阅读说明：本技术 监测水体生化需氧量的浮标装置 (Buoy device for monitoring biochemical oxygen demand of water body ) 是由 刘志丹 贾冰楠 黄思捷 于 2021-09-16 设计创作，主要内容包括：本发明提供一种监测水体生化需氧量的浮标装置,包括壳体、设在壳体上的通讯系统、浮力调节系统、控制系统和电源管理系统,通讯系统与地面监控中心通信；浮力调节系统控制壳体升降；控制系统与通讯系统和浮力调节系统电连接；电源管理系统包括给控制系统供电的电池、给电池充电的MFC型BOD传感器和给MFC型BOD传感器阴极供氧的供气机构,MFC型BOD传感器阳极与水体接触、以检测水体BOD浓度。本浮标装置通过MFC型BOD传感器给电池充电,使电池具有足够电量为整体装置供电,解决了现有浮标设备电能供应限制问题,增加了浮标装置的寿命,使浮标装置有实时定深检测水体中BOD浓度的功能,通过供气机构为MFC型BOD传感器阴极提供足够的氧气,保证MFC型BOD传感器能正常运行。(The invention provides a buoy device for monitoring biochemical oxygen demand of a water body, which comprises a shell, a communication system, a buoyancy regulating system, a control system and a power supply management system, wherein the communication system, the buoyancy regulating system, the control system and the power supply management system are arranged on the shell; the buoyancy regulating system controls the shell to lift; the control system is electrically connected with the communication system and the buoyancy regulating system; the power management system comprises a battery for supplying power to the control system, an MFC type BOD sensor for charging the battery and an air supply mechanism for supplying oxygen to the cathode of the MFC type BOD sensor, wherein the anode of the MFC type BOD sensor is in contact with the water body so as to detect the BOD concentration of the water body. This buoy device charges for the battery through MFC type BOD sensor, makes the battery have enough electric quantity and supplies power for the whole device, has solved current buoy device electric energy supply restriction problem, has increased buoy device's life-span, makes buoy device have the function of the BOD concentration in the real-time depthkeeping detection water, provides sufficient oxygen for MFC type BOD sensor negative pole through air feed mechanism, guarantees MFC type BOD sensor ability normal operating.)

1. The utility model provides a buoy device of monitoring water body biochemical oxygen demand which characterized in that includes:

a housing;

the communication system is arranged on the shell and is used for communicating with a ground monitoring center;

the buoyancy adjusting system is arranged on the shell and used for controlling the shell to lift;

the control system is arranged on the shell and is electrically connected with the communication system and the buoyancy regulating system;

the power management system sets up on the casing, the power management system including be used for giving the battery of control system power supply, be used for giving MFC type BOD sensor that the battery charges and be used for giving the air feed mechanism of MFC type BOD sensor's negative pole oxygen suppliment, MFC type BOD sensor's positive pole contacts with the water, with the BOD concentration that can detect the water.

2. The buoy device for monitoring biochemical oxygen demand of a water body according to claim 1, wherein the gas supply mechanism comprises:

the air pipe is used for communicating the external atmosphere with the cathode of the MFC type BOD sensor;

and the air pressure valve is arranged on the air pipe and used for controlling the on-off of the air pipe, and the air pressure valve is electrically connected with the control system.

3. The buoy device for monitoring the biochemical oxygen demand of the water body as claimed in claim 2, wherein the buoyancy regulating system comprises an outer airbag disposed on the housing, the outer airbag is communicated with the outside atmosphere through a first air pipe, a first air pressure valve for controlling the on-off of the first air pipe is disposed on the first air pipe, the first air pressure valve is electrically connected with the control system, and the outer airbag can be communicated with the air pipe.

4. The float device for monitoring biochemical oxygen demand of a water body according to claim 1, wherein the power management system further comprises a power processor for processing the electrical power generated by the MFC type BOD sensor, the power processor being electrically connected to the MFC type BOD sensor and the battery.

5. The buoy device for monitoring biochemical oxygen demand of a water body according to claim 1, wherein the power management system further comprises a backup battery, and the backup battery is electrically connected with the control system.

