pressure cavity in a sliding manner, a movable cavity is communicated with the inner wall of the lower end of the water pressure cavity, a movable threaded block is arranged in the movable cavity in a sliding manner, a connecting spring is fixedly arranged on the upper end surface of the movable threaded block, and a pushing block which is arranged in the movable cavity in a sliding manner is fixedly arranged on the upper end of the connecting spring;

a bilaterally symmetrical connecting cavity is communicated and arranged in the left end wall and the right end wall of the moving cavity, a sealing block is slidably arranged in the connecting cavity, one end of the sealing block, which is close to the center line of the moving cavity, extends into the moving cavity to block the pushing block from moving upwards, a sliding cavity is communicated and arranged below the connecting cavity, a connecting groove with a downward opening is arranged in the lower end face of the sealing block, a hinge rod is hinged in the connecting groove, a reset spring is fixedly arranged between the right end face of the sealing block and the end face of the connecting cavity, which is far away from the center line of the moving cavity, a moving block slidably arranged in the sliding cavity is hinged at the lower end of the hinge rod, and a filter block;

an open slot with a downward opening is arranged in the filter block, a rotatable rotating wheel is arranged in the open slot, annular open cavities which are symmetrical front and back and have openings facing away from the center line of the moving cavity are arranged in the front and back end surfaces of the moving shell, closed glass is fixedly arranged at the openings of the annular open cavities, the outward openings of the annular open cavities are closed by the closed glass, a camera recognizer is rotatably arranged in the annular open cavities, a network transmitter is fixedly arranged in the end surface of the camera recognizer on the side away from the center line of the moving cavity, a rotating block is fixedly arranged in the end surface of the network transmitter on the side away from the center line of the moving cavity, water inlet pipelines which are symmetrical left and right are fixedly arranged in the left and right end walls of the water pressure cavity, a water inlet pipeline is fixedly arranged at one end of the water inlet pipeline, which is far away from the center, the water inlet pipe is characterized in that an extending cavity is communicated and arranged in the left end wall and the right end wall of the water inlet pipe, the opening of the extending cavity faces away from the central line side of the moving cavity, a water pressure block is arranged at the opening of the extending cavity in a sliding installation mode, the water pressure block seals the outward position of the opening of the extending cavity, and a fixing spring is fixedly arranged between the end face of one side, close to the central line of the moving cavity, of the water pressure block and the end wall of one side, close to the central.

Preferably, a rotating cavity located in the movable housing is arranged above the open slot, the upper end of the rotating wheel is fixedly mounted on a driving threaded shaft, the driving threaded shaft is rotatably mounted between the open slot and the rotating cavity, a rotating gear fixedly mounted on the driving threaded shaft is arranged in the rotating cavity, connecting gears are symmetrically arranged on the front side and the rear side of the rotating gear, the connecting gears are meshed with the rotating gear, the connecting gears are fixedly mounted on a connecting shaft, a pulley cavity is arranged above the rotating gear, the connecting shaft is rotatably mounted between the rotating gear and the pulley cavity, a rotating belt pulley fixedly mounted on the connecting shaft is arranged in the pulley cavity, a rotating belt pulley is arranged on the left side of the rotating belt pulley, and the rotating belt pulley is connected with the rotating belt pulley through a connecting belt, the rotary belt pulley is fixedly installed on a driven shaft, the driven shaft is installed between the belt pulley cavity and the annular opening cavity in a rotating mode, a rotary gear fixedly installed on the driven shaft is arranged in the annular opening cavity, and one side, far away from the center line of the moving cavity, of the rotary gear is connected with the camera shooting recognizer in a meshing mode.

