CN113376343A - Internet of things environment detection system based on ocean engineering - Google Patents

Abstract

The invention provides an Internet of things environment detection system based on ocean engineering, and relates to the field of ocean environment detection. This thing networking environment detecting system, including first equipment box, the first double-end motor of center department fixedly connected with of first equipment box bottom inner wall, the equal fixedly connected with first rotation pole of drive end of first double-end motor both sides. Realize the removal of control overall unit through the start-up of first double-end motor of treater control and second double-end motor, the transfer of the overall unit of being convenient for, enlarge detection range, monitor the rainwater through the PH sensor, and realize the closure of two waterproof cases under the effect of treater, the realization is to the protection of overall unit, and service life is prolonged, through pressure sensor to the accurate sample quality of accuse, and under water quality detector's effect, realize the detection to the ration sea water, improve the accuracy nature that detects, be worth wideling popularize.

Description

Internet of things environment detection system based on ocean engineering

Technical Field

The invention relates to the technical field of marine environment detection, in particular to an Internet of things environment detection system based on marine engineering.

Background

The vast ocean is an important component of a global ecosphere by using a water body accounting for 98 percent of the land, the storage amount of ocean resources is immeasurable, China is the coastal country with the largest population in the world, ocean development is listed in a national development strategy, the development of the ocean resources is not separated from scientific and technological support, the ocean development is different from the land development, the special environment has great influence on the development, the ocean resource development depends on the guarantee of the ocean environment to a great extent, people must look at the ocean environment of a development area, and need to acquire the temperature, the salinity, the density and other parameters of an ocean environment field all the time, so that the establishment of an ocean environment field information system has very important significance.

In thing networking environment detecting system among ocean engineering at present stage, there is the relatively poor problem of detecting system device body mobility, leads to the detection range limitation great simultaneously, secondly, to the system device that detects on the sea for a long time, the long-term erosion of rainwater of sea easily influences its life, simultaneously, when examining marine environment, the majority can't realize quantitative determination, and is inaccurate to the contrast reference data between the different sea areas testing result.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention provides an Internet of things environment detection system based on ocean engineering, and solves the problems of poor mobility, large detection range limitation, short service life and inaccurate comparison of detection results with reference data.

(II) technical scheme

In order to achieve the purpose, the invention is realized by the following technical scheme: the utility model provides a thing networking environment detecting system based on among ocean engineering, includes first equipment box, the first double-end motor of fixedly connected with is located at the center of first equipment box bottom end inner wall, the equal first dwang of fixedly connected with of drive end of first double-end motor both sides, the equal first drive wheel of fixedly connected with of one end that first double-end motor was kept away from to first dwang, first double-end motor top end fixedly connected with second double-end motor, the equal fixedly connected with second dwang of drive end of the second double-end motor left and right sides, the equal fixedly connected with second drive wheel of one end that second double-end motor was kept away from to the second dwang, the equal fixedly connected with flotation pontoon in middle part of first equipment box external diameter a week, first equipment box top end fixedly connected with second equipment box.

Preferably, fixedly connected with servo motor is located at the center of second equipment box bottom inner wall, the first worm wheel of servo motor drive end fixedly connected with, first worm wheel rear end meshing is connected with first worm, the first bevel gear of the equal fixedly connected with in both ends about the first worm, the front side that servo motor one end was kept away from to first bevel gear all meshes and is connected with the second bevel gear, the equal fixedly connected with third dwang of the inside through-hole department of second bevel gear, equal fixedly connected with straight-tooth gear on the symmetrical external diameter in both sides around the third dwang, the straight-tooth gear top all meshes and is connected with the rack board, the rack board is fixed connection respectively on the extension board at both ends around waterproof case bottom, second equipment box top center fixedly connected with third equipment box.