6. The float device for monitoring biochemical oxygen demand of a water body according to claim 4, wherein the MFC type BOD sensor comprises a plurality of single-chamber MFCs fixed at the bottom of the housing, the single-chamber MFCs comprise a ceramic cylinder, an MFC anode wrapped on the outer wall of the ceramic cylinder, and an MFC cathode located in the ceramic cylinder, the MFC anode is electrically connected with the negative electrode of the power processor, and the MFC cathode is electrically connected with the positive electrode of the power processor.

7. The buoy device for monitoring biochemical oxygen demand of a water body according to claim 1, wherein the buoyancy regulating system further comprises a hydraulic system, the hydraulic system comprising:

the hydraulic cylinder is arranged in the shell;

the buoyancy oil bag is arranged outside the shell and communicated with the hydraulic cylinder through an oil pipe;

and the driving module is used for driving the hydraulic cylinder to act, and is electrically connected with the control system.

8. The buoy device for monitoring biochemical oxygen demand of a water body according to claim 1, further comprising a CTD sensor disposed at an upper portion of the housing, the CTD sensor being electrically connected to the control system.

9. The buoy device for monitoring biochemical oxygen demand of a water body according to claim 1, wherein the communication system comprises a communication module located in the housing and an antenna located at the top end of the housing, the antenna is electrically connected with the communication module, and the communication module is electrically connected with the control system.

10. The buoy device for monitoring biochemical oxygen demand of a water body according to claim 6, wherein a plurality of the single-chamber MFCs are fixed at the bottom of the housing through a non-metal plate, and an MFC anode of the single-chamber MFC is lower than the non-metal plate.

Technical Field

The invention relates to the technical field of water body pollution and treatment, in particular to a buoy device for monitoring biochemical oxygen demand of a water body.

Background

The real-time and effective monitoring of the hydrological environment is a crucial link for ecological civilization construction, and the self-sustaining section buoy is one of the earliest observation platforms applied in water body detection, can be used for observing water body information related to climate change, and has the characteristics of easiness in investment, small size, light weight and low manufacturing cost. However, since the current buoy device cannot be replenished during use, the portable battery capacity is limited, and the battery capacity becomes an important factor limiting the life of the self-contained buoy device.

Biochemical Oxygen Demand (BOD) is a comprehensive index representing the content of aerobic pollutants in water, is an important water pollution parameter, and has been widely used as an environmental monitoring index for a long time. However, the traditional BOD monitoring is time-consuming and labor-consuming, and is not suitable for in-situ monitoring and on-line monitoring of the actual water body environment; the Microbial Fuel Cell (MFC) as a biosensor capable of monitoring BOD has the advantages of rapidness, real-time performance and self-maintenance, and is essentially used as a battery, can automatically output an electric signal without an external power supply, and is an ideal choice for monitoring the actual water environment.

The technical specification of surface water and sewage monitoring (HJ/T91-2002) clearly stipulates that the pollution condition of surface water can be objectively reflected to a great extent after subsequent test and analysis on water samples collected at fixed depth, and the method has important value for water environment evaluation. However, in the field of BOD monitoring, in the existing research (Peixoto et al, 2011) that the MFC is applied to test the organic matter concentration of the water body in the diving mode, the water body only stays at the depth close to the water surface, and the self-power function is not provided, and in the research (Pasternak et al, 2017) that the MFC is applied to test the organic matter concentration of the water body under the water surface, the self-power function is added, but the water body is only limited to the depth close to the water surface. The air cathode MFC configuration was chosen in both studies because of its high power generation efficiency, but because the cathode of the MFC had insufficient oxygen to ensure the proper operation of the device when the device was submerged, the depth-fixed BOD monitoring was not possible.

Therefore, how to solve the problem that the cathode of the MFC cannot have sufficient oxygen to ensure the normal operation of the device and the deep BOD monitoring cannot be performed when the conventional device for monitoring the biochemical oxygen demand of the water body by using the MFC is in a submerged state is an important subject to be solved in the industry at present.