Preferably, a thread groove with a downward opening is formed in the lower end face of the movable thread block, the upper end of the driving thread shaft extends into the thread groove and is in threaded connection with the thread groove, a rotation cavity which is communicated with the movable cavity and is bilaterally symmetrical is formed between the pushing block and the movable thread block, a rotation shaft is rotatably installed on the front end wall and the rear end wall of the rotation cavity, a connecting gear is fixedly arranged on the rotation shaft, a rotation block fixedly installed on the rotation shaft is arranged on the front side of the connecting gear, one end, close to the center line of the movable cavity, of the rotation block extends into the movable cavity, and one side, far away from the center line of the movable cavity, of the connecting gear is in meshed connection with one side.

Preferably, the front end wall and the rear end wall of the moving cavity are communicated with linking cavities which are symmetrical front and back, a clamping block is arranged in the linking cavities in a sliding mode, one end, close to the center line of the moving cavity, of the clamping block can extend into the moving cavity to block the pushing block from moving downwards, a rack cavity is communicated and arranged below the linking cavities, a linking cavity with a downward opening is arranged in the lower end face of the clamping block, a connecting rod is hinged in the linking cavity, a linking spring is fixedly arranged between the right end face of the clamping block and the end face of the linking cavity, far away from the center line of the moving cavity, of the linking cavity, a moving rack which is slidably arranged in the rack cavity is hinged at the lower end of the connecting rod, a transmission cavity which is communicated with the moving cavity and symmetrical front and back is arranged below the rotating cavity, limiting shafts are rotatably arranged on the left end wall and, one end, close to the center line of the moving cavity, of the limiting plate can extend into the moving cavity, and one side, far away from the center line of the moving cavity, of the transmission gear is meshed and connected with one side, close to the center line of the moving cavity, of the moving rack.

Preferably, a buoyancy block is arranged above the movable shell, a rope wheel cavity with a downward opening is formed in the lower end face of the buoyancy block, a rope wheel shaft is arranged in the left end wall and the right end wall of the rope wheel cavity in a rotating mode, a rope wheel is fixedly arranged on the rope wheel shaft, a connecting rope is wound on the rope wheel, four fixing ropes are fixedly arranged at the lower end of the connecting rope, and the lower end of each fixing rope is fixedly arranged on the upper end face of the movable shell in a circumferential array mode.

Preferably, a closing plate is fixedly arranged at the upward opening of the water pressure cavity, and a one-way check valve is fixedly arranged in the closing plate.

The invention has the beneficial effects that: the invention can realize the automatic up-and-down movement by the deep sea water pressure to recognize and record the ecological information of the fixed-point sea, and transmit the recorded ecological information to the ground through the network for analysis and maintenance.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a schematic structural diagram at A-A in FIG. 1 according to an embodiment of the present invention;

FIG. 3 is an enlarged schematic view of the embodiment of the present invention at B in FIG. 1;

FIG. 4 is an enlarged schematic view of the embodiment of the present invention at C in FIG. 2.

