CN212872430U - Novel coastal waters water body environmental monitoring drift ball - Google Patents

Abstract

The utility model provides a novel coastal waters water environment monitoring drift ball, including monitoring drift spheroid, fluorescence coating, solar cell panel, controller, first lithium cell, turbidity sensor, protection casing, COD sensor, sealing plug, second lithium cell, support division board, horizontal hanger plate, connecting ear limit, fixed link, the sealed cover plate assembly of leak protection and support frame. The first lithium battery and the second lithium battery of the utility model play a role in power supply and counterweight shaping; the novel water body monitoring ball is used for monitoring parameter information such as turbidity, COD and the like in the tested water body environment in real time, and positioning monitoring and real-time return of monitoring data are realized through a GSM/GPRS satellite navigation system so as to obtain real-time and continuous water environment parameter information; the arrangement of the fluorescent coating can play a role in preventing pollution and corrosion; the device has the characteristics of low cost and convenient use, and is connected with the offshore fixing device through the connecting ear edge and the fixing hanging ring, so that the stability is improved.

Description

Novel coastal waters water body environmental monitoring drift ball

Technical Field

The utility model belongs to the technical field of ocean water quality monitoring, especially, relate to a novel coastal waters water environmental monitoring drift ball.

Background

The marine environment is variable, sometimes windy and beautiful, level as mirrors, sometimes frightening as a horror, growling as a thunder. In order to better understand the ocean and monitor the ocean dynamics, a large number of ocean monitoring buoys are usually installed in the ocean to monitor the wave height of the waves, the direction of the ocean currents, the temperature, direction and pressure of the seawater. The general volume of ocean monitoring buoy is less, in the marine environment of big stormy waves, often rocks very badly to can influence the normal work of installing the monitoring facilities on ocean monitoring buoy, even more can lead to the monitoring facilities who installs on ocean monitoring buoy to take place to destroy or the trouble.

In addition, the invention is named as an ocean water quality monitoring device with the Chinese patent publication No. CN110912331A, the structure that a winding shaft is connected to an output shaft on the left side of a driving motor is that the winding shaft is connected with the output shaft on the left side of the driving motor through a coupler, the output shaft on the left side of the driving motor and the winding shaft are both cylindrical structures, the coupler comprises a sleeve with two through ends, a tensioning screw, a buffer rubber ring, a spiral beryllium bronze wire and a guide block, and more than two openings are distributed on the left end wall of the sleeve and the right end wall of the sleeve in an up-down mirror image mode by taking the central line of the sleeve as a reference. However, the existing drifting ball for monitoring the offshore water environment also has the problems that the installation and the positioning are inconvenient, the drifting ball is easy to invade seawater and the service life is short.

Therefore, the invention is very necessary to invent a novel drifting ball for monitoring the offshore water environment.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides a novel coastal waters water environmental monitoring drift ball to solve current coastal waters water environmental monitoring drift ball and be not convenient for install the location, invade the problem that sea water and life are shorter easily.

A novel offshore water environment monitoring drifting ball comprises a drifting ball body, a fluorescent coating, a solar cell panel, a controller, a first lithium battery, a turbidity sensor, a protective cover, a COD sensor, a sealing plug, a second lithium battery, a supporting and separating plate, a transverse hanging plate, a connecting lug edge, a fixing hanging ring, a leakage-proof sealing cover plate assembly and a supporting frame;

the fluorescent coating is coated on the outer surface of the drift monitoring sphere; the controller is connected with the middle position of the lower part of the transverse hanging plate through a screw and is positioned in the middle position inside the drifting monitoring sphere; the first lithium battery is connected to the left lower side of the interior of the drifting monitoring sphere through a bolt; the second lithium battery is connected to the right lower side of the interior of the drifting monitoring sphere through a bolt;

the turbidity sensor and the COD sensor penetrate through the middle position of the lower part of the drifting sphere and are connected with the controller; the protective covers are respectively arranged at the outer sides of the turbidity sensor and the COD sensor and are connected with the drifting monitoring sphere through bolts; one end of the supporting partition plate is longitudinally riveted on the inner wall of the drifting monitoring sphere, and the other end of the supporting partition plate is connected to the lower part of the transverse hanging plate through a screw;

