CN214373587U - Plateau water chemistry monitoring devices - Google Patents

Abstract

A high-altitude water chemical monitoring device, comprising a monitoring main body box, a water tank, a solar panel, an electric air pump, a water pump, a central processor, a sampling bottle, a pressure sensor, a cleaning pipe, a detection device and a battery; the connecting pipe is arranged at the gas outlet of the electric air pump The sampling bottle is arranged on the connecting pipe, and the sampling tube is arranged at the bottom of the sampling bottle; the detection device is arranged on the first fixing plate, and the liquid inlet pipe is arranged on the sampling bottle and communicated with the detection device; the central processing unit is arranged in the monitoring main body box The first control valve and the second control valve are connected to the central processor in communication; the liquid inlet end of the water pump is connected to the water tank; the cleaning pipe is arranged at the liquid outlet end of the water pump and communicated with the sampling bottle; the third control valve is arranged in the cleaning pipe and communicate with the central processor. The utility model facilitates comparison of detection data, prevents samples from influencing each other, improves detection accuracy, is remotely controlled by a central processor, automatically performs sampling detection, reduces labor intensity of staff, and is simpler.

Description

Plateau water chemistry monitoring devices

Technical Field

The utility model relates to a water quality monitoring equipment technical field especially relates to a plateau water chemistry monitoring devices.

Background

The water quality monitoring is a process for monitoring and measuring the types of pollutants in the water body, the concentrations and the variation trends of various pollutants and evaluating the water quality condition. The monitoring range is very wide, and the monitoring range comprises uncontaminated and contaminated natural water (rivers, lakes, seas and underground water), various industrial drainage and the like. The main monitoring projects can be divided into two main categories: one is a comprehensive index reflecting the water quality conditions, such as temperature, chroma, turbidity, pH value, conductivity, suspended matters, dissolved oxygen, chemical oxygen demand, biochemical oxygen demand and the like; the other is some toxic substances, such as phenol, cyanogen, arsenic, lead, chromium, cadmium, mercury, organic pesticides and the like. In order to objectively evaluate the conditions of the water quality of rivers and oceans, except for the monitoring projects, the flow velocity and flow are sometimes measured, at present, when plateau water is monitored, workers are usually required to go to appointed rivers or lakes to take water and carry the water back to the detection, the water quality is analyzed through detection results, and regular or irregular sampling detection is required; the prior publication No. CN202020052943.X is a device for monitoring chemical pollution factors of surface water; the device can lead underground water to different collecting boxes through an electronic valve, can respectively monitor the pH value and the temperature of the underground water through a pH monitoring device and a temperature monitoring device, can heat and gasify the underground water, and can respectively detect the contents of organic matters and heavy metals in the underground water through a gas chromatography device and an atomic absorption spectroscopy device, so that the device can integrate multiple detections of the underground water into a whole, realizes integrated control, simplifies the complex flow of detecting different types of the underground water, greatly shortens the detection time, but still needs a worker to pour the taken sample into the device, has complicated sampling, cannot simultaneously detect and compare different areas, cannot automatically detect water at regular or irregular intervals, has poor monitoring effect, and does not have an automatic cleaning function, residual water can affect the accuracy of the detection.

SUMMERY OF THE UTILITY MODEL

Objects of the invention

For solving the technical problem that exists among the background art, the utility model provides a plateau water chemistry monitoring devices, through central treater control air pump work and sample and detect different regions through the multiunit sampling tube, convenient contrast detection data, acquire clean water from the water tank through the water pump and wash sampling bottle and sampling tube, prevent that the sample from influencing each other, improve and detect the precision, simultaneously through central treater remote control, carry out the sample detection automatically, reduce staff intensity of labour, it is simpler.

(II) technical scheme

The utility model provides a plateau water chemistry monitoring device, which comprises a monitoring main body box, a water tank, a solar panel, a supporting frame, an electric air pump, a water pump, a central processor, a connecting pipe, a sampling bottle, a pressure sensor, a pressing plate, a spring, a suspension ball, a pull rope, a cleaning pipe, a detection device, a first fixed plate, a liquid inlet pipe, a first control valve, a second control valve, a sampling pipe, a third control valve and a storage battery;

