CN110104127B - Buoy for remote control water quality monitoring - Google Patents

Abstract

The invention discloses a remote control buoy for water quality monitoring, which comprises a floating box and an adjusting box, wherein the bottom of the floating box is communicated with a drainage box, the bottom of the drainage box is communicated with a drainage pipe, a partition plate is fixedly connected between two sides of an inner cavity of the floating box, a motor box is fixedly connected between one side of the top of the partition plate and the top of the inner cavity of the floating box, and a first motor is fixedly connected to one side of the bottom of the inner cavity of the motor box through a support plate. This buoy for remote control water quality monitoring can carry out water quality monitoring to the moisture of the different degree of depth in same waters, and the person of being convenient for use monitors the quality of water of the different degree of depth, has improved water quality monitoring's comprehensiveness and diversification, has improved monitoring data's scope for monitoring result is more comprehensive, and the user can control the falling depth of water pump in the long-range, great saving the energy, can improve solar cell panel's the utilization ratio to the sunlight.

Description

Buoy for remote control water quality monitoring

Technical Field

The invention relates to the technical field of water quality monitoring, in particular to a buoy for remotely controlling water quality monitoring.

Background

The water quality monitoring is a process for monitoring and measuring the types of pollutants in water bodies, the concentrations and the change trends of various pollutants and evaluating the water quality conditions, and a chemical method, an electrochemical method, an atomic absorption spectrophotometry, an ion selective electrode method, an ion chromatography method, a gas chromatography method, a plasma emission spectrometry method and the like are also commonly adopted in the routine monitoring of water quality at home and abroad, wherein the ion selective electrode method (qualitative method, quantitative method) and the chemical method (gravimetric method, volumetric titration method and spectrophotometry) are generally adopted, a buoy is generally required to detect the water quality of different water areas in the water quality monitoring process, and the buoy refers to a navigation mark floating on the water surface and is anchored at a designated position for marking the range of a navigation channel, indicating a shoal, obstructing the navigation objects or representing a water surface navigation aid mark with special purposes. The buoy has the largest quantity in the navigation mark, is widely applied and is arranged at the position where the fixed navigation mark is difficult or not suitable to be arranged, the existing buoy can only extract water with a certain depth and then carry out water quality monitoring, so that a user is inconvenient to monitor the water quality with different depths in the same water area, and the use of the user is influenced.

Traditional buoy for remote control water quality monitoring, can not carry out water quality monitoring to the moisture of the different degree of depth in same waters, the user of being not convenient for monitors the quality of water of the different degree of depth, water quality monitoring's comprehensiveness and diversification have been reduced, monitoring data's scope has been reduced, and the user can not control the descending degree of depth of water pump in the long-range, safe and reliable inadequately, great waste the energy, can not improve solar cell panel's the utilization ratio to the sunlight, energy-concerving and environment-protective enough, can not wholly carry out the dismouting to the regulating box at fixed plate top, the user of being not convenient for carries out the transportation after the dismouting to the device, can not be fine discharge the moisture at baffle top.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a remote control buoy for water quality monitoring, which solves the problems that the remote control buoy for water quality monitoring can not monitor the water quality of different depths in the same water area and can not improve the utilization rate of solar panels to sunlight.

In order to achieve the purpose, the invention is realized by the following technical scheme: a buoy for remote control water quality monitoring comprises a floating box and an adjusting box, wherein the bottom of the floating box is communicated with a drainage box, the bottom of the drainage box is communicated with a drainage pipe, a partition plate is fixedly connected between two sides of an inner cavity of the floating box, a motor box is fixedly connected between one side of the top of the partition plate and the top of the inner cavity of the floating box, one side of the bottom of the inner cavity of the motor box is fixedly connected with a first motor through a support plate, an output shaft of the first motor is fixedly connected with a rotating rod, one end, away from the first motor, of the rotating rod is rotatably connected with one side of the inner cavity of the motor box through a bearing, a wire coil is fixedly connected to the surface of the rotating rod, a connecting wire is fixedly connected to the surface of the wire coil, the bottom end of the connecting wire sequentially penetrates through the motor box and the floating box and extends to the inner cavity of the floating box, and the connecting wire extends to the one end fixedly connected with water pump of drain pipe bottom, the delivery port intercommunication of water pump has coupling hose, coupling hose's top runs through water drainage tank, flotation tank and baffle in proper order and extends to the top of baffle, the top of flotation tank inner chamber and the one side fixedly connected with water quality monitoring probe that is located the motor case, the top of baffle just is located water quality monitoring probe and runs through fixed pipe under, the inside fixedly connected with solenoid valve of fixed pipe.

