AU2020103206A4 - Ocean environment monitoring device for ocean engineering - Google Patents

Abstract

OF THE DISCLOSURE The utility model relates to the technical field of ocean monitoring devices, and specifically to an ocean environment monitoring device for ocean engineering, comprising a floating plate. The floating plate is fixedly installed with a detecting box; the detecting box is internally provided with a sampling and detecting mechanism; a transmission rod is fixed on the top of the detecting box; and a fan wheel is fixedly installed on the top of the transmission rod. The ocean environment monitoring device for ocean engineering can perform automatic sampling and detection on the ocean environment on the ocean surface, and features simple and convenient operation and relatively high sampling efficiency. 1/4 DRAWINGS 43 FIG1 F4 FIG2

Description

1/4

DRAWINGS

43

FIG1

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FIG2

OCEAN ENVIRONMENT MONITORING DEVICE FOR OCEAN ENGINEERING BACKGROUND OF THE INVENTION

[0001] 1. Technical Field

[0002] The utility model relates to the technical field of ocean monitoring devices, specifically to an ocean environment monitoring device for ocean engineering.

[0003] 2. Description of Related Art

[0004] Earth is a unique blue planet, and deep ocean areas with a depth of over 1000 m account for 90% of the total ocean area. Since effective scientific technologies and high construction and maintenance cost are required to construct and maintain a deep ocean observation station, there is a lack of real-time observation data of deep ocean in the world for a long time, which limits the development and utilization of gasoline, gas hydrate and gene resources deep in the ocean, and affects prediction on global weather, earthquakes, tsunamis and other disasters. Besides, acute climatic changes in recent years are joint consequences of the atmosphere and ocean, so that ocean environment monitoring has a great significance for development of coastal economy, ocean science research, reduction of ocean environment disasters and improvement on the capacities for ocean defense. It is extremely difficult to carry out all-weather, all-day and continuous fixed-point monitoring in a harsh ocean environment by manpower to obtain various accurate and reliable parameters of the ocean environment, and usually a great amount of human resources and material resources are needed. Ocean environment monitoring devices currently available on the market are relatively cumbersome, need to be hoisted during replacement and recycling, and are complicated in use. Therefore, an ocean environment monitoring device becomes an urgent need to meet people's demands.

BRIEF SUMMARY OF THE INVENTION

[0005] The objective of the utility model is to provide an ocean environment monitoring device for ocean engineering to solve the problem proposed in the background technology.

[0006] To achieve the above objective, the utility model provides the following technical solution:

[0007] An ocean environment monitoring device for ocean engineering includes a floating plate; the floating plate is fixedly installed with a detecting box; the detecting box is internally provided with a sampling and detecting mechanism; a transmission rod is fixed on the top of the detecting box; and a fan wheel is fixedly installed on the top of the transmission rod.

[0008] As a further solution of the utility model, the transmission rod penetrates through the detection box and is connected with a power generating device.

[0009] Another objective of this embodiment of the utility model is as follows: The sampling and detecting mechanism includes a support pole fixed on the floating plate and a bracket; a rotary rod penetrates through and is installed on the top of the support pole; a rotary plate is fixedly installed at one end of the rotary rod; a connecting plate is fixedly installed on an outer side of the rotary plate; a first rotary pin is provided at the end portion of one end of the connecting plate; the first rotary pin is rotationally equipped with a first connecting rod; a second rotary pin is provided at the other end of thefirst connecting rod; the second rotary pin penetrates through the bracket and is connected with a first rocker arm; a third rotary pin is provided at the other end of the first rocker arm; a second connecting rod is provided at the other end of the third rotary pin; a fourth rotary pin is provided at the other end of the second connecting rod; a second rocker arm is installed at the other end of the fourth rotary pin; a fifth rotary pin is provided at an end portion of the second rocker arm; the fifth rotary pin is rotationally installed on the bracket; a sleeve is fixedly installed at the middle part of the second connecting rod; the bottom of the sleeve is fixedly connected with a lifting rod, and a water collection mechanism is installed at the bottom of the lifting rod.

[0010] As a further solution of the utility model, the floating plate is formed with a sampling hole at a position corresponding to the water lifting rod.

[0011] As a further solution of the utility model, the rotary rod is fixed at a non-central position of the rotary plate.

[0012] Another objective of this embodiment of the utility model is as follows: The water collection mechanism includes a controller; a third connecting rod is fixed at the bottom of the controller; a motor is fixedly installed at an end portion of the third connecting rod; the motor is rotationally connected with a drive shaft; a first connecting block is fixed at the other end of the drive shaft; the first connecting block is internally penetrated by a first movable rod; a first rotary connecting block is provided at an end portion of the first movable rod; the other side of the first rotary connecting block is rotationally connected with a second movable rod; a second rotary connecting block is provided at an end portion of the second movable rod; the second rotary connecting block is equipped with a third movable rod; a second connecting block is provided at the middle part of the third movable rod; one side of the second connecting block is connected with a third connecting rod; a connecting disc is fixed at an end portion of the third connecting rod; and a sampling tank is fixed at the bottom of the connecting disc.