the bottom of the monitoring main body box is provided with a fixing frame for fixing, the water tank is arranged on the monitoring main body box, and the solar panel is arranged on the water tank through a supporting frame; the monitoring main body box is provided with a second fixing plate, and the storage battery is arranged on the second fixing plate and is electrically connected with the solar panel; the electric air pump is arranged on the second fixing plate, and the connecting pipe is arranged at the air outlet end of the electric air pump; the sampling bottle is arranged on the connecting pipe, the sampling pipe is arranged at the bottom of the sampling bottle and penetrates through the monitoring main body box to extend to the periphery, and a liquid inlet end of the sampling pipe is provided with a filtering piece for filtering impurities; the first fixing plate is arranged on the monitoring main body box, the detection device is arranged on the first fixing plate, and the liquid inlet pipe is arranged on the sampling bottle and communicated with the detection device; the central processor is arranged on the monitoring main body box, the liquid inlet pipe is provided with a first control valve, the sampling pipe is provided with a second control valve, and the first control valve and the second control valve are in communication connection with the central processor; the pressure sensor is arranged on the sampling bottle, the pressure plate is connected with the pressure sensor through a spring, and the suspension ball is arranged on the sampling bottle and is positioned below the pressure plate through a pull rope;

the water pump is arranged on the second fixing plate, and the liquid inlet end of the water pump is communicated with the water tank; the cleaning pipe is arranged at the liquid outlet end of the water pump, communicated with the sampling bottle and positioned below the pressing plate; the third control valve is arranged on the cleaning pipe and is in communication connection with the central processor.

Preferably, the number of the detection devices, the sampling bottles and the sampling tubes is two.

Preferably, the detection device is provided with a liquid outlet pipe for discharging the detection sample.

Preferably, the filter element is removably attached to the sampling tube.

Preferably, the sampling tube is a hose.

Preferably, the device also comprises a box door; the box door is rotatably arranged on the monitoring main box, and the box door and the monitoring main box are directly provided with sealing gaskets.

Preferably, a control panel is arranged on one side of the box door close to the detection device, and the control panel is in communication connection with the central processor.

Preferably, the central processor is provided with a network communication component.

Compared with the prior art, the above technical scheme of the utility model following profitable technological effect has: when the device works, the solar panel supplies power to the storage battery, the storage battery provides power for the device, when sampling is needed, the first control valve and the third control valve are closed, the second control valve is opened, the electric air pump works and samples, water to be detected enters the sampling tube and the sampling bottle after being filtered by the filter piece, then the suspension ball props against the pressing plate and compresses the spring, when the numerical value of the pressure sensor reaches a preset value, the second control valve is closed, the electric air pump stops working, the first control valve is opened at the moment, the sample flows into the detection device for detection, after the detection is finished, the first control valve, the second control valve and the third control valve are opened, the water pump works and injects clean water, and then the sampling tube, the sampling tube and the detection device are cleaned; the working personnel can operate the device through the remote control center processor; the utility model discloses a work of central treater control air pump and through the multiunit sampling tube to take a sample and detect different regions, convenient contrast detection data, acquire clean water from the water tank through the water pump and wash sampling bottle and sampling tube, prevent that the sample from influencing each other, improve and detect the precision, simultaneously through central treater remote control, carry out the sample detection voluntarily, reduce staff intensity of labour, it is simpler.

Drawings

Fig. 1 is a schematic perspective view of a plateau water chemistry monitoring device provided by the present invention.

Fig. 2 is a schematic sectional structural view of a plateau water chemistry monitoring device provided by the present invention.

Fig. 3 is a schematic sectional structural diagram (right side view) of a plateau water chemistry monitoring device provided by the present invention.

Fig. 4 is a partially enlarged schematic view of a position a in the plateau water chemistry monitoring device provided by the present invention.

Reference numerals: 1. monitoring the main body box; 2. a fixed mount; 3. a water tank; 4. a solar panel; 5. a support frame; 6. an electric air pump; 7. a water pump; 8. a central processor; 9. a connecting pipe; 10. sampling a bottle; 11. a pressure sensor; 12. pressing a plate; 13. a spring; 14. suspending the ball; 15. pulling a rope; 16. cleaning the tube; 17. a detection device; 18. a first fixing plate; 19. a liquid inlet pipe; 20. a first control valve; 21. a second control valve; 22. a sampling tube; 23. a filter member; 24. a third control valve; 25. a box door; 26. a second fixing plate; 27. and (4) a storage battery.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in detail with reference to the accompanying drawings. It should be understood that the description is intended to be illustrative only and is not intended to limit the scope of the present invention. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.