Preferably, the fixed case of one side fixedly connected with at regulating box inner chamber top, backup pad fixedly connected with second motor is passed through to one side of fixed incasement chamber bottom, the first belt pulley of output shaft fixedly connected with of second motor, the opposite side fixedly connected with connecting plate of fixed incasement chamber bottom to the inside of connecting plate is rotated through the bearing and is connected with the connecting rod, the one end fixedly connected with second belt pulley of connecting rod, the surface of first belt pulley and the surface of second belt pulley pass through belt transmission and connect, the other end fixedly connected with gear of connecting rod.

Preferably, the equal fixedly connected with slide rail in both sides of fixed bottom of the case portion, the bottom of slide rail and the bottom fixed connection of regulating box inner chamber to sliding connection has the slide between two slide rails, the top fixedly connected with tooth dental lamina of slide, the top of tooth dental lamina runs through fixed case and regulating box in proper order and extends to the top of regulating box to the surface swing joint that the tooth dental lamina extended to the regulating box top has solar cell panel, one side swing joint at moving part and regulating box top is passed through to one side of solar cell panel bottom, the surface of tooth dental lamina one side and the surface meshing of gear one side.

Preferably, the bottom of the adjusting box is fixedly connected with a fixing plate, the clamping boxes are fixedly connected to two sides of an inner cavity of the fixing plate, pressing rods penetrate through two sides of the fixing plate, one end, extending to the inner cavity of the fixing plate, of each pressing rod penetrates through the clamping box and extends to the inner cavity of the clamping box, the top and the bottom, extending to the inner cavity of the clamping box, of each pressing rod are connected with the top and the bottom of the inner cavity of the clamping box in a sliding mode, and one end of each pressing rod is fixedly connected with a pressing cap.

Preferably, the top fixedly connected with landing slab of flotation tank, the equal fixedly connected with guard plate in both sides at landing slab top, the top of guard plate runs through the fixed plate and extends to the inner chamber of fixed plate to one side fixedly connected with reset spring in guard plate inner chamber, reset spring's one end fixedly connected with cardboard, one side that reset spring was kept away from to the cardboard runs through guard plate and card case in proper order and extends to the inner chamber of card case.

Preferably, the bottom fixedly connected with pulley of flotation tank inner chamber to the surface contact of pulley and connecting wire, the equal fixedly connected with support in both sides that the bottom of drain tank just is located the drain pipe.

Preferably, both sides at landing slab top just are located fixedly connected with baffle between two guard plates to fixedly connected with diaphragm between two baffles.

Preferably, the top of landing slab just is located fixedly connected with power box between two baffles to one side fixedly connected with battery of power box inner chamber bottom, the opposite side fixedly connected with central processing unit of power box inner chamber bottom, the top fixedly connected with dc-to-ac converter of power box.

Preferably, the output end of the solar cell panel is connected with the input end of the inverter, the output end of the inverter is electrically connected with the input end of the storage battery, the output end of the storage battery is electrically connected with the input end of the central processing unit, the output end of the central processing unit is respectively connected with the input end of the first motor and the input end of the electromagnetic valve, the central processing unit is connected with the water quality monitoring probe in a two-way mode, the central processing unit is connected with the wireless transceiver module in a two-way mode, and the wireless transceiver module is connected with the remote control terminal in a two-way mode.