Detailed Description

The invention will now be described in detail with reference to fig. 1-4, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The ecological information identification device based on the network, which is described with reference to fig. 1-4, comprises a movable housing 19, a hydraulic pressure chamber 24 with an upward opening is arranged in the movable housing 19, a sliding plate 25 is arranged in the hydraulic pressure chamber 24 in a sliding manner, a movable chamber 16 is arranged in the lower end wall of the hydraulic pressure chamber 24 in a communicating manner, a movable threaded block 17 is arranged in the movable chamber 16 in a sliding manner, a connecting spring 55 is fixedly arranged on the upper end surface of the movable threaded block 17, a pushing block 33 which is slidably arranged in the movable chamber 16 is fixedly arranged on the upper end of the connecting spring 55, a bilaterally symmetrical connecting chamber 30 is arranged in the left and right end walls of the movable chamber 16 in a communicating manner, a sealing block 26 is arranged in the connecting chamber 30 in a sliding manner, one end of the sealing block 26, which is close to the center line of the movable chamber 16, extends to prevent the pushing block 33 from moving, a connecting groove 28 with a downward opening is formed in the lower end face of the sealing block 26, a hinge rod 27 is hinged in the connecting groove 28, a return spring 29 is fixedly arranged between the right end face of the sealing block 26 and the end face of the connecting cavity 30 far away from the side of the central line of the moving cavity 16, a moving block 31 slidably mounted in the sliding cavity 32 is hinged at the lower end of the hinge rod 27, a filter block 10 is fixedly arranged on the lower end face of the moving shell 19, an open groove 11 with a downward opening is formed in the filter block 10, a rotatable rotating wheel 12 is arranged in the open groove 11, annular opening cavities 42 which are symmetrical in the front and back and are opened towards the side of the central line of the moving cavity 16 are formed in the front and back end faces of the moving shell 19, sealing glass 41 is fixedly arranged at the opening of the annular opening cavity 42, the sealing glass 41 seals the opening of the annular opening cavity 42 facing outwards, a network transmitter 67 is fixedly arranged in the end face of one side of the camera identifier 44, which is far away from the center line of the movable cavity 16, a rotating block 43 is fixedly arranged in the end face of one side of the network transmitter 67, which is far away from the center line of the movable cavity 16, water inlet pipes 23 which are bilaterally symmetrical are fixedly arranged in the left and right end walls of the water pressure cavity 24, one ends of the water inlet pipes 23, which are far away from the center line of the movable cavity 16, are fixedly provided with water inlet pipes 18, the lower ends of the water inlet pipes 18 are opened towards one side of the center line of the movable cavity 16, the left and right end walls of the water inlet pipes 18 are communicated with extension cavities 21, the openings of the extension cavities 21 are opened towards one side of the center line of the movable cavity 16, water pressure blocks 20 are slidably arranged at the openings of the extension cavities 21, the water pressure blocks 20 seal the outward openings of the extension cavities 21, and fixed springs 22 are fixedly arranged.

Beneficially, be equipped with above the open slot 11 and be located the rotation chamber 13 in the removal casing 19, swiveling wheel 12 upper end fixed mounting is on initiative threaded shaft 15, initiative threaded shaft 15 rotates to be installed in open slot 11 with rotate the chamber 13 with remove between the chamber 16, be equipped with fixed mounting in rotating chamber 13 and be equipped with turning gear 14 on initiative threaded shaft 15, the lateral symmetry is equipped with connecting gear 40 around turning gear 14, connecting gear 40 with turning gear 14 meshing is connected, connecting gear 40 fixed mounting is on connecting axle 39, be equipped with pulley chamber 34 above turning gear 14, connecting axle 39 rotates to be installed between turning gear 14 and pulley chamber 34, be equipped with the rotatory belt pulley 38 of fixed mounting on connecting axle 39 in the pulley chamber 34, rotatory belt pulley 38 left side is equipped with rotates belt pulley 35, the rotating belt pulley 35 is connected with the rotating belt pulley 38 through a connecting belt 37, the rotating belt pulley 35 is fixedly installed on a driven shaft 36, the driven shaft 36 is rotatably installed between the belt pulley cavity 34 and the annular opening cavity 42, a rotating gear 45 fixedly installed on the driven shaft 36 is arranged in the annular opening cavity 42, and the rotating gear 45 is far away from one side of the central line of the moving cavity 16 and is meshed with the camera shooting recognizer 44.

Beneficially, a thread groove 68 with a downward opening is formed in the lower end face of the moving thread block 17, the upper end of the driving thread shaft 15 extends into the thread groove 68 and is in threaded connection with the same, a rotation cavity 52 which is communicated with the moving cavity 16 and is symmetrical left and right is formed between the pushing block 33 and the moving thread block 17, a rotation shaft 53 is rotatably installed on the front end wall and the rear end wall of the rotation cavity 52, a connecting gear 71 is fixedly installed on the rotation shaft 53, a rotation block 54 fixedly installed on the rotation shaft 53 is arranged on the front side of the connecting gear 71, one end of the rotation block 54 close to the center line of the moving cavity 16 extends into the moving cavity 16, and one side of the connecting gear 71 far away from the center line of the moving cavity 16 is in meshed connection with one side of the moving block 31 close to the center.