Disclosure of Invention

The invention provides a buoy device for monitoring biochemical oxygen demand of a water body, which is used for solving the defect that the cathode of an MFC (micro-electro-mechanical Fuel cell) does not have sufficient oxygen to ensure the normal operation of the device and the BOD monitoring at a fixed depth can not be carried out when the conventional equipment for monitoring the biochemical oxygen demand of the water body by utilizing the MFC is in a submerged state, solving the problem of the limitation of the electric energy supply of the conventional profile buoy device, greatly prolonging the service life of the buoy device, simultaneously enabling the buoy device to have the function of detecting the BOD concentration in the water body at a fixed depth in real time, and enabling the BOD concentration of the water body to be monitored at a fixed depth in a remote area in real time; and through the air supply mechanism arranged in the buoy device, the floating and sinking capacity loss near the water surface is reduced, meanwhile, enough oxygen is provided for the cathode of the MFC type BOD sensor, and the normal operation of the MFC type BOD sensor is ensured.

The invention provides a buoy device for monitoring biochemical oxygen demand of a water body, comprising:

a housing;

the communication system is arranged on the shell and is used for communicating with a ground monitoring center;

the buoyancy adjusting system is arranged on the shell and used for controlling the shell to lift;

the control system is arranged on the shell and is electrically connected with the communication system and the buoyancy regulating system;

the power management system sets up on the casing, the power management system including be used for giving the battery of control system power supply, be used for giving MFC type BOD sensor that the battery charges and be used for giving the air feed mechanism of MFC type BOD sensor's negative pole oxygen suppliment, MFC type BOD sensor's positive pole contacts with the water, with the BOD concentration that can detect the water.

According to the buoy device for monitoring the biochemical oxygen demand of the water body, provided by the invention, the gas supply mechanism comprises:

the air pipe is used for communicating the external atmosphere with the cathode of the MFC type BOD sensor;

and the air pressure valve is arranged on the air pipe and used for controlling the on-off of the air pipe, and the air pressure valve is electrically connected with the control system.

According to the buoy device for monitoring the biochemical oxygen demand of the water body, provided by the invention, the buoyancy regulating system comprises an outer air bag arranged on the shell, the outer air bag is communicated with the outside atmosphere through a first air pipe, a first air pressure valve for controlling the first air pipe to be switched on and off is arranged on the first air pipe, the first air pressure valve is electrically connected with the control system, and the outer air bag can be communicated with the air pipe.

According to the buoy device for monitoring the biochemical oxygen demand of the water body, provided by the invention, the power management system further comprises an electric energy processor for processing electric energy generated by the MFC type BOD sensor, and the electric energy processor is electrically connected with the MFC type BOD sensor and the battery.

According to the buoy device for monitoring the biochemical oxygen demand of the water body, provided by the invention, the power management system further comprises a standby battery, and the standby battery is electrically connected with the control system.

According to the buoy device for monitoring the biochemical oxygen demand of the water body, provided by the invention, the MFC type BOD sensor comprises a plurality of single-chamber MFCs fixed at the bottom of the shell, each single-chamber MFC comprises a ceramic cylinder, an MFC anode wrapped on the outer wall of the ceramic cylinder and an MFC cathode positioned in the ceramic cylinder, the MFC anode is electrically connected with the cathode of the electric energy processor, and the MFC cathode is electrically connected with the anode of the electric energy processor.

According to the buoy device for monitoring the biochemical oxygen demand of the water body, the buoyancy adjusting system further comprises a hydraulic system, and the hydraulic system comprises:

the hydraulic cylinder is arranged in the shell;

the buoyancy oil bag is arranged outside the shell and communicated with the hydraulic cylinder through an oil pipe;

and the driving module is used for driving the hydraulic cylinder to act, and is electrically connected with the control system.

The buoy device for monitoring the biochemical oxygen demand of the water body further comprises a CTD sensor arranged on the upper portion of the shell, and the CTD sensor is electrically connected with the control system.

According to the buoy device for monitoring the biochemical oxygen demand of the water body, provided by the invention, the communication system comprises a communication module positioned in the shell and an antenna positioned at the top end of the shell, the antenna is electrically connected with the communication module, and the communication module is electrically connected with the control system.