the transverse hanging plate is transversely riveted at the upper side position inside the drifting monitoring sphere; the connecting lug side is connected to the upper part of the outer wall of the drifting monitoring sphere through a bolt; the fixed hanging ring is axially connected to the right side of the connecting ear; the leak-proof sealing cover plate assembly is connected to the upper part of the drifting monitoring sphere through bolts; one end of the support frame is connected to the upper portion of the drifting monitoring sphere through a bolt, and the other end of the support frame is connected to the lower portion of the solar cell panel through a bolt.

Preferably, the leakproof sealing cover plate assembly comprises a sealing cover, an upper clamping plate, an inflation tube, a sealing cover and a sealing rubber gasket, wherein the sealing cover is integrally poured in the middle of the upper part of the upper clamping plate; one end of the inflation tube is embedded in the middle of the upper part of the sealing cover, and the other end of the inflation tube is in threaded connection with the sealing cover; the sealing rubber gasket is arranged at the lower part of the upper clamping plate.

Preferably, the controller is internally embedded with a GSM/GPRS signal transmitter.

Preferably, the upper part of the drifting monitoring sphere is embedded with a lower connecting splint.

Preferably, the lower part of the protective cover is provided with a flow guide through hole; the flow guide through holes are provided in plurality.

Preferably, the first lithium battery and the second lithium battery are symmetrically arranged.

Preferably, the sealing plug is embedded at the intersection of the turbidity sensor, the COD sensor and the drift monitoring sphere.

Preferably, the lower connecting clamp plate and the upper connecting clamp plate are arranged in a bolt connection manner; the sealing rubber gasket is arranged between the lower connecting clamp plate and the upper connecting clamp plate.

Preferably, the drift monitoring sphere is an ABS plastic sphere; the wall thickness of the drift monitoring sphere is set to be five millimeters to eight millimeters.

Preferably, the turbidity sensor and the COD sensor are respectively and electrically connected with the controller; the turbidity sensor, the COD sensor and the controller are respectively and electrically connected with the first lithium battery and the second lithium battery.

Compared with the prior art, the beneficial effects of the utility model are that: the first lithium battery and the second lithium battery play a role in power supply and also play a role in counterweight sizing; the novel water body monitoring ball is used for monitoring parameter information such as turbidity, COD and the like in the tested water body environment in real time, and positioning monitoring and real-time return of monitoring data are realized through a GSM/GPRS satellite navigation system so as to obtain real-time and continuous water environment parameter information; the arrangement of the fluorescent coating can play a role in preventing pollution and corrosion; this drift monitoring ball is disposable formula water environmental monitoring system of throwing promptly, has with low costs, convenient to use's characteristics, is connected with coastal waters fixing device through connecting ear limit and fixed link, increases stability.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural view of the leak-proof sealing cover plate assembly of the present invention.

In the figure:

1. monitoring the drifting sphere; 1-1, connecting a lower splint; 2. a fluorescent coating; 3. a solar panel; 4. a controller; 5. a first lithium battery; 6. a turbidity sensor; 7. a protective cover; 8. a COD sensor; 9. a sealing plug; 10. a second lithium battery; 11. supporting the partition plate; 12. a transverse hanging plate; 13. connecting the ear edges; 14. fixing a hanging ring; 15. a leak-proof sealing cover plate assembly; 16. a support frame; 151. a sealing cover; 152. connecting an upper splint; 153. an inflation tube; 154. a sealing plug; 155. and sealing the rubber gasket.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

example (b):

as shown in the accompanying drawings 1 and 2, the utility model provides a novel coastal waters water environment monitoring drift ball, including monitoring drift spheroid 1, fluorescence coating 2, solar cell panel 3, controller 4, first lithium cell 5, turbidity sensor 6, protection casing 7, COD sensor 8, sealing plug 9, second lithium cell 10, support division board 11, horizontal hanger plate 12, connecting ear limit 13, fixed link 14, the sealed cover plate subassembly of leak protection 15 and support frame 16.