Preferably, the center of the inner wall of the bottom end of the third device is fixedly connected with a water quality detector, the input end at the top of the water quality detector is fixedly connected with one end of the water inlet pipe, the other end of the water inlet pipe is fixedly connected with a water collecting tank, a water storage frame is arranged at the position of the top of the third equipment box corresponding to the water collecting tank, four corners of the inner wall of the bottom end of the water storage frame are fixedly connected with first springs, the top ends of the first springs are respectively and fixedly connected with four corners of the bottom end of the baffle plate, a second spring is fixedly connected at the center of the inner wall of the bottom end of the water collecting tank, the top end of the second spring is fixedly connected with a pressure sensor, the centers of the front and the rear ends of the water storage frame are fixedly connected with connecting rods, the middle part of the connecting rod at the rear end is fixedly connected with a second worm wheel, the right end of the second worm wheel is connected with a second worm in a meshed mode, and the bottom end of the second worm is fixedly connected to the driving end of the electric push rod.

Preferably, the intermediate position department fixedly connected with suction pump of second equipment box top front end, the suction pump rear side output runs through the third equipment box through the pipeline and falls into the corresponding position department in retaining frame top, second equipment box top rear end and the corresponding position department fixedly connected with water tank of suction pump, the fixedly connected with PH sensor of center department of water tank bottom inner wall, there is the funnel that catchments on the water tank top through the pipe connection, third equipment box top fixedly connected with photovoltaic electroplax, the rear end middle part fixedly connected with treater of third equipment box top inner wall, the position department fixedly connected with battery that third equipment box bottom inner wall is close to the water quality testing ware front end, the bottom middle part fixedly connected with signal receiver of third equipment box front side inner wall.

Preferably, first dwang and second dwang are located the equal fixedly connected with first bearing of external diameter department near first drive wheel and second drive wheel respectively, the top the equal fixed connection in first horizontal pole one end of front end of first bearing, the bottom the equal fixed connection in second horizontal pole one end of right-hand member of first bearing, the equal fixed connection of the other end of first horizontal pole and second horizontal pole is on the inner wall of first equipment box, first equipment box bottom end and the corresponding position of first drive wheel and second drive wheel go out and all be provided with the recess.

Preferably, equal fixedly connected with second bearing on the symmetrical external diameter of first worm left and right sides, the equal fixed connection in second bearing bottom is in pole setting one end, the equal fixed connection of the pole setting other end is on the inner wall of second equipment case, same level equal sliding connection has the dead lever in the through-hole of both sides around the rack board, the equal fixed connection in dead lever both ends is on the inner wall of second equipment case.

Preferably, the equal fixedly connected with baffle in both ends around the water catch bowl top, the equal fixed connection in baffle bottom is on the bottom inner wall of third equipment case, the equal fixedly connected with sheet rubber of baffle external diameter a week, the equal sliding connection of sheet rubber is on the inner wall of retaining frame, the one end that retaining frame was kept away from to the connecting rod is all rotated and is connected on the inner wall of third equipment case, electric putter fixed connection is on the rear end inner wall of third equipment case.

Preferably, the photovoltaic electroplax passes through the signal line and links to each other with the battery, the treater passes through the signal line and links to each other with signal receiver, the treater all passes through the signal line and links to each other with first double-end motor, second double-end motor, servo motor, water quality detector, pressure sensor, electric putter, suction pump and PH sensor.