According to the buoy device for monitoring the biochemical oxygen demand of the water body, provided by the invention, a plurality of single-chamber MFCs are fixed at the bottom of the shell through the non-metal plate, and the MFC anodes of the single-chamber MFCs are lower than the non-metal plate.

According to the buoy device for monitoring the biochemical oxygen demand of the water body, the electric energy generated by degrading organic matters in the water body through the MFC type BOD sensor is used for charging the battery, so that the battery supplies power for the whole device, the problem of electric energy supply limitation of the existing profile buoy equipment is solved, the service life of the buoy device is greatly prolonged, meanwhile, the buoy device has the function of detecting the BOD concentration in the water body at a fixed depth in real time, and the real-time fixed depth monitoring of the BOD concentration in the water body in remote areas is possible; and through the air supply mechanism arranged in the buoy device, the floating and sinking capacity loss near the water surface is reduced, meanwhile, enough oxygen is provided for the cathode of the MFC type BOD sensor, and the normal operation of the MFC type BOD sensor is ensured.

Drawings

In order to more clearly illustrate the technical solutions of the present invention or the prior art, the drawings needed for 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 some embodiments of the present invention, and those skilled in the art can also obtain other drawings according to the drawings without creative efforts.

FIG. 1 is a schematic diagram of a float device for monitoring biochemical oxygen demand of a water body according to the present invention;

FIG. 2 is a top view of an acrylic panel provided by the present invention.

Reference numerals:

1: a housing; 101: a protective cover; 102: an access door;

2: a communication module; 201: an antenna; 3: a drive module;

301: a hydraulic cylinder; 4: a control system; 401: a CTD sensor;

501: MFC type BOD 502: a backup battery; 503: an electric energy processor;

a sensor;

504: an MFC cathode; 505: an MFC anode; 601: an outer bladder;

602: a first air pipe; 603: a second air pipe; 604: a third air pipe;

605: a buoyant oil bladder; 606: an acrylic plate; 607: an inner cavity of the shell;

608: and a through hole.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings, and it is obvious that the described embodiments are some, but not all embodiments of the present invention. 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.

The following describes the buoy device for monitoring the biochemical oxygen demand of the water body, which is disclosed by the invention, with reference to fig. 1-2, and comprises a shell 1, a communication system, a buoyancy regulating system, a control system 4 and a power management system, wherein the communication system, the buoyancy regulating system, the control system 4 and the power management system are all arranged on the shell 1, and the buoyancy regulating system is used for controlling the shell 1 to ascend and descend (namely, to ascend and descend) so as to regulate and control the position of the shell 1, namely, the position of the buoy device in the water body, and the buoy device can conveniently measure the water bodies at different depths; the communication system is used for communicating with the ground monitoring center so as to transmit data, buoy state information, positioning information and the like measured by the buoy device to the ground monitoring center and receive a control instruction sent by the ground monitoring center; the control system 4 is electrically connected with the communication system and the buoyancy regulating system and is used for controlling the communication system and the buoyancy regulating system; the power management system is used for supplying power to the control system 4, namely, the power management system can supply power to the electric equipment of the buoy device, so that the normal operation of the buoy device is ensured.

Wherein, power management system includes battery, MFC type BOD sensor 501 and air feed mechanism, and specifically, this battery can be the lithium cell, and MFC type BOD sensor 501 is used for charging for the battery, and the battery is used for supplying power for control system 4, supplies power for whole device through the battery, has improved the stability of this buoy device's electric energy supply. The gas supply mechanism is communicated with the cathode of the MFC type BOD sensor 501 for supplying oxygen to the cathode of the MFC type BOD sensor 501 to ensure that the cathode of the MFC type BOD sensor 501 has enough oxygen to generate electricity, thereby ensuring the normal operation of the MFC type BOD sensor 501. The anode of the MFC type BOD sensor 501 is in contact with the water body to detect the BOD concentration of the water body and ensure the normal operation of the MFC type BOD sensor 501.