Advantageous effects

The invention provides a buoy for remotely controlling water quality monitoring. Compared with the prior art, the method has the following beneficial effects:

(1) the remote control water quality monitoring buoy is characterized in that a rotating rod is fixedly connected through an output shaft of a first motor, one end of the rotating rod, far away from the first motor, is rotatably connected with one side of an inner cavity of a motor box through a bearing, a wire coil is fixedly connected to the surface of the rotating rod, a connecting wire is fixedly connected to the surface of the wire coil, the bottom end of the connecting wire sequentially penetrates through the motor box and the buoyancy tank and extends to the inner cavity of the buoyancy tank, one end of the connecting wire, extending to the inner cavity of the buoyancy tank, sequentially penetrates through a drainage box and a drainage pipe and extends to the bottom of the drainage pipe, a water pump is fixedly connected to one end, extending to the bottom of the drainage pipe, of the connecting wire, a water outlet of the water pump is communicated with a connecting hose, the top end of the connecting hose sequentially penetrates through the drainage box, the comprehensive and diversified water quality monitoring is improved, the range of monitoring data is improved, the monitoring result is more comprehensive, and a user can remotely control the falling depth of the water pump, so that the water pump monitoring system is safe and reliable.

(2) This buoy for remote control water quality monitoring, the equal fixedly connected with slide rail in both sides through the fixed bottom of the case portion, the bottom of slide rail and the bottom fixed connection of regulating box inner chamber, and sliding connection has the slide between two slide rails, the top fixedly connected with tooth board of slide, the top of tooth board runs through fixed case and regulating box in proper order and extends to the top of regulating box, and the surface swing joint that the tooth board extended to the regulating box top has solar cell panel, one side swing joint at moving part and regulating box top is passed through to one side of solar cell panel bottom, great energy saving, can improve solar cell panel's the utilization ratio to the sunlight, energy-concerving and environment-protective.

(3) This buoy for remote control water quality monitoring, bottom fixedly connected with fixed plate through the regulating box, and the equal fixedly connected with card case in both sides of fixed plate inner chamber, the depression bar has all been run through to the both sides of fixed plate, the one end that the depression bar extends to the fixed plate inner chamber runs through the card case and extends to the inner chamber of card case, and the top and the bottom sliding connection of depression bar extension to card case inner chamber all with card incasement chamber's top and bottom, the one end fixedly connected with press the cap of depression bar, can wholly carry out the dismouting to the regulating box at fixed plate top, convenient to use person carries out the transportation after the dismouting to the device.

(4) This buoy for remote control water quality monitoring runs through motor case and flotation tank in proper order and extends to the inner chamber of flotation tank through the bottom of connecting wire, and the one end that the connecting wire extended to the flotation tank inner chamber runs through drain tank and drain pipe in proper order and extends to the bottom of drain pipe to the one end fixedly connected with water pump that the connecting wire extended to the drain pipe bottom, and the delivery port intercommunication of water pump has coupling hose, can be intelligent adjust the water pump degree of depth, and convenient to use person uses.

(5) This remote control buoy for water quality monitoring, one side fixedly connected with water quality monitoring probe that just is located the motor case through the top of flotation tank inner chamber, the top of baffle just is located water quality monitoring probe and runs through fixed pipe under, the inside fixedly connected with solenoid valve of fixed pipe, can be fine with the moisture discharge at baffle top, safe and reliable.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a cross-sectional view of the buoyancy tank and drainage tank configuration of the present invention;

FIG. 3 is a cross-sectional view of the regulating box and stationary box structure of the present invention;

FIG. 4 is a side view of the web and connecting rod arrangement of the present invention;

FIG. 5 is a cross-sectional view of the fender, retainer plate and cassette structure of the present invention;

fig. 6 is a schematic block diagram of the architecture of the system of the present invention.

In the figure: 1 buoyancy tank, 2 regulating box, 3 drainage tank, 4 drain pipes, 5 clapboards, 6 motor box, 7 first motor, 8 rotating rods, 9 wire coils, 10 connecting wires, 11 water pump, 12 connecting hoses, 13 water quality monitoring probe, 14 fixed pipe, 15 electromagnetic valve, 16 fixed box, 17 second motor, 18 first belt pulley, 19 connecting plate, 20 connecting rod, 21 second belt pulley, 22 belt, 23 gear, 24 slide rail, 25 slide plate, 26 toothed plate, 27 solar cell panel, 28 fixed plate, 29 card box, 30 compression bar, 31 platform board, 32 protection plate, 33 reset spring, 34 card board, 35 pulley, 36 support, 37 baffle, 38 power box, 39 storage battery, 40 central processing unit, 41 inverter, 42 wireless transceiver module, 43 remote control terminal.