The working principle is as follows: when raining in a detected ocean area, rainwater enters the water tank through the water collecting funnel, the PH values of seawater and rainwater are different, the PH value of seawater is 8.0-8.5, the PH value of fresh water is 6-7, so whether raining occurs or not is judged according to the PH value of water entering the water tank, if rainwater is detected, detection information is transmitted into the processor through the PH sensor, the processor activates the starting of the servo motor in the second equipment box, the servo motor drives the first worm gear to rotate, the first worm gear drives the first bevel gears at two ends to rotate, the first bevel gears drive the corresponding second bevel gears to rotate, the second bevel gears drive the third rotating rods inside the second equipment box to rotate, the third rotating rods drive the corresponding straight gears to rotate, the corresponding rack plates are driven by the straight gears to slide on the fixed rods, and under the action of the two second bevel gears, the relative movement of the two waterproof shells is realized, so that the purpose of closing the whole device is realized, the damage to the whole device caused by the erosion of rainwater or rainstorm is effectively prevented, the service life of the whole device is prolonged, when the seawater environment in a detected ocean area is detected, the processor activates the starting of the water suction pump, seawater is pumped into the third equipment box through the water suction pump, the seawater enters the water storage frame through a connecting pipeline between the water suction pump and the third equipment box, the baffle in the water storage frame moves downwards under the action of the continuous injection of the seawater, so that the four first springs deform and are in contact with the pressure sensor, when the pressure detected by the pressure sensor reaches a standard set value, a signal is transmitted into the processor, the processor controls the closing of the water suction pump and activates the starting of the electric push rod, the electric push rod drives the second worm to move upwards, so as to drive the second worm wheel to rotate, the second worm wheel drives the internal connecting rod to rotate, the connecting rod drives the water storage frame to rotate, the water storage frame is turned over under the action of the front end connecting rod, seawater in the water storage frame enters the water collecting tank and finally flows into the water quality detector under the action of the water inlet pipe, the water quality detector detects quantitative seawater and uploads a detection result to the server under the action of the internal signal transmitter of the water quality detector, so as to realize quantitative detection of the seawater in a specific area, after the detection of the seawater in the area is finished, a signal transmitted by the server is received through the signal receiver, the signal receiver transmits the signal into the processor, when the whole device needs to move transversely in the horizontal direction, the processor activates the starting of the first double-head motor, the first double-head motor drives the first rotating rod to rotate, the first rotating rod drives the corresponding first driving wheel to rotate, the first driving wheel can realize the transverse movement of the whole device in the horizontal direction under the effect of the first driving wheel on the seawater turnover, when the whole device needs to move longitudinally in the horizontal direction, the processor can activate the starting of the second double-head motor, the second double-head motor can drive the second rotating rod to rotate, the second rotating rod can drive the corresponding second driving wheel to rotate, the second driving wheel can realize the longitudinal movement of the whole device in the horizontal direction under the effect of the second driving wheel on the seawater turnover, so that the whole device can move conveniently, and the detection range is enlarged.

(III) advantageous effects

The invention provides an Internet of things environment detection system based on ocean engineering. The method has the following beneficial effects:

1. according to the invention, the PH sensor is used for monitoring rainwater, and the two waterproof shells are closed under the action of the processor, so that the whole device is protected, and the service life is prolonged.

2. The invention controls the start of the first double-head motor and the second double-head motor through the processor to realize the control of the movement of the whole device, thereby being convenient for the transfer of the whole device and expanding the detection range.

3. The invention controls the accurate sampling quality through the pressure sensor pair, realizes the detection of quantitative seawater under the action of the water quality detector, and improves the accuracy of comparison data among detection results of different sea areas.

Drawings

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a perspective view of a third equipment cabinet according to the present invention;

FIG. 3 is a perspective view of the internal structure of a first equipment cabinet according to the present invention;

FIG. 4 is a perspective view showing the internal structure of a second equipment box according to the present invention;

FIG. 5 is a schematic view showing the internal structure of a third equipment box according to the present invention;

fig. 6 is a schematic view of the internal structure of the water tank of the present invention.

Wherein, 1, a first equipment box; 2. a first double-headed motor; 3. a first rotating lever; 4. a first drive wheel; 5. a second double-headed motor; 6. a second rotating lever; 7. a second drive wheel; 8. a float bowl; 9. a second equipment box; 10. a servo motor; 11. a first worm gear; 12. a first worm; 13. a first bevel gear; 14. a second bevel gear; 15. a third rotating rod; 16. a spur gear; 17. a rack plate; 18. a waterproof housing; 19. a third equipment box; 20. a water quality detector; 21. a water inlet pipe; 22. a water collection tank; 23. a water storage frame; 24. a first spring; 25. a baffle plate; 26. a second spring; 27. a pressure sensor; 28. a connecting rod; 29. a second worm gear; 30. a second worm; 31. an electric push rod; 32. a water pump; 33. a water tank; 34. a pH sensor; 35. a water collection funnel; 36. a photovoltaic panel; 37. a processor; 38. a storage battery; 39. a signal receiver; 40. a first bearing; 41. a first cross bar; 42. a second cross bar; 43. a second bearing; 44. erecting a rod; 45. fixing the rod; 46. a partition plate; 47. a rubber sheet.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example (b):