Here, the power management system further includes a power processor 503, the power processor 503 is electrically connected to the MFC type BOD sensor 501 and the battery, and the power processor 503 is configured to process the power generated by the MFC type BOD sensor 501, to compare and process the power generated by the MFC type BOD sensor 501, and to output stable power to charge the battery, so that the battery power is continuously supplied, and the service life of the battery is increased. The power processor 503 includes a variable resistor, a super capacitor, and a hysteresis board equipped with a maximum power point tracking function. The power processor 503 may be an existing device, and only needs to convert the electric power generated by the MFC type BOD sensor 501 into electric power suitable for the battery. The power processor 503 may be communicatively connected to the communication system or control system 4 to transmit the BOD concentration data of the water body detected by the MFC type BOD sensor to the communication system or control system 4.

Therefore, the buoy device charges the battery through the electric energy generated by degrading organic matters in the water body by the MFC type BOD sensor 501, is used for running the whole device, solves the problem of electric energy supply limitation of the existing profile buoy equipment, greatly prolongs the service life of the buoy device, has the function of detecting the BOD concentration in the water body at the fixed depth in real time, and makes the monitoring of the BOD concentration in the water body at the fixed depth in real time in remote areas possible; and through the air feed mechanism that sets up in the buoy device, reduced the ability loss of sinking and floating near the surface of water, provided sufficient oxygen for the negative pole of MFC type BOD sensor 501 simultaneously, guaranteed MFC type BOD sensor 501 can normal operating.

In an alternative embodiment of the invention the air supply means comprises an air pipe and an air pressure valve, the air pipe being adapted to connect the outside atmosphere to the cathode of the MFC-type BOD sensor 501 so that outside air can enter at the cathode of the MFC-type BOD sensor 501 to supply oxygen to the cathode of the MFC-type BOD sensor 501. The air pressure valve is arranged on the air pipe and used for controlling the on-off of the air pipe so as to control the air to enter and exit, and the control system 4 is electrically connected with the air pressure valve and used for realizing the air transfer by controlling the state of the air pressure valve so as to supply oxygen for the cathode of the MFC type BOD sensor 501. And a pneumatic pump is further provided between the air tube and the cathode of the MFC-type BOD sensor 501, by which air is introduced into the cathode of the MFC-type BOD sensor 501.

In an alternative embodiment, the buoyancy adjusting system comprises an outer airbag 601 disposed on the housing 1, the outer airbag 601 is communicated with the outside atmosphere through a first air pipe 602, a first air pressure valve is disposed on the first air pipe 602 for controlling the on/off of the first air pipe 602, and the first air pressure valve is electrically connected with the control system 4. In this way, the external air bag 601 is inflated and deflated by controlling the state of the first air pressure valve, so that the lifting of the housing 1 can be controlled, and the position of the buoy device can be adjusted. And a first pneumatic pump is further provided between the first air tube 602 and the outer bladder 601, by which inflation and deflation of the outer bladder 601 are facilitated.

The outer bag 601 can communicate with the air tube, and oxygen can be supplied to the cathode of the MFC type BOD sensor 501 through the outer bag 601.

In a further embodiment, the gas supply mechanism may further comprise a housing inner cavity 607 disposed in the housing 1, the housing inner cavity 607 being capable of communicating with the outer airbag 601 and the cathode of the MFC type BOD sensor 501, wherein the gas pipe comprises a second gas pipe 603 and a third gas pipe 604, the second gas pipe 603 is used for communicating the housing inner cavity 607 and the outer airbag 601, and the third gas pipe 604 is used for communicating the housing inner cavity 607 and the cathode of the MFC type BOD sensor 501; the air pressure valves comprise a second air pressure valve and a third air pressure valve, the second air pressure valve is arranged on the second air pipe 603 and used for controlling the on-off of the second air pipe 603, and the third air pressure valve is arranged on the third air pipe 604 and used for controlling the on-off of the third air pipe 604; the pneumatic pump comprises a second pneumatic pump and a third pneumatic pump, the second pneumatic pump is arranged between the inner cavity 607 of the shell and the second air pipe 603, and the third pneumatic pump is arranged between the cathode of the MFC type BOD sensor 501 and the third air pipe 604. When the buoy device is in a state of sending and receiving information on the water surface, the control system 4 controls the first air pressure valve, the second air pressure valve and the third air pressure valve to be opened, and controls the first air pressure pump, the second air pressure pump and the third air pressure pump to be started to discharge the gas in the buoy device and suck new air, so that the cathode of the MFC type BOD sensor 501 has enough oxygen supply.