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.

Referring to fig. 1-6, the present invention provides two technical solutions:

example one

A buoy for remote control water quality monitoring comprises a floating box 1 and an adjusting box 2, wherein one side of the top of an inner cavity of the adjusting box 2 is fixedly connected with a fixed box 16, one side of the bottom of the inner cavity of the fixed box 16 is fixedly connected with a second motor 17 through a supporting plate, an output shaft of the second motor 17 is fixedly connected with a first belt pulley 18, the other side of the bottom of the inner cavity of the fixed box 16 is fixedly connected with a connecting plate 19, the inside of the connecting plate 19 is rotatably connected with a connecting rod 20 through a bearing, one end of the connecting rod 20 is fixedly connected with a second belt pulley 21, the surface of the first belt pulley 18 and the surface of the second belt pulley 21 are in transmission connection through a belt 22, the other end of the connecting rod 20 is fixedly connected with a gear 23, two sides of the bottom of the fixed box 16 are fixedly connected with slide rails 24, the bottoms of the slide rails, the top of the sliding plate 25 is fixedly connected with a tooth plate 26, the top of the tooth plate 26 sequentially penetrates through the fixed box 16 and the adjusting box 2 and extends to the top of the adjusting box 2, the surface of the tooth plate 26 extending to the top of the adjusting box 2 is movably connected with a solar cell panel 27, one side of the bottom of the solar cell panel 27 is movably connected with one side of the top of the adjusting box 2 through a movable piece, the surface of one side of the tooth plate 26 is meshed with the surface of one side of the gear 23, the output end of the solar cell panel 27 is connected with the input end of the inverter 41, the output end of the inverter 41 is electrically connected with the input end of the storage battery 39, the output end of the storage battery 39 is electrically connected with the input end of the central processor 40, the output end of the central processor 40 is respectively connected with the input end of the first motor 7 and the input end of the electromagnetic valve 15, the model of the central processor 40 is, the central processing unit 40 is in bidirectional connection with the wireless transceiver module 42, the wireless transceiver module 42 is in bidirectional connection with the remote control terminal 43, the bottom of the floating box 1 is communicated with the drainage box 3, the bottom of the drainage box 3 is communicated with the drainage pipe 4, a partition plate 5 is fixedly connected between two sides of an inner cavity of the floating box 1, a motor box 6 is fixedly connected between one side of the top of the partition plate 5 and the top of the inner cavity of the floating box 1, a first motor 7 is fixedly connected to one side of the bottom of the inner cavity of the motor box 6 through a support plate, a rotating rod 8 is fixedly connected to an output shaft of the first motor 7, one end of the rotating rod 8, far away from the first motor 7, is rotatably connected with one side of the inner cavity of the motor box 6 through a bearing, a wire coil 9 is fixedly connected to the surface of the rotating rod 8, a connecting wire 10 is fixedly connected to the surface of the wire, the one end that connecting wire 10 extended to 1 inner chamber of flotation tank runs through drain tank 3 and drain pipe 4 in proper order and extends to the bottom of drain pipe 4, and connecting wire 10 extends to the one end fixedly connected with water pump 11 of drain pipe 4 bottom, the delivery port intercommunication of water pump 11 has coupling hose 12, coupling hose 12's top runs through drain tank 3 in proper order, flotation tank 1 and baffle 5 extend to the top of baffle 5, the top of 1 inner chamber of flotation tank just is located one side fixedly connected with water quality monitoring probe 13 of motor case 6, the top of baffle 5 just is located water quality monitoring probe 13 and runs through fixed pipe 14 under, fixed pipe 14's inside fixedly connected with solenoid valve 15.