The fluorescent coating 2 is coated on the outer surface of the drift monitoring sphere 1; the controller 4 is connected with the middle position of the lower part of the transverse hanging plate 12 through a screw and is positioned in the middle position inside the drifting sphere 1; the first lithium battery 5 is connected to the left lower side of the interior of the drift monitoring sphere 1 through a bolt; the second lithium battery 10 is connected to the right lower side of the interior of the drift monitoring sphere 1 through a bolt;

the turbidity sensor 6 and the COD sensor 8 penetrate through the middle position of the lower part of the drift monitoring sphere 1 and are connected with the controller 4; the protective cover 7 is respectively arranged at the outer sides of the turbidity sensor 6 and the COD sensor 8 and is connected with the drifting monitoring sphere 1 through bolts; one end of the supporting partition plate 11 is longitudinally riveted on the inner wall of the drift monitoring sphere 1, and the other end is connected with the lower part of the transverse hanging plate 12 through a screw;

the transverse hanging plate 12 is transversely riveted at the upper side position inside the drift monitoring sphere 1; the connecting lug edge 13 is in bolted connection with the upper part of the outer wall of the drifting monitoring sphere 1; the fixed hanging ring 14 is coupled at the right side of the connecting ear edge 13; the leakproof sealing cover plate component 15 is connected to the upper part of the drifting monitoring sphere 1 through bolts; one end of the support frame 16 is connected with the upper part of the drifting monitoring sphere 1 through a bolt, and the other end of the support frame is connected with the lower part of the solar cell panel 3 through a bolt.

In the above embodiment, as shown in fig. 1, specifically, the leakproof sealing cover assembly 15 comprises a sealing cover 151, an upper clamping plate 152, an inflation tube 153, a sealing cover 154 and a sealing rubber gasket 155, wherein the sealing cover 151 is integrally cast at the upper middle position of the upper clamping plate 152; one end of the inflation tube 153 is embedded in the middle of the upper part of the sealing cover 151, and the other end is in threaded connection with a sealing cover 154; the sealing rubber gasket 155 is disposed at the lower portion of the upper clamping plate 152.

In the above embodiment, specifically, the controller 4 is embedded with a GSM/GPRS signal transmitter; the upper part of the drift monitoring sphere 1 is embedded with a lower connecting splint 1-1; the lower part of the protective cover 7 is provided with a flow guide through hole; the flow guide through holes are provided in plurality.

In the above embodiment, specifically, the first lithium battery 5 and the second lithium battery 10 are symmetrically disposed; the sealing plug 9 is embedded at the intersection of the turbidity sensor 6, the COD sensor 8 and the drift monitoring sphere 1; the lower connecting splint 1-1 and the upper connecting splint 152 are arranged in a bolt connection way; the sealing rubber gasket 155 is disposed between the lower connecting plate 1-1 and the upper connecting plate 152.

In the above embodiment, specifically, the drift monitoring sphere 1 is specifically an ABS plastic sphere; the wall thickness of the drift monitoring sphere 1 is set to be five millimeters to eight millimeters.

In the above embodiment, specifically, the turbidity sensor 6 and the COD sensor 8 are respectively electrically connected to the controller 4; the turbidity sensor 6, the COD sensor 8 and the controller 4 are respectively and electrically connected with the first lithium battery 5 and the second lithium battery 10.

In the above embodiment, specifically, the solar cell panel 3, the controller 4, the first lithium battery 5, the turbidity sensor 6, the COD sensor 8 and the second lithium battery 10 are conventional devices commonly used in the art; for example: the turbidity sensor 6 is a sensor with the model number of RS 485; the COD sensor 8 specifically adopts a sensor with the model of ZZ-WQS-CODA.