Beneficially, the front end wall and the rear end wall of the moving cavity 16 are communicated with each other to form a connecting cavity 61 which is symmetrical in the front and rear directions, a clamping block 59 is slidably installed in the connecting cavity 61, one end of the clamping block 59, which is close to the center line of the moving cavity 16, can extend into the moving cavity 16 to prevent the pushing block 33 from moving downwards, a rack cavity 58 is communicated below the connecting cavity 61, a connecting cavity 61 with a downward opening is formed in the lower end face of the clamping block 59, a connecting rod 57 is hinged in the connecting cavity 61, a connecting spring 62 is fixedly arranged between the right end face of the clamping block 59 and the end face of the connecting cavity 61, which is far away from the center line of the moving cavity 16, a moving rack 56 which is slidably installed in the rack cavity 58 is hinged at the lower end of the connecting rod 57, a transmission cavity 65 which is symmetrical in the front and rear directions and is communicated with the moving cavity, a transmission gear 64 is fixedly arranged on the limiting shaft 63, a limiting plate 66 fixedly arranged on the limiting shaft 63 is arranged on the right side of the transmission gear 64, one end, close to the central line of the moving cavity 16, of the limiting plate 66 can extend into the moving cavity 16, and one side, far away from the central line of the moving cavity 16, of the transmission gear 64 is meshed and connected with one side, close to the central line of the moving cavity 16, of the moving rack 56.

Advantageously, a buoyancy block 47 is arranged above the movable shell 19, a pulley cavity 48 with a downward opening is arranged in the lower end face of the buoyancy block 47, a pulley shaft 50 is rotatably mounted on the left and right end walls of the pulley cavity 48, a pulley 49 is fixedly arranged on the pulley shaft 50, a connecting rope 51 is wound on the pulley 49, four fixed ropes 46 are fixedly arranged at the lower ends of the connecting ropes 51, and the lower ends of the fixed ropes 46 are fixedly arranged on the upper end face of the movable shell 19 in a circumferential array.

Advantageously, a closing plate 69 is fixedly arranged at the upward opening of the hydraulic pressure cavity 24, and a one-way check valve 70 is fixedly arranged in the closing plate 69.

In the initial state, the engaging spring 62 is in a compressed state; the hydraulic pressure cavity 24 is filled with water; the buoyancy block 47 floats on the sea surface.

The movable housing 19 sinks into the sea bottom under the influence of gravity, the rotating wheel 12 is driven to rotate by the downward moving force and the action of seawater when the movable housing 19 moves downward, the rotating wheel 12 rotates to drive the driving threaded shaft 15 to rotate, the driving threaded shaft 15 rotates to drive the rotating gear 14 to rotate and drive the movable threaded block 17 to move upward, the rotating gear 14 rotates to drive the connecting gear 40 to rotate, the connecting gear 40 rotates to drive the connecting shaft 39 to rotate, the connecting shaft 39 rotates to drive the rotating belt pulley 38 to rotate, the rotating belt pulley 38 rotates to drive the rotating belt pulley 35 to rotate through the connecting belt 37, the rotating belt pulley 35 rotates to drive the driven shaft 36 to rotate, the driven shaft 36 rotates to drive the rotating gear 45 to rotate, the rotating gear 45 rotates to drive the camera identifier 44 to rotate, the camera identifier 44 rotates to drive the rotating block 43 to rotate, the rotating block 43 rotates to enable the ecological information of ocean energy to be identified and recorded by three hundred sixty degrees, then the recorded and identified information is transmitted into the thread groove 68, and the thread groove 68 is fed back into the control equipment above through a network for analysis and storage by operators.