Example two

A buoy for remote control water quality monitoring comprises a floating box 1 and an adjusting box 2, wherein the bottom of the floating box 1 is communicated with a drainage box 3, the bottom of the drainage box 3 is communicated with a drainage pipe 4, a partition plate 5 is fixedly connected between two sides of an inner cavity of the floating box 1, a motor box 6 is fixedly connected between one side of the top of the partition plate 5 and the top of the inner cavity of the floating box 1, one side of the bottom of the inner cavity of the motor box 6 is fixedly connected with a first motor 7 through a supporting plate, an output shaft of the first motor 7 is fixedly connected with a rotating rod 8, one end, away from the first motor 7, of the rotating rod 8 is rotatably connected with one side of the inner cavity of the motor box 6 through a bearing, a wire coil 9 is fixedly connected with the surface of the rotating rod 8, a connecting wire 10 is fixedly connected with the surface of the wire coil 9, and the bottom end of the connecting wire 10 sequentially, one end of the connecting line 10, extending to the inner cavity of the floating box 1, sequentially penetrates through the drainage box 3 and the drainage pipe 4 and extends to the bottom of the drainage pipe 4, one end of the connecting line 10, extending to the bottom of the drainage pipe 4, is fixedly connected with a water pump 11, a water outlet of the water pump 11 is communicated with a connecting hose 12, the top end of the connecting hose 12 sequentially penetrates through the drainage box 3, the floating box 1 and the partition plate 5 and extends to the top of the partition plate 5, a water quality monitoring probe 13 is fixedly connected to the top of the inner cavity of the floating box 1 and located on one side of the motor box 6, a fixing pipe 14 penetrates through the top of the partition plate 5 and located right below the water quality monitoring probe 13, and an electromagnetic valve 15 is fixedly connected; the bottom of the adjusting box 2 is fixedly connected with a fixing plate 28, two sides of an inner cavity of the fixing plate 28 are fixedly connected with a clamping box 29, two sides of the fixing plate 28 are penetrated by a pressing rod 30, one end of the pressing rod 30, extending to the inner cavity of the fixing plate 28, penetrates through the clamping box 29 and extends to the inner cavity of the clamping box 29, the top and the bottom of the inner cavity of the clamping box 29, extending to the top and the bottom of the inner cavity of the clamping box 29, are connected with a pressing cap, one end of the pressing rod 30 is fixedly connected with a platform plate 31, two sides of the top of the platform plate 31 are fixedly connected with a protection plate 32, the top of the protection plate 32 penetrates through the fixing plate 28 and extends to the inner cavity of the fixing plate 28, one side of the inner cavity of the protection plate 32 is fixedly connected with a return spring 33, one end of the return spring 33 is fixedly connected with a clamping plate 34, one side, far, bottom fixedly connected with pulley 35 of flotation tank 1 inner chamber, and the surface of pulley 35 and the surface contact of connecting wire 10, the bottom of drain tank 3 and the equal fixedly connected with support 36 in both sides that is located drain pipe 4, the both sides at landing slab 31 top just are located fixedly connected with baffle 37 between two guard plates 32, and fixedly connected with diaphragm between two baffle 37, landing slab 31's top just is located fixedly connected with power box 38 between two baffle 37, and one side fixedly connected with battery 39 of power box 38 inner chamber bottom, the opposite side fixedly connected with central processing unit 40 of power box 38 inner chamber bottom, the top fixedly connected with dc-to-ac converter 41 of power box 38.

When the device is used, a user can place the device at a proper water area position, when the water quality of the water area with a certain depth needs to be monitored, the user can send an instruction at the remote control terminal 43, information is transmitted to the central processing unit 40 through the wireless transceiver module 42, then the central processing unit 40 controls the first motor 7 to work, the first motor 7 drives the rotating rod 8 to rotate when working, and further drives the wire coil 9 to rotate, at the moment, the user can control the connecting wire 10 to wind or loosen on the wire coil 9 by controlling the rotation direction of the first motor 7, so that the submerging depth of the water pump 11 can be controlled, when the water pump is submerged to a proper depth, the user can start the water pump 11 to pump the water with the water depth to the top of the partition plate 5 through the connecting hose 12, at the moment, the staff can monitor the pumped water through the water quality monitoring probe 13 through the remote control terminal 43, will open solenoid valve 15 after monitoring, will discharge the moisture at baffle 5 top through fixed pipe 14, then flow out through drain box 3 and drain pipe 4, and water quality monitoring probe 13 can give central processing unit 40 with the data transfer of monitoring, at this moment, the user just can carry out real-time observation to the quality of water in this waters at remote control terminal 43, and a plurality of light intensity sensor of fixedly connected with on the solar cell panel 27, light intensity data according to each point monitoring contrast, can work by automatic start second motor 17, and then the rotation of first belt pulley 18 has been driven, then the rotation of second piece band pulley 21 has been driven through belt 22, thereby the rotation of gear 23 has been driven through connecting rod 20, tooth board 26 will be driven to move like this, and then drive solar cell panel 27 and move to suitable position.