as shown in fig. 1-6, an embodiment of the present invention provides an internet of things environment detection system based on ocean engineering, which includes a first equipment box 1, a first double-head motor 2 is fixedly connected to the center of the inner wall of the bottom end of the first equipment box 1, first rotating rods 3 are fixedly connected to the driving ends of both sides of the first double-head motor 2, first driving wheels 4 are fixedly connected to the ends of the first rotating rods 3 far away from the first double-head motor 2, a second double-head motor 5 is fixedly connected to the top end of the first double-head motor 2, second rotating rods 6 are fixedly connected to the driving ends of both sides of the second double-head motor 5, second driving wheels 7 are fixedly connected to the ends of the second rotating rods 6 far away from the second double-head motor 5, a buoy 8 is fixedly connected to the middle of one circle of the outer diameter of the first equipment box 1, the buoy 8 ensures that the whole device normally floats on the sea surface, a second equipment box 9 is fixedly connected to the top end of the first equipment box 1, when the whole device needs to move transversely in the horizontal direction, the processor 37 activates the starting of the first double-head motor 2, the first double-head motor 2 drives the first rotating rod 3 to rotate, the first rotating rod 3 drives the corresponding first driving wheel 4 to rotate, the transverse movement of the whole device in the horizontal direction is realized under the action of the first driving wheel 4 on seawater overturning, when the whole device needs to move longitudinally in the horizontal direction, the processor 37 activates the starting of the second double-head motor 5, the second double-head motor 5 drives the second rotating rod 6 to rotate, the second rotating rod 6 drives the corresponding second driving wheel 7 to rotate, the longitudinal movement of the whole device in the horizontal direction is realized under the action of the second driving wheel 7 on seawater overturning, the movement of the whole device is facilitated, and the detection range of the whole device is expanded.

The center department fixedly connected with servo motor 10 of second equipment box 9 bottom inner wall, servo motor 10 drive end fixedly connected with first worm wheel 11, the meshing of first worm wheel 11 rear end is connected with first worm 12, the equal first bevel gear 13 of fixedly connected with in both ends about first worm 12, the equal meshing of the front side that servo motor 10 one end was kept away from to first bevel gear 13 is connected with second bevel gear 14, the equal fixedly connected with third dwang 15 of the inside through-hole department of second bevel gear 14, equal fixedly connected with straight-tooth gear 16 on the symmetrical external diameter in both sides around the third dwang 15, the equal meshing in straight-tooth gear 16 top is connected with rack plate 17, rack plate 17 is fixed connection respectively on the extension board at both ends around waterproof housing 18 bottom, 9 top center department fixedly connected with third equipment box 19 in second equipment box.

The center of the inner wall of the bottom end of the third equipment box 19 is fixedly connected with a water quality detector 20, the input end of the top of the water quality detector 20 is fixedly connected with one end of a water inlet pipe 21, the other end of the water inlet pipe 21 is fixedly connected with a water collecting tank 22, the position of the top of the third equipment box 19 corresponding to the water collecting tank 22 is provided with a water storage frame 23, four corners of the inner wall of the bottom end of the water storage frame 23 are fixedly connected with first springs 24, the top ends of the first springs 24 are respectively and fixedly connected with four corners of the bottom end of a baffle plate 25, the center of the inner wall of the bottom end of the water collecting tank 22 is fixedly connected with a second spring 26, the top ends of the second springs 26 are fixedly connected with a pressure sensor 27, the centers of the front end and the rear end of the water storage frame 23 are respectively and fixedly connected with a, when the detected sea water environment in the sea area is detected, the processor 37 activates the water pump 32 to pump the sea water into the third equipment box 19 through the water pump 32, the sea water enters the water storage frame 23 through the connecting pipeline between the water pump 32 and the third equipment box 19, the baffle 25 in the water storage frame 23 moves downwards under the action of continuous injection of the sea water, so that the four first springs 24 deform, the baffle 25 is in contact with the pressure sensor 27, when the pressure detected by the pressure sensor 27 reaches a standard set value, a signal is transmitted to the processor 37, the processor 37 controls the water pump 32 to be closed, the electric push rod 31 is activated, the electric push rod 31 drives the second worm 30 to move upwards, so that the second worm wheel 29 is driven to rotate, the second worm wheel 29 drives the internal connecting rod 28 to rotate, and the connecting rod 28 drives the water storage frame 23 to rotate, the water storage frame 23 is turned over under the action of the front end connecting rod 28, seawater in the water storage frame 23 enters the water collection tank 22 and finally flows into the water quality detector 20 under the action of the water inlet pipe 21, the water quality detector 20 detects quantitative seawater, and a detection result is uploaded to the server under the action of an internal signal emitter of the water quality detector 20, so that quantitative detection of the seawater in a specific area is realized.