In an optional embodiment of the present invention, the power management system may further include a backup battery 502, the backup battery 502 is electrically connected to the control system 4, and when the electric energy generated by the MFC type BOD sensor 501 is insufficient for the entire device due to too low BOD concentration in the water body, the backup battery 502 can supply power to the electric equipment of the buoy device, so as to achieve the effect of uninterrupted power supply to the entire device.

In an alternative embodiment, the MFC type BOD sensor 501 comprises a plurality of single-chamber MFCs fixed to the bottom of the housing 1 such that the anodes of the single-chamber MFCs are in contact with the body of water. Wherein, the single-chamber MFC comprises a ceramic cylinder, an MFC anode 505 wrapped on the outer wall of the ceramic cylinder and an MFC cathode 504 positioned in the ceramic cylinder, the MFC anode 505 is electrically connected with the negative pole of the power processor 503, and the MFC cathode 504 is electrically connected with the positive pole of the power processor 503 so as to be capable of transmitting the generated power into the power processor 503.

Specifically, the ceramic cylinder was 200mm long, 60mm in inside diameter and 66mm in outside diameter, and the MFC anode 505 was composed of carbon fiber veil which was cut to a surface area of 1500cm²The rectangle is folded and wrapped on the outer wall of the ceramic cylinder, so thatAfter the carbon fiber veil is wound and fixed by one end of the nickel-chromium wire, the other end is connected with the negative electrode of the electric energy processor 503; the MFC cathode 504 may be a rectangular cathode sheet, and the rectangular cathode sheet is connected with the positive electrode of the electric energy processor 503 through a nichrome wire, the rectangular cathode sheet is folded and placed inside a ceramic cylinder, and the rectangular cathode sheet is composed of carbon fiber veil coated with a mixture of tetrafluoroethylene and activated carbon powder.

In this embodiment, the MFC type BOD sensor 501 includes six single-chamber MFCs, the six single-chamber MFCs are fixed at the bottom end of the housing 1 through a non-metal plate, specifically, the non-metal plate may be an acrylic plate 606, and the thickness of the acrylic plate 606 may be 3mm, the acrylic plate 606 is fixedly connected with the bottom end of the housing 1, six through holes 608 for fixing the single-chamber MFCs are provided on the acrylic plate 606, and an O-shaped rubber ring is further provided between the through holes 608 and the single-chamber MFCs to prevent water from entering the interior of the housing 1 through a gap between the through holes 608 and the single-chamber MFCs, thereby ensuring the sealing performance of the device.

It should be noted that the MFC anode 505 is disposed below the non-metal plate, i.e., the MFC anode 505 is disposed below the acrylic plate 606 so as to be able to contact the water body.

In an optional embodiment of the present invention, the buoyancy adjusting system further includes a hydraulic system, the hydraulic system includes a hydraulic cylinder 301 disposed in the housing 1, a buoyancy oil bag 605 disposed outside the housing 1, and a driving module 3 for driving the hydraulic cylinder 301 to move, the buoyancy oil bag 605 is communicated with the hydraulic cylinder 301 through an oil pipe, the driving module 3 is electrically connected to the control system 4, the control system 4 controls the driving module 3 to drive the hydraulic cylinder 301 to move, so as to realize the transfer of hydraulic oil between the hydraulic cylinder 301 and the buoyancy oil bag 605, regulate and control the lifting of the housing 1, and thus regulate and control the position of the buoy apparatus. Specifically, the driving module 3 may include a motor assembly, and the motor assembly drives the hydraulic cylinder 301 to move, so as to implement the transfer of hydraulic oil. In addition, the buoyancy regulating system further comprises a hydraulic valve arranged on the oil pipe, the control system 4 is electrically connected with the hydraulic valve, and the hydraulic oil is transferred from the buoyancy oil sac 605 to the hydraulic cylinder 301 or from the hydraulic cylinder 301 to the buoyancy oil sac 605 by controlling the state of the hydraulic valve and the action of the hydraulic cylinder 301.