EXAMPLE III

A method for using a buoy for remotely controlling water quality monitoring comprises the steps that when the buoy is used, a user can place the buoy at a proper water area position, when water quality at a certain depth of the water area needs to be monitored, the user can send an instruction at a remote control terminal 43, information is transmitted to a central processing unit 40 through a wireless transceiver module 42, then the central processing unit 40 controls a first motor 7 to work, the first motor 7 works to drive a rotating rod 8 to rotate, and further the wire coil 9 rotates, the user can control a connecting wire 10 to wind or loosen on the wire coil 9 by controlling the rotation direction of the first motor 7, so that the submergence depth of a water pump 11 can be controlled, when the buoy submerges to a proper depth, the user can start the water pump 11 to pump water at the water depth to the top of a partition plate 5 through a connecting hose 12, at this time, the staff can monitor the water sucked through the remote control terminal 43 by the water quality monitoring probe 13, after monitoring, the electromagnetic valve 15 is opened, the water on the top of the partition board 5 is discharged through the fixing pipe 14, and then flows out through the drainage box 3 and the drainage pipe 4, and the water quality monitoring probe 13 transmits the monitored data to the central processing unit 40, at this time, the user can observe the water quality of the water area in real time at the remote control terminal 43, and the solar panel 27 is fixedly connected with a plurality of light intensity sensors, and the second motor 17 is automatically started to work according to comparison of the light intensity data monitored at each point, so as to drive the rotation of the first belt pulley 18, then the rotation of the second belt pulley 21 is driven by the belt 22, thereby the rotation of the gear 23 is driven by the connecting rod 20, so as to drive the tooth plate 26 to move, thereby driving the solar cell panel 27 to move to a proper position. It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

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 (1)