Meanwhile, the moving screw block 17 moves upwards to drive the pushing block 33 to move upwards through the connecting spring 55, the pushing block 33 is blocked by the sealing block 26 so as not to move upwards, therefore, the moving screw block 17 moves upwards to compress the connecting spring 55, when the device moves to a certain depth and reaches the limit of the depth bearing capacity of the device, the moving screw block 17 moves upwards to just below the rotating block 54, then the rotating block 54 is driven to rotate, the rotating shaft 53 is driven to rotate, the engaging gear 71 is driven to rotate so as to drive the moving block 31 to move upwards, the moving block 31 moves upwards through the hinged rod 27 so as to drive the sealing block 26 to move to one side far away from the central line of the moving cavity 16 and compress the return spring 29, the sealing block 26 moves to one side far away from the central line of the moving cavity 16 so as to leave from the moving cavity 16 and not block the pushing block, so that the pushing block 33 moves upwards under the driving of the resilience of the connecting spring 55, the pushing block 33 moves upwards for a second time to push the sliding plate 25 to move upwards, the sliding plate 25 moves upwards to pass through the one-way valve 70 to push the water in the water pressure chamber 24 out of the device, and vacuum is formed in the water pressure chamber 24, and the water pressure is gradually increased when the movable shell 19 moves downwards, and the water pressure drives the water pressure block 20 to move towards one side close to the central line of the movable chamber 16 to close the communication position of the water inlet pipeline 18 and compress the fixed spring 22.

Meanwhile, the fixture block 59 is driven by the resilience force of the engaging spring 62 to move towards one side close to the center line of the moving cavity 16, the fixture block 59 moves towards one side close to the center line of the moving cavity 16 and drives the moving rack 56 to move downwards through the connecting rod 57, the moving rack 56 moves downwards and drives the transmission gear 64 to rotate, the transmission gear 64 rotates and drives the limiting shaft 63 to rotate, the limiting shaft 63 rotates and drives the limiting plate 66 to rotate, the limiting plate 66 rotates, so that one end, close to the center line of the moving cavity 16, of the limiting plate 66 rotates into the moving cavity 16, and the fixture block 59 moves towards one side close to the center line of the moving cavity 16 and simultaneously blocks the pushing.

After vacuum is formed in the water pressure cavity 24, gravity of the movable shell 19 is reduced, the movable shell 19 moves upwards under the buoyancy of the vacuum in the water pressure cavity 24, the movable shell 19 moves upwards to drive the rotating wheel 12 to rotate reversely, the rotating wheel 12 rotates reversely to drive the driving threaded shaft 15 to rotate reversely, the driving threaded shaft 15 rotates reversely to drive the movable threaded block 17 to move downwards, the movable threaded block 17 moves downwards to drive the pushing block 33 to move downwards through the connecting spring 55, the pushing block 33 is blocked by the clamping block 59 so as not to move downwards, the movable threaded block 17 moves downwards to move the wire drawing connecting spring 55, when the device floats to a certain shallow degree, the water pressure is gradually reduced when the movable shell 19 moves upwards, the fixed spring 22 drives the water pressure block 20 to move towards one side gradually far away from the central line of the movable cavity 16, and when the water pressure block 20 moves away from the water inlet pipeline 18, the inlet pipe 18 is communicated with the inlet pipe 23 so that the water in the sea flows into the inlet pipe 18 by water pressure and flows into the hydraulic pressure chamber 24 by the inlet pipe 23, thereby the hydraulic pressure chamber 24 is filled with the sea water, then the movable housing 19 sinks again to perform reciprocating ecological information recognition and recording on the organisms in the fixed-point ocean, and then the network transmitter 67 is transmitted to the receiving device on the land through the network.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims

1. A network-based ecological information identification device comprises a mobile shell, and is characterized in that: a hydraulic pressure cavity with an upward opening is arranged in the movable shell, a sliding plate is arranged in the hydraulic pressure cavity in a sliding mode, a movable cavity is communicated and arranged in the lower end wall of the hydraulic pressure cavity, a movable threaded block is arranged in the movable cavity in a sliding mode, a connecting spring is fixedly arranged on the upper end face of the movable threaded block, and a pushing block which is arranged in the movable cavity in a sliding mode is fixedly arranged at the upper end of the connecting spring;