[0013] As a further solution of the utility model, the sampling tank is formed with a plurality of sampling openings in different directions.

[0014] Compared with the prior art, the utility model has the following beneficial effect:

[0015] The device can perform automatic sampling and detection on the ocean environment on the ocean surface and features simple and convenient operation and high sampling efficiency.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

[0016] FIG. 1 is a structural view of an ocean environment monitoring device for ocean engineering.

[0017] FIG. 2 is a top view of an ocean environment monitoring device for ocean engineering.

[0018] FIG. 3 is a front view of a sampling and detecting mechanism of an ocean environment monitoring device for ocean engineering.

[0019] FIG. 4 is a top view of a sampling and detecting mechanism of an ocean environment monitoring device for ocean engineering.

[0020] FIG. 5 is a structural view of a water collection mechanism of an ocean environment monitoring device for ocean engineering.

[0021] FIG. 6 is a left view of a water collection mechanism of an ocean environment monitoring device for ocean engineering.

[0022] FIG. 7 is a top view of a water collection mechanism of an ocean environment monitoring device for ocean engineering.

[0023] Description of reference signs: 1-floating plate; 2-detecting box; 3-transmission rod;

4-fan wheel; 5-sampling and detecting mechanism; 501-support pole; 502-rotary rod; 503 rotary plate; 504-connecting plate; 505-first rotary pin; 506-first connecting rod; 507 bracket; 508-second rotary pin; 509-first rocker arm; 510-third rotary pin; 511-second connecting rod; 512-fourth rotary pin; 513-second rocker arm; 514-sleeve; 515-lifting rod; 516-fifth rotary pin; 517-sampling hole; 6-water collection mechanism; 601-controller; 602-third connecting rod; 603-motor; 604- drive shaft; 605-first rotary connecting block; 606-first movable rod; 607-first connecting block; 608-second movable rod; 609-second rotary connecting block; 610-third movable rod; 611-second connecting block, 612-third connecting rod; 613-connecting disc; 614-sampling tank.

DETAILED DESCRIPTION OF THE INVENTION

[0024] The following are further detailed description of the technical solution of the present disclosure in conjunction with specific embodiments.

[0025] The following are detailed description of embodiments of the utility model. The reference signs of the embodiments are shown in the accompanying drawings, wherein always identical or similar reference signs represent identical or similar components or have identical or similar functional components. The following embodiments described with reference to the accompanying drawings are exemplary embodiments with reference to the accompanying drawings, which are merely used for interpreting the utility model and cannot be construed as limiting the utility model.

[0026] Embodiment 1

[0027] Refer to FIG. 1 to FIG. 7. In this embodiment of the utility model, an ocean environment monitoring device for ocean engineering includes a floating plate 1, wherein the floating plate 1 is fixedly installed with a detecting box 2; the detecting box 2 is internally provided with a sampling and detecting mechanism 5; a transmission rod 3 is fixed on the top of the detecting box 2; and a fan wheel 4 is fixedly installed on the top of the transmission rod 3.

[0028] In this embodiment, the transmission rod 3 penetrates through the detecting box 2 and is connected with a power generating device. By wind power generation, the device can work and act.

[0029] Embodiment 2

[0030] Refer to FIG. 1 to FIG. 7, In this embodiment, the sampling and detecting mechanism 5 includes a support pole 501 fixed on the floating plate 1 and a bracket 507; a rotary rod 502 penetrates through and is installed on the top of the support pole 501; a rotary plate 503 is fixedly installed at one end of the rotary rod 502; a connecting plate 504 is fixedly installed on an outer side of the rotary plate 503; a first rotary pin 505 is provided at the end portion of one end of the connecting plate 504; the first rotary pin 505 is rotationally equipped with a first connecting rod 506; a second rotary pin 508 is provided at the other end of the first connecting rod 506; the second rotary pin 508 penetrates through the bracket 507 and is connected with a first rocker arm 509; a third rotary pin 510 is provided at the other end of the first rocker arm 509; a second connecting rod 511 is provided at the other end of the third rotary pin 510; a fourth rotary pin 512 is provided at the other end of the second connecting rod 511; a second rocker arm 513 is installed at the other end of the fourth rotary pin 512; a fifth rotary pin 516 is provided at an end portion of the second rocker arm 513; the fifth rotary pin 516 is rotationally installed on the bracket 507; a sleeve 514 is fixedly installed at the middle part of the second connecting rod 511; the bottom of the sleeve 514 is fixedly connected with a lifting rod 515, and a water collection mechanism 6 is installed at the bottom of the lifting rod 515.