Principle of operation

When the utility model is used, the first lithium battery 5 and the second lithium battery 10 play a role in power supply and counterweight shaping; the novel water body monitoring ball is used for monitoring parameter information such as turbidity, COD and the like in the tested water body environment in real time, and positioning monitoring and real-time return of monitoring data are realized through a GSM/GPRS satellite navigation system so as to obtain real-time and continuous water environment parameter information; the arrangement of the fluorescent coating 2 can play a role in preventing pollution and corrosion; this drift monitoring ball is disposable formula water environmental monitoring system of throwing promptly, has with low costs, convenient to use's characteristics, is connected with coastal waters fixing device through connecting ear limit 13 and fixed link 14, increases stability.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the equipment or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (7)

1. The novel offshore water environment monitoring drifting ball is characterized by comprising a monitoring drifting ball body (1), a fluorescent coating (2), a solar cell panel (3), a controller (4), a first lithium battery (5), a turbidity sensor (6), a protective cover (7), a COD (chemical oxygen demand) sensor (8), a sealing plug (9), a second lithium battery (10), a supporting and separating plate (11), a transverse hanging plate (12), a connecting lug edge (13), a fixed hanging ring (14), a leakage-proof sealing cover plate assembly (15) and a supporting frame (16);

the fluorescent coating (2) is coated on the outer surface of the drift monitoring sphere (1); the controller (4) is connected to the middle position of the lower part of the transverse hanging plate (12) through a screw and is positioned in the middle position inside the drift monitoring sphere (1); the first lithium battery (5) is connected to the left lower side of the interior of the drift monitoring sphere (1) through a bolt; the second lithium battery (10) is connected to the right lower side of the interior of the drift monitoring sphere (1) through a bolt;

the turbidity sensor (6) and the COD sensor (8) penetrate through the middle position of the lower part of the drift monitoring sphere (1) and are connected with the controller (4); the protective cover (7) is respectively arranged at the outer sides of the turbidity sensor (6) and the COD sensor (8) and is connected with the drifting monitoring sphere (1) through bolts; one end of the supporting partition plate (11) is longitudinally riveted on the inner wall of the drift monitoring sphere (1), and the other end of the supporting partition plate is connected with the lower part of the transverse hanging plate (12) through a screw; the transverse hanging plate (12) is transversely riveted at the upper side position inside the drift monitoring sphere (1);

the connecting lug edge (13) is connected to the upper part of the outer wall of the drifting monitoring sphere (1) through bolts; the fixed suspension loop (14) is coupled at the right side of the connecting ear edge (13); the leakproof sealing cover plate component (15) is connected to the upper part of the drifting monitoring sphere (1) through bolts; one end of the support frame (16) is connected with the upper part of the drifting monitoring sphere (1) through a bolt, and the other end of the support frame is connected with the lower part of the solar cell panel (3) through a bolt.

2. The novel offshore water environment monitoring drift ball of claim 1, wherein the leakproof sealing cover assembly (15) comprises a sealing cover (151), an upper clamping plate (152), an inflation tube (153), a sealing cover (154) and a sealing rubber gasket (155); the sealing cover (151) is integrally cast at the middle position of the upper part of the upper connecting splint (152); one end of the inflation tube (153) is embedded in the middle of the upper part of the sealing cover (151), and the other end of the inflation tube is in threaded connection with a sealing cover (154); the sealing rubber gasket (155) is arranged at the lower part of the upper clamping plate (152);

the upper part of the drift monitoring sphere (1) is embedded with a lower connecting splint (1-1).

3. A novel offshore water environment monitoring drift ball according to claim 1, wherein said controller (4) is embedded with a GSM/GPRS signal transmitter.

4. The novel offshore water environment monitoring drifting ball of claim 1, characterized in that the lower part of the protective cover (7) is provided with a flow guiding through hole; the flow guide through holes are provided in plurality.

5. Novel offshore water environment monitoring drift ball according to claim 1, wherein said sealing plug (9) is embedded at the intersection of the turbidity sensor (6) and the COD sensor (8) with the monitoring drift ball (1).

6. The novel offshore water environment monitoring drift ball of claim 2, wherein the lower connecting plate (1-1) and the upper connecting plate (152) are arranged in a bolted connection; the sealing rubber gasket (155) is arranged between the lower connecting splint (1-1) and the upper connecting splint (152).

7. The novel offshore water environment monitoring drift ball as claimed in claim 1, wherein said drift monitoring ball (1) is an ABS plastic ball; the wall thickness of the drift monitoring sphere (1) is set to be five millimeters to eight millimeters.

Images