As shown in fig. 1-4, the utility model provides a plateau hydrochemistry monitoring device, including monitoring main part case 1, water tank 3, solar panel 4, support frame 5, electronic air pump 6, water pump 7, central processing unit 8, connecting pipe 9, sampling bottle 10, pressure sensor 11, clamp plate 12, spring 13, suspension ball 14, stay cord 15, scavenge pipe 16, detection device 17, first fixed plate 18, feed liquor pipe 19, first control valve 20, second control valve 21, sampling tube 22, third control valve 24 and battery 27;

the bottom of the monitoring main body box 1 is provided with a fixing frame 2 for fixing, the water tank 3 is arranged on the monitoring main body box 1, and the solar panel 4 is arranged on the water tank 3 through a supporting frame 5; the monitoring main body box 1 is provided with a second fixing plate 26, and the storage battery 27 is arranged on the second fixing plate 26 and is electrically connected with the solar panel 4; the electric air pump 6 is arranged on the second fixing plate 26, and the connecting pipe 9 is arranged at the air outlet end of the electric air pump 6; the sampling bottle 10 is arranged on the connecting pipe 9, the sampling pipe 22 is arranged at the bottom of the sampling bottle 10 and penetrates through the monitoring main body box 1 to extend to the periphery, and the liquid inlet end of the sampling pipe 22 is provided with a filtering piece 23 for filtering impurities; the first fixing plate 18 is arranged on the monitoring main body box 1, the detection device 17 is arranged on the first fixing plate 18, and the liquid inlet pipe 19 is arranged on the sampling bottle 10 and communicated with the detection device 17; the central processor 8 is arranged on the monitoring main body box 1, the liquid inlet pipe 19 is provided with a first control valve 20, the sampling pipe 22 is provided with a second control valve 21, and the first control valve 20 and the second control valve 21 are in communication connection with the central processor; the pressure sensor 11 is arranged on the sampling bottle 10, the pressure plate 12 is connected with the pressure sensor 11 through the spring 13, and the floating ball 14 is arranged on the sampling bottle 10 and is positioned below the pressure plate 12 through the pull rope 15;

the water pump 7 is arranged on the second fixing plate 26, and the liquid inlet end of the water pump 7 is communicated with the water tank 3; the cleaning pipe 16 is arranged at the liquid outlet end of the water pump 7, communicated with the sampling bottle 10 and positioned below the pressure plate 12; a third control valve 24 is provided on the cleaning tube 16 and is in communication with the central processor 8.

In an alternative embodiment, the number of the detection devices 17, the sampling bottles 10 and the sampling tubes 22 is two, and the two groups are used for simultaneously obtaining water quality samples in different areas and performing detection.

In an alternative embodiment, the detection device 17 is provided with a drain for draining the test sample.

In an alternative embodiment, the filter element 23 is detachably connected to the sampling tube 22, so that the filter element 23 can be cleaned, maintained and replaced conveniently, and the sampling is smooth.

In an alternative embodiment, sampling tube 22 is a flexible tube for easy placement.

In an alternative embodiment, a door 25 is also included; the box door 25 is rotatably disposed on the monitoring main body box 1, and the box door 25 and the monitoring main body box 1 are directly provided with a sealing gasket.

In an alternative embodiment, a control panel is provided on the door 25 on a side thereof adjacent the detection device 17, and the control panel is communicatively connected to the central processor for commissioning the device during installation.

In an alternative embodiment, the central processor 8 is provided with a network communication component for data transmission and remote control.

The utility model discloses in, in operation, solar panel 4 supplies power for battery 27, battery 27 provides the power for the device, when needs take a sample, first control valve 20 third control valve 24 closes, second control valve 21 opens, the work of electronic air pump 6 is and take a sample, the water that awaits measuring gets into in sampling tube 22 and the sampling bottle 10 after filtering through filter piece 23, later suspension ball 14 supports clamp plate 12 and compression spring 13, when pressure sensor 11's numerical value reaches the default, second control valve 21 closes, later electronic air pump 6 stops working, first control valve 20 opens this moment, flow into detection device 17 through the sample and detect, after the detection, first control valve 20, second control valve 21 and third control valve 24 open, water pump 7 works and pours into the clear water into, wash sampling bottle 10 afterwards, sampling tube 22 and detection device 17; the working personnel can operate the device through the remote control center processor; the utility model discloses a work of central treater control air pump and through the multiunit sampling tube to take a sample and detect different regions, convenient contrast detection data, acquire clean water from the water tank through the water pump and wash sampling bottle and sampling tube, prevent that the sample from influencing each other, improve and detect the precision, simultaneously through central treater remote control, carry out the sample detection voluntarily, reduce staff intensity of labour, it is simpler.

