CN218212213U - Equipment for monitoring and collecting mobile source pollutants - Google Patents

Abstract

The utility model discloses an equipment for removing source pollutant monitoring and collection relates to and removes source pollutant monitoring and collection technical field, and in-process for solving current device and using only can monitor the pollution source, can not carry out sample acquisition to the pollution source, the problem of the follow-up analysis that is not convenient for handles. The gas sampling pump is embedded into the upper end of the main body of the rotor unmanned aerial vehicle, one side of the front end of the gas sampling pump is provided with a gas inlet, and the other side of the front end of the gas sampling pump is provided with an exhaust pipe; the gas sampling pump is arranged above the gas sampling pump, the front end of the gas sampling pump is provided with four electromagnetic valves, and the rear ends of the four electromagnetic valves are provided with sampling bags; a contaminant detection module mounted at a side of the gas sampling pump.

Description

Equipment for monitoring and collecting mobile source pollutants

Technical Field

The utility model relates to a remove source pollutant monitoring and collection technical field, specifically be an equipment for removing source pollutant monitoring and collection.

Background

The pollutant discharge and amplification of the workshop section are carried out through an overhead discharge port, a pollution source can move along with the action of wind power, and an unmanned aerial vehicle device is generally adopted to monitor the pollution source;

the application number is CN113371183A, namely, the system and the method for monitoring the emission of the elevated point source pollutants based on the multi-rotor unmanned aerial vehicle comprise the following steps: the system comprises a multi-rotor unmanned aerial vehicle, a pollutant acquisition and detection module, a wind measurement module, a data transmission module and a remote control terminal; the multi-rotor unmanned aerial vehicle is used as a flight platform and carries a pollutant acquisition and detection module, a wind measurement module and a data transmission module; the pollutant collecting and detecting module and the wind measuring module are connected with one end of the data transmission module; the other end of the data transmission module is connected with the remote control terminal.

In the using process of the device, only a pollution source can be monitored, and the sample collection of the pollution source cannot be carried out, so that the subsequent analysis and treatment are inconvenient; we have therefore proposed an apparatus for mobile source contaminant monitoring and collection in order to address the problems set out above.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an equipment for removing source pollutant monitoring and collection to solve the in-process that the current device that proposes in the above-mentioned background art was using, only can monitor the pollution source, can not carry out sample acquisition to the pollution source, the problem of the follow-up analysis and treatment of being not convenient for.

In order to achieve the above object, the utility model provides a following technical scheme: a device for monitoring and collecting moving source pollutants comprises a rotor wing unmanned aerial vehicle main body, wherein a pan-tilt camera is mounted at the lower end of the rotor wing unmanned aerial vehicle main body;

further comprising:

the gas sampling pump is embedded into the upper end of the main body of the rotor unmanned aerial vehicle, one side of the front end of the gas sampling pump is provided with a gas inlet, and the other side of the front end of the gas sampling pump is provided with an exhaust pipe;

the gas sampling pump is arranged above the gas sampling pump, the front end of the gas sampling pump is provided with four electromagnetic valves, and the rear ends of the four electromagnetic valves are provided with sampling bags;

a contaminant detection module mounted at one side of the gas sampling pump.

Preferably, the exhaust pipe is communicated with the four electromagnetic valves through the shunt pipes.

Preferably, the front end of the sampling bag is connected with the electromagnetic valve through a soft rubber pipe joint, a manual air inlet valve is installed on the soft rubber pipe joint, and a manual air outlet valve is installed at the front end of the sampling bag.

Preferably, a filter screen is installed inside the air inlet.

Preferably, the upper surface of the protective box is provided with a box cover, and the periphery of the box cover is connected with the protective box through a hasp.

Preferably, the internally mounted of rotor unmanned aerial vehicle main part has singlechip chip, wireless data transmission module, solenoid valve control module, GPS orientation module and power module, the internally mounted of blast pipe and gas sampling pump junction has baroceptor, pollutant detection module, GPS orientation module, cloud platform camera and power module's output all with singlechip chip's input electric connection, singlechip chip passes through wireless data transmission module and remote control terminal electric connection, singlechip chip's output passes through solenoid valve control module and solenoid valve electric connection.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model discloses a set up gaseous sampling pump and four sample bags on the device, when unmanned aerial vehicle reachs the source position of pollution, at first detect the record by pollutant detection module to pollutant composition and concentration, later by one of them solenoid valve opening on the single chip microcomputer chip through solenoid valve control module controlling means, and drive the operation of gaseous sampling pump, with this leading-in sample bag of pollution source, when baroceptor detected pressure reachs the threshold value, then feedback signal closes the solenoid valve to single chip microcomputer chip, solenoid valve and sample bag respectively are equipped with four, can be at the monitoring in-process, detect the sample to the source pollutant of moving everywhere, high efficiency, the in-process that has solved current device and is using, only can monitor the pollution source, the unable sample collection that carries out to the pollution source, be not convenient for follow-up analysis processes's problem.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the internal structure of the protective box of the present invention;

FIG. 3 is a schematic diagram of the present invention;

in the figure: 1. a rotor unmanned aerial vehicle body; 2. a pan-tilt camera; 3. a gas sampling pump; 4. an air inlet; 5. a filter screen; 6. a contaminant detection module; 7. a protective box; 8. a box cover; 9. a hasp; 10. an exhaust pipe; 101. a shunt tube; 11. an electromagnetic valve; 12. a sampling bag; 13. a flexible glue pipe joint; 14. a manual air intake valve; 15. a manual exhaust valve; 16. a single chip processor chip; 17. a wireless data transmission module; 18. a solenoid valve control module; 19. a GPS positioning module; 20. a power supply module; 21. an air pressure sensor.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-3, the present invention provides an embodiment: a device for monitoring and collecting moving source pollutants comprises a rotor wing unmanned aerial vehicle main body 1, wherein a pan-tilt camera 2 is installed at the lower end of the rotor wing unmanned aerial vehicle main body 1;

further comprising:

the gas sampling pump 3 is embedded into the upper end of the main body 1 of the rotor unmanned aerial vehicle, one side of the front end of the gas sampling pump 3 is provided with a gas inlet 4, and the other side of the