[0031] In this embodiment, the floating plate 1 is formed with a sampling hole 517 at a position corresponding to the water lifting rod 515. Sea water samples are collected and detected through the sampling hole 517.

[0032] In this embodiment, the rotary rod 502 is fixed at a non-central position of the rotary plate 503, such that the rotary plate 503 drives the connecting plate 514 to perform circulation rotation.

[0033] Embodiment 3

[0034] Refer to FIG. 1 to FIG. 7. In this embodiment, the water collection mechanism 6 includes a controller 601; a third connecting rod 602 is fixed at the bottom of the controller 601; a motor 603 is fixedly installed at an end portion of the third connecting rod 602; the motor 603 is rotationally connected with a drive shaft 604; a first connecting block 607 is fixed at the other end of the drive shaft 604; the first connecting block 607 is internally penetrated by a first movable rod 606; a first rotary connecting block 605 is provided at an end portion of the first movable rod 606; the other side of thefirst rotary connecting block 605 is rotationally connected with a second movable rod 608; a second rotary connecting block 609 is provided at an end portion of the second movable rod 608; the second rotary connecting block 609 is equipped with a third movable rod 610; a second connecting block 611 is provided at the middle part of the third movable rod 610; one side of the second connecting block 611 is connected with a third connecting rod 612; a connecting disc 613 is fixed at an end portion of the third connecting rod 612; and a sampling tank 614 is fixed at the bottom of the connecting disc 613.

[0035] In this embodiment, the sampling tank 614 is formed with a plurality of sampling openings in different positions, facilitating water sampling and detection in different positions.

[0036] Working principle of the utility model: The device is placed at a specific detecting point on the ocean surface, and the fan wheel 4 on the detecting box 2 generates power which is supplied to the sampling and detecting mechanism 5; when the sampling and detecting mechanism 5 is working and the lifting rod 515 moves to the upper part of the sampling hole 517,the water collection mechanism 6 collects sea water for detection, and the ocean environment is monitored according to the detection result. The ocean environment monitoring device for ocean engineering is convenient and practical.

[0037] The foregoing are merely preferred embodiments of the utility model. It should be noted that, within the concept of the utility model, those ordinarily skilled in the art can make various changes and improvements which shall all fall within the protective scope of the utility model and shall not affect the effects and patent practice of the utility model.

Claims (5)

1. An ocean environment monitoring device for ocean engineering, comprising a floating plate (1), wherein the floating plate (1) is fixedly installed with a detecting box (2); the detecting box (2) is internally provided with a sampling and detecting mechanism (5); a transmission rod (3) is fixed on the top of the detecting box (2); and a fan wheel (4) is fixedly installed on the top of the transmission rod (3).

2. The ocean environment monitoring device for ocean engineering according to Claim 1, wherein the transmission rod (3) penetrates through the detecting box (2) and is connected with a power generating device.

3. The ocean environment monitoring device for ocean engineering according to Claim 1, wherein the sampling and detecting mechanism (5) comprises a support pole (501) fixed on the floating plate (1) and a bracket (507); a rotary rod (502) penetrates through and is installed on the top of the support pole (501); a rotary plate (503) isfixedly installed at one end of the rotary rod (502); a connecting plate (504) is fixedly installed on an outer side of the rotary plate (503); a first rotary pin (505) is provided at the end portion of one end of the connecting plate (504); the first rotary pin (505) is rotationally equipped with a first connecting rod (506); a second rotary pin (508) is provided at the other end of the first connecting rod (506); the second rotary pin (508) penetrates through the bracket (507) and is connected with a first rocker arm (509); a third rotary pin (510) is provided at the other end of the first rocker arm (509); a second connecting rod (511) is provided at the other end of the third rotary pin (510); a fourth rotary pin (512) is provided at the other end of the second connecting rod (511); a second rocker arm (513) is installed at the other end of the fourth rotary pin (512); a fifth rotary pin (516) is provided at an end portion of the second rocker arm (513); the fifth rotary pin (516) is rotationally installed on the bracket (507); a sleeve (514) is fixedly installed at the middle part of the second connecting rod (511); the bottom of the sleeve (514) is fixedly connected with a lifting rod (515), and a water collection mechanism (6) is installed at the bottom of the lifting rod (515).

4. The ocean environment monitoring device for ocean engineering according to Claim 3, wherein the floating plate (1) is formed with a sampling hole (517) at a position corresponding to the lifting rod (515).

5. The ocean environment monitoring device for ocean engineering according to Claim 3, wherein the rotary rod (502) is fixed at a non-central position of the rotary plate (503).