2. The network-based ecological information recognition apparatus according to claim 1, wherein: a rotating cavity positioned in the moving shell is arranged above the open slot, the upper end of the rotating wheel is fixedly arranged on a driving threaded shaft, the driving threaded shaft is rotatably arranged between the open slot and the rotating cavity, a rotating gear fixedly arranged on the driving threaded shaft is arranged in the rotating cavity, connecting gears are symmetrically arranged on the front side and the rear side of the rotating gear, the connecting gears are meshed with the rotating gear, the connecting gears are fixedly arranged on a connecting shaft, a belt pulley cavity is arranged above the rotating gear, the connecting shaft is rotatably arranged between the rotating gear and the belt pulley cavity, a rotating belt pulley fixedly arranged on the connecting shaft is arranged in the belt pulley cavity, a rotating belt pulley is arranged on the left side of the rotating belt pulley, and the rotating belt pulley is connected with the rotating belt pulley through a connecting belt, the rotary belt pulley is fixedly installed on a driven shaft, the driven shaft is installed between the belt pulley cavity and the annular opening cavity in a rotating mode, a rotary gear fixedly installed on the driven shaft is arranged in the annular opening cavity, and one side, far away from the center line of the moving cavity, of the rotary gear is connected with the camera shooting recognizer in a meshing mode.

3. The network-based ecological information recognition apparatus according to claim 1, wherein: the movable threaded block is characterized in that a threaded groove with a downward opening is formed in the lower end face of the movable threaded block, the upper end of the driving threaded shaft extends into the threaded groove and is in threaded connection with the threaded groove, a rotating cavity which is communicated with the movable cavity and is bilaterally symmetrical is formed between the pushing block and the movable threaded block, a rotating shaft is rotatably installed on the front end wall and the rear end wall of the rotating cavity, a connecting gear is fixedly arranged on the rotating shaft, a rotating block fixedly installed on the rotating shaft is arranged on the front side of the connecting gear, one end, close to the center line of the movable cavity, of the rotating block extends into the movable cavity, and one side, far away from the center line of the movable cavity, of the.

4. The network-based ecological information recognition apparatus according to claim 1, wherein: the front end wall and the rear end wall of the moving cavity are internally communicated with linking cavities which are symmetrical front and back, a clamping block is arranged in the linking cavities in a sliding installation manner, one end of the clamping block close to the center line of the moving cavity can extend into the moving cavity to block the pushing block from moving downwards, a rack cavity is arranged below the linking cavities in a communicating manner, a linking cavity with a downward opening is arranged in the lower end face of the clamping block, a linking spring is fixedly arranged between the right end face of the clamping block and the end face of the linking cavity far away from the center line of the moving cavity, a moving rack which is slidably arranged in the rack cavity is hinged at the lower end of the connecting rod, a transmission cavity which is communicated with the moving cavity and symmetrical front and back is arranged below the rotating cavity, a limiting shaft is arranged on the left end wall and the right end wall of the transmission cavity in a rotating manner, one end, close to the center line of the moving cavity, of the limiting plate can extend into the moving cavity, and one side, far away from the center line of the moving cavity, of the transmission gear is meshed and connected with one side, close to the center line of the moving cavity, of the moving rack.

5. The network-based ecological information recognition apparatus according to claim 1, wherein: the movable rope wheel is characterized in that a buoyancy block is arranged above the movable shell, a rope wheel cavity with a downward opening is formed in the lower end face of the buoyancy block, a rope wheel shaft is arranged in the left end wall and the right end wall of the rope wheel cavity in a rotating mode, a rope wheel is fixedly arranged on the rope wheel shaft, a connecting rope is wound on the rope wheel, four fixing ropes are fixedly arranged at the lower end of the connecting rope, and the lower end of each fixing rope is fixedly arranged on the upper end face of the movable shell in a circumferential.

6. The network-based ecological information recognition apparatus according to claim 1, wherein: and a sealing plate is fixedly arranged at the upward opening of the water pressure cavity, and a one-way check valve is fixedly arranged in the sealing plate.