1. The using method of the remote control buoy for water quality monitoring is characterized in that the remote control buoy for water quality monitoring comprises a floating box (1) and an adjusting box (2), a fixed box (16) is fixedly connected to one side of the top of an inner cavity of the adjusting box (2), a second motor (17) is fixedly connected to one side of the bottom of the inner cavity of the fixed box (16) through a supporting plate, a first belt pulley (18) is fixedly connected to an output shaft of the second motor (17), a connecting plate (19) is fixedly connected to the other side of the bottom of the inner cavity of the fixed box (16), a connecting rod (20) is rotatably connected to the inside of the connecting plate (19) through a bearing, a second belt pulley (21) is fixedly connected to one end of the connecting rod (20), the surface of the first belt pulley (18) is in transmission connection with the surface of the second belt pulley (21) through a belt (22), the other end of the connecting rod (20) is fixedly connected with a gear (23), two sides of the bottom of the fixed box (16) are fixedly connected with sliding rails (24), the bottom of each sliding rail (24) is fixedly connected with the bottom of the inner cavity of the adjusting box (2), a sliding plate (25) is slidably connected between the two sliding rails (24), the top of each sliding plate (25) is fixedly connected with a toothed plate (26), the top of each toothed plate (26) sequentially penetrates through the fixed box (16) and the adjusting box (2) and extends to the top of the adjusting box (2), the surface of each toothed plate (26) extending to the top of the adjusting box (2) is movably connected with a solar cell panel (27), one side of the bottom of each solar cell panel (27) is movably connected with one side of the top of the adjusting box (2) through a moving part, and the surface of one side of each toothed plate (26) is meshed with the surface of one side of the gear (, the output end of the solar cell panel (27) is connected with the input end of the inverter (41), the output end of the inverter (41) is electrically connected with the input end of the storage battery (39), the output end of the storage battery (39) is electrically connected with the input end of the central processing unit (40), the output end of the central processing unit (40) is respectively connected with the input end of the first motor (7) and the input end of the electromagnetic valve (15), the central processing unit (40) and the water quality monitoring probe (13) are connected in a bidirectional mode, the central processing unit (40) and the wireless transceiver module (42) are connected in a bidirectional mode, the wireless transceiver module (42) and the remote control terminal (43) are connected in a bidirectional mode, the bottom of the floating box (1) is communicated with the drainage box (3), and the bottom of the drainage box (3) is communicated with the drainage pipe (4), fixedly connected with baffle (5) between the both sides of flotation tank (1) inner chamber, fixedly connected with motor case (6) between one side at baffle (5) top and the top of flotation tank (1) inner chamber, the first motor (7) of backup pad fixedly connected with are passed through to one side of motor case (6) inner chamber bottom, the output shaft fixedly connected with dwang (8) of first motor (7), dwang (8) are kept away from the one end of first motor (7) with one side of motor case (6) inner chamber is passed through the bearing and is rotated and be connected, the fixed surface of dwang (8) is connected with drum (9), the fixed surface of drum (9) is connected with connecting wire (10), the bottom of connecting wire (10) runs through in proper order motor case (6) with flotation tank (1) and extend to the inner chamber of flotation tank (1), connecting wire (10) extend to the one end of flotation tank (1) inner chamber runs through in proper order drainage tank (3) ) The water quality monitoring device comprises a water drainage pipe (4), a connecting line (10), a water pump (11), a connecting hose (12), a water outlet of the water pump (11), a water quality monitoring probe (13), a fixing pipe (14) and an electromagnetic valve (15), wherein the water drainage pipe (4) extends to the bottom of the water drainage pipe (4), the connecting line (10) extends to one end of the bottom of the water drainage pipe (4) and is fixedly connected with the water pump (11), the water outlet of the water pump (11) is communicated with the connecting hose (12), the top end of the connecting hose (12) sequentially penetrates through the water drainage tank (3), the buoyancy tank (1) and the partition plate (5) and extends to the top of the partition plate (5), the top of the inner cavity of the buoyancy tank (1) is fixedly connected with the water quality monitoring probe (13) and is positioned under; when the buoy is used, a user can place the buoy for remote control water quality monitoring at a proper water area position, when the water quality of a certain depth of the water area needs to be monitored, the user can send an instruction at a remote control terminal (43), information is transmitted to a central processing unit (40) through a wireless transceiver module (42), then the central processing unit (40) can control a first motor (7) to work, the first motor (7) works to drive a rotating rod (8) to rotate, further the wire coil (9) is driven to rotate, at the moment, the user can control a connecting wire (10) to be wound or loosened on the wire coil (9) by controlling the rotation direction of the first motor (7), so that the submerging depth of a water pump (11) can be controlled, when the water pump is submerged to a proper depth, the user can start the water pump (11) to pump the water of the proper depth to the top of the partition plate (5) through a connecting hose (12), at the moment, a worker can monitor the pumped water through the water quality monitoring probe (13) through the remote control terminal (43), the electromagnetic valve (15) is opened after monitoring is finished, the water at the top of the partition plate (5) is discharged through the fixed pipe (14), then the water flows out through the drainage box (3) and the drainage pipe (4), the water quality monitoring probe (13) transmits monitored data to the central processing unit (40), at the moment, the user can observe the water quality of the water area in real time at the remote control terminal (43), the solar cell panel (27) is fixedly connected with a plurality of light intensity sensors, comparison is carried out according to the light intensity data monitored at each point, the second motor (17) can be automatically started to work, so that the rotation of the first belt pulley (18) is driven, and then the rotation of the second belt pulley (21) is driven through the belt (22), therefore, the connecting rod (20) drives the gear (23) to rotate, so that the toothed plate (26) is driven to move, and the solar cell panel (27) is driven to move to a proper position.

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