A water suction pump 32 is fixedly connected to the middle position of the front end of the top of the second equipment box 9, the rear output end of the water suction pump 32 penetrates through the third equipment box 19 through a pipeline and extends to the position corresponding to the top end of the water storage frame 23, a water tank 33 is fixedly connected to the position corresponding to the water suction pump 32 at the rear end of the top of the second equipment box 9, a pH sensor 34 is fixedly connected to the center of the inner wall of the bottom end of the water tank 33, a water collection funnel 35 is connected to the top end of the water tank 33 through a pipeline, a photovoltaic panel 36 is fixedly connected to the top end of the third equipment box 19, a processor 37 is fixedly connected to the middle part of the rear end of the inner wall of the top of the third equipment box 19, a storage battery 38 is fixedly connected to the position of the inner wall of the bottom end of the third equipment box 19, which is close to the front end of the water quality detector 20, a signal receiver 39 is fixedly connected to the middle part of the bottom end of the inner wall of the front side of the third equipment box 19, when raining in the detected ocean area, rainwater enters the water tank 33 through the water collection funnel 35, because the pH values of seawater and rainwater are different, the pH value of seawater is 8.0-8.5, and the pH value of fresh water is 6-7, whether it rains or not is judged according to the pH value of water entering the water tank 33, if it is detected that rainwater is present, the detected information is transmitted to the processor 37 through the pH sensor 34, the processor 37 activates the start of the servo motor 10 in the second equipment tank 9, the servo motor 10 drives the first worm wheel 11 to rotate, the first worm wheel 11 drives the first worm 12 to rotate, the first worm 12 drives the first bevel gears 13 at two ends to rotate, the first bevel gears 13 drive the corresponding second bevel gears 14 to rotate, the second bevel gears 14 drive the third rotating rods 15 inside to rotate, the third rotating rods 15 drive the corresponding straight gears 16 to rotate, the rack plates 17 driven by the straight gears 16 slide on the fixing rods 45, and under the action of the two second bevel gears 14, the relative movement of the two waterproof housings 18 is realized, so that the aim of closing the whole device is fulfilled, the damage to the whole device caused by the erosion of rainwater or rainstorm is effectively prevented, and the service life of the whole device is prolonged.

The first rotating rod 3 and the second rotating rod 6 are respectively positioned at the outer diameters close to the first driving wheel 4 and the second driving wheel 7 and are fixedly connected with a first bearing 40, the front end of the first bearing 40 at the top end is fixedly connected at one end of a first cross rod 41, the right end of the first bearing 40 at the bottom end is fixedly connected at one end of a second cross rod 42, the other ends of the first cross rod 41 and the second cross rod 42 are fixedly connected on the inner wall of the first equipment box 1, the first bearing 40 plays a role in supporting and fixing the first rotating rod 3 and the second rotating rod 6, the normal rotation of the first rotating rod 3 and the second rotating rod 6 is ensured, the first cross rod 41 and the second cross rod 42 play a role in supporting and fixing the first bearing 40 corresponding to the fixed phase, the positions of the bottom end of the first equipment box 1 corresponding to the first driving wheel 4 and the second driving wheel 7 are respectively provided with a groove, the first rotating rod 3 and the second rotating rod 6 respectively penetrate through the grooves, and the first driving wheel 4 and the second driving wheel 7 are respectively arranged on the corresponding first rotating rod 3 and the second rotating rod 6 in the groove, so that the situation that water enters the bottom of the first equipment box 1 is avoided.