In addition, the buoy device further comprises a CTD sensor 401 arranged at the upper part of the housing 1 for measuring water quality parameters of the water body, such as temperature, conductivity, pressure and the like of the water body. The CTD sensor 401 is electrically connected to the control system 4 so as to transmit the measured data to the control system 4, and then the measured data is transmitted to the ground monitoring center by the control system 4 through the communication system.

In an alternative embodiment, the communication system includes a communication module 2 located in the housing 1 and an antenna 201 located at the top end of the housing 1, the antenna 201 is electrically connected to the communication module 2 for receiving and transmitting signals, and the communication module 2 is electrically connected to the control system 4 for transmitting the received signals to the control system 4 or transmitting data stored in the control system 4 to the ground monitoring center.

And, control system 4 comprises control algorithm and control circuit, and control system 4 receives the remote control instruction through communication system, selects the mode of device motion. The temperature, pressure, conductivity and float control command measured by the CTD sensor 401 make the float device reach a preset state, and the data measured by the CTD sensor 401, float state information, positioning information and BOD concentration measured by the MFC type BOD sensor 501 are stored in motion and sent to the ground monitoring center through a communication system.

When the buoy device is positioned on the water surface and in a message receiving and sending state, the control system 4 controls the first air pressure valve, the second air pressure valve and the third air pressure valve to be opened, and exhausts the gas in the device through the three air pressure pumps and sucks new air again, so that the MFC cathode 504 has enough oxygen supply. Meanwhile, the communication system sends the data measured by the CTD sensor 401, the buoy state information and the positioning information to a ground monitoring center through satellite two-way communication and receives a next control instruction sent by the ground monitoring center; when the control command state is started, the buoyancy of the device at that time is calculated by the temperature, pressure, conductivity and float control command measured by the CTD sensor 401, and the control system 4 controls the hydraulic system to perform oil discharge or oil return operation and the outer bladder 601 to perform air discharge or air return operation, so that the float device reaches a predetermined position. In the process of floating up or submerging, after reaching a preset position set by a control command, the water body is measured by the mounted CTD sensor 401 and the MFC type BOD sensor 501, and the measured data is transmitted to the control system 4 for storage. Meanwhile, the MFC type BOD sensor 501 charges the battery after passing through the electric energy processor 503 by the electric energy generated by degrading organic matters in the water body, so that the battery can stably supply power to the whole device; when the BOD concentration of the water body is too low and the electric quantity is insufficient, the standby battery 502 can be used for supplying power temporarily, and the effects of uninterrupted power supply of the whole device and real-time depth-fixed monitoring of the BOD concentration of the water body are achieved.

In an alternative embodiment, the right side of the housing 1 is provided with an access door 102 with a width of 200mm from top to bottom so as to facilitate the access to the equipment and instruments in the housing 1. Further, a protection cover 101 is provided outside the housing 1, and the protection cover 101 covers the outer bag 601 to protect the outer bag 601. The shell 1 can be a hollow cylindrical structure, and the shell 1 is made of borosilicate glass, so that the shell has the advantages of low thermal expansion rate, difficult crushing, high compressive strength, high cost performance, never corrosion, no pollution and no electric conduction; the protective cover 101 may be made of polyethylene.

The above-described embodiments of the apparatus are merely illustrative, and the units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of the present embodiment. One of ordinary skill in the art can understand and implement it without inventive effort.

Through the above description of the embodiments, those skilled in the art will clearly understand that each embodiment can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware. With this understanding in mind, the above-described technical solutions may be embodied in the form of a software product, which can be stored in a computer-readable storage medium such as ROM/RAM, magnetic disk, optical disk, etc., and includes instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to execute the methods described in the embodiments or some parts of the embodiments.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.