It is to be understood that the above-described embodiments of the present invention are merely illustrative of or explaining the principles of the invention and are not to be construed as limiting the invention. Therefore, any modification, equivalent replacement, improvement and the like made without departing from the spirit and scope of the present invention should be included in the protection scope of the present invention. Further, it is intended that the appended claims cover all such variations and modifications as fall within the scope and boundaries of the appended claims or the equivalents of such scope and boundaries.

Claims (8)

1. A high altitude hydrochemistry monitoring device is characterized by comprising a monitoring main body box (1), a water tank (3), a solar panel (4), a support frame (5), an electric air pump (6), a water pump (7), a central processor (8), a connecting pipe (9), a sampling bottle (10), a pressure sensor (11), a pressing plate (12), a spring (13), a suspension ball (14), a pull rope (15), a cleaning pipe (16), a detection device (17), a first fixing plate (18), a liquid inlet pipe (19), a first control valve (20), a second control valve (21), a sampling pipe (22), a third control valve (24) and a storage battery (27);

the bottom of the monitoring main body box (1) is provided with a fixing frame (2) for fixing, the water tank (3) is arranged on the monitoring main body box (1), and the solar panel (4) is arranged on the water tank (3) through a supporting frame (5); a second fixing plate (26) is arranged on the monitoring main body box (1), and a storage battery (27) is arranged on the second fixing plate (26) and is electrically connected with the solar panel (4); the electric air pump (6) is arranged on the second fixing plate (26), and the connecting pipe (9) is arranged at the air outlet end of the electric air pump (6); the sampling bottle (10) is arranged on the connecting pipe (9), the sampling pipe (22) is arranged at the bottom of the sampling bottle (10) and penetrates through the monitoring main body box (1) to extend to the periphery, and the liquid inlet end of the sampling pipe (22) is provided with a filtering piece (23) for filtering impurities; the first fixing plate (18) is arranged on the monitoring main body box (1), the detection device (17) is arranged on the first fixing plate (18), and the liquid inlet pipe (19) is arranged on the sampling bottle (10) and communicated with the detection device (17); the central processor (8) is arranged on the monitoring main body box (1), the liquid inlet pipe (19) is provided with a first control valve (20), the sampling pipe (22) is provided with a second control valve (21), and the first control valve (20) and the second control valve (21) are in communication connection with the central processor; the pressure sensor (11) is arranged on the sampling bottle (10), the pressure plate (12) is connected with the pressure sensor (11) through a spring (13), and the suspension ball (14) is arranged on the sampling bottle (10) through a pull rope (15) and is positioned below the pressure plate (12);

the water pump (7) is arranged on the second fixing plate (26), and the liquid inlet end of the water pump (7) is communicated with the water tank (3); the cleaning pipe (16) is arranged at the liquid outlet end of the water pump (7), is communicated with the sampling bottle (10) and is positioned below the pressure plate (12); a third control valve (24) is disposed on the cleaning tube (16) and is communicatively connected to the central processor (8).

2. The plateau water chemistry monitoring device as claimed in claim 1, characterised in that the number of detection devices (17), sampling bottles (10) and sampling tubes (22) is two.

3. The plateau water chemistry monitoring device as claimed in claim 1, characterised in that the detection device (17) is provided with a drain for draining the test sample.

4. The plateau water chemistry monitoring device of claim 1, wherein the filter element (23) is removably connected to the sampling tube (22).

5. The plateau water chemistry monitoring device of claim 1, wherein the sampling tube (22) is a flexible tube.

6. The high altitude water chemistry monitoring device of claim 1, further comprising a chamber door (25); the box door (25) is rotatably arranged on the monitoring main body box (1), and the box door (25) and the monitoring main body box (1) are directly provided with sealing gaskets.

7. The plateau water chemistry monitoring device as claimed in claim 1, wherein a control panel is provided on the side of the box door (25) near the detection device (17), and the control panel is in communication with the central processor.

8. The plateau water chemistry monitoring device of claim 1, wherein the central processor (8) is provided with a network communication component.

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