Equal fixedly connected with second bearing 43 on the symmetrical external diameter of first worm 12 left and right sides, the equal fixed connection in second bearing 43 bottom is in pole setting 44 one end, the equal fixed connection of the pole setting 44 other end is on the inner wall of second equipment case 9, second bearing 43 plays the effect of supporting and fixed first worm 12, the normal rotation of first worm 12 has been guaranteed simultaneously, pole setting 44 plays the effect of supporting and fixed second bearing 43, equal sliding connection has dead lever 45 in the through-hole of same horizontal rack board 17 front and back both sides, the equal fixed connection in dead lever 45 both ends is on the inner wall of second equipment case 9, dead lever 45 has strengthened rack board 17's stability, rack board 17 has been guaranteed simultaneously along with straight-teeth gear 16's normal removal.

Equal fixedly connected with baffle 46 in both ends around the water catch bowl 22 top, the equal fixed connection in baffle 46 bottom is on the bottom inner wall of third equipment case 19, baffle 46 plays the effect of supporting with fixed water catch bowl 22, the equal fixedly connected with sheet rubber 47 of baffle 25 external diameter a week, the equal sliding connection of sheet rubber 47 is on the inner wall of retaining frame 23, sheet rubber 47 plays the effect that prevents the sea water entering baffle 25 bottom, the one end that retaining frame 23 was kept away from to connecting rod 28 all rotates and connects on the inner wall of third equipment case 19, electric putter 31 fixed connection is on the rear end inner wall of third equipment case 19.

The photovoltaic panel 36 is connected with the storage battery 38 through a signal line, the processor 37 is connected with the signal receiver 39 through a signal line, the photovoltaic panel 36 converts light energy into electric energy and charges the storage battery 38, the storage battery 38 supplies power for a structure of electric energy required in the system, the energy-saving and environment-friendly effects are achieved, and the processor 37 is connected with the first double-head motor 2, the second double-head motor 5, the servo motor 10, the water quality detector 20, the pressure sensor 27, the electric push rod 31, the water suction pump 32 and the PH sensor 34 through signal lines.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The utility model provides a thing networking environment detecting system based on among ocean engineering, includes first equipment box (1), its characterized in that: a first double-head motor (2) is fixedly connected at the center of the inner wall of the bottom end of the first equipment box (1), the driving ends at both sides of the first double-head motor (2) are fixedly connected with a first rotating rod (3), one end of the first rotating rod (3) far away from the first double-head motor (2) is fixedly connected with a first driving wheel (4), the top end of the first double-head motor (2) is fixedly connected with a second double-head motor (5), the driving ends of the left side and the right side of the second double-head motor (5) are fixedly connected with a second rotating rod (6), one end of the second rotating rod (6) far away from the second double-head motor (5) is fixedly connected with a second driving wheel (7), the middle part of one circle of the outer diameter of the first equipment box (1) is fixedly connected with a buoy (8), the top end of the first equipment box (1) is fixedly connected with a second equipment box (9).

2. The Internet of things environment detection system based on ocean engineering according to claim 1, wherein: the center of the inner wall of the bottom end of the second equipment box (9) is fixedly connected with a servo motor (10), a driving end of the servo motor (10) is fixedly connected with a first worm wheel (11), the rear end of the first worm wheel (11) is meshed with a first worm (12), the left end and the right end of the first worm (12) are fixedly connected with a first bevel gear (13), the front side of one end, far away from the servo motor (10), of the first bevel gear (13) is meshed with a second bevel gear (14), the inner through hole of the second bevel gear (14) is fixedly connected with a third rotating rod (15), the symmetrical outer diameters of the front side and the rear side of the third rotating rod (15) are fixedly connected with straight gears (16), the top ends of the straight gears (16) are meshed with rack plates (17), and the rack plates (17) are respectively fixedly connected to extension plates at the front end and the rear end of the bottom of a waterproof shell (18), and a third equipment box (19) is fixedly connected to the center of the top end of the second equipment box (9).

3. The Internet of things environment detection system based on ocean engineering according to claim 2, wherein: the water quality monitoring device is characterized in that a water quality detector (20) is fixedly connected to the center of the inner wall of the bottom end of the third equipment box (19), the top input end of the water quality detector (20) is fixedly connected to one end of the water inlet pipe (21), the other end of the water inlet pipe (21) is fixedly connected with a water collecting tank (22), a water storage frame (23) is arranged at the position, corresponding to the water collecting tank (22), of the top of the third equipment box (19), first springs (24) are fixedly connected to four corners of the inner wall of the bottom end of the water storage frame (23), the top ends of the first springs (24) are respectively fixedly connected to four corners of the bottom end of a baffle plate (25), a second spring (26) is fixedly connected to the center of the inner wall of the bottom end of the water collecting tank (22), a pressure sensor (27) is fixedly connected to the top end of the second spring (26), and connecting rods (28) are fixedly connected to the centers of the front end and the rear end of the water storage frame (23), the middle part of the rear end connecting rod (28) is fixedly connected with a second worm wheel (29), the right end of the second worm wheel (29) is connected with a second worm (30) in a meshed mode, and the bottom end of the second worm (30) is fixedly connected to the driving end of an electric push rod (31).

4. The Internet of things environment detection system based on ocean engineering according to claim 3, wherein: the water storage device is characterized in that a water suction pump (32) is fixedly connected to the middle position of the front end of the top of the second device box (9), the output end of the rear side of the water suction pump (32) penetrates through a third device box (19) through a pipeline and extends to the position corresponding to the top end of a water storage frame (23), a water tank (33) is fixedly connected to the position corresponding to the water suction pump (32) at the rear end of the top of the second device box (9), a PH sensor (34) is fixedly connected to the center of the inner wall of the bottom end of the water tank (33), a water collection funnel (35) is connected to the top end of the water tank (33) through a pipeline, a photovoltaic panel (36) is fixedly connected to the top end of the third device box (19), a processor (37) is fixedly connected to the middle part of the rear end of the inner wall of the top of the third device box (19), a storage battery (38) is fixedly connected to the position, close to the front end of a water quality detector (20), of the inner wall of the bottom end of the third device box (19), and the middle part of the bottom end of the inner wall of the front side of the third equipment box (19) is fixedly connected with a signal receiver (39).

5. The Internet of things environment detection system based on ocean engineering according to claim 1, wherein: first dwang (3) and second dwang (6) are located respectively and are close to the equal fixedly connected with first bearing (40) of external diameter department of first drive wheel (4) and second drive wheel (7), the top the equal fixed connection in first horizontal pole (41) one end of front end of first bearing (40), the bottom the equal fixed connection in second horizontal pole (42) one end of right-hand member of first bearing (40), the equal fixed connection of the other end of first horizontal pole (41) and second horizontal pole (42) is on the inner wall of first equipment box (1), first equipment box (1) bottom and first drive wheel (4) and the corresponding position of second drive wheel (7) go out and all be provided with the recess.

6. The Internet of things environment detection system based on ocean engineering according to claim 2, wherein: equal fixedly connected with second bearing (43) on the symmetrical external diameter of first worm (12) left and right sides, the equal fixed connection in pole setting (44) one end in second bearing (43) bottom, the equal fixed connection in pole setting (44) other end is on the inner wall of second equipment box (9), same level equal sliding connection has dead lever (45) in the through-hole of both sides around rack plate (17), the equal fixed connection in dead lever (45) both ends is on the inner wall of second equipment box (9).

7. The Internet of things environment detection system based on ocean engineering according to claim 3, wherein: equal fixedly connected with baffle (46) in both ends around water catch bowl (22) top, equal fixed connection in baffle (46) bottom is on the bottom inner wall of third equipment case (19), equal fixedly connected with sheet rubber (47) of baffle (25) external diameter a week, equal sliding connection of sheet rubber (47) is on the inner wall of retaining frame (23), the one end that retaining frame (23) were kept away from in connecting rod (28) all rotates and connects on the inner wall of third equipment case (19), electric putter (31) fixed connection is on the rear end inner wall of third equipment case (19).

8. The Internet of things environment detection system based on ocean engineering according to claim 4, wherein: photovoltaic electroplax (36) link to each other with battery (38) through the signal line, treater (37) link to each other with signal receiver (39) through the signal line, treater (37) all link to each other with first double-end motor (2), second double-end motor (5), servo motor (10), water quality detector (20), pressure sensor (27), electric putter (31), suction pump (32) and PH sensor (34) through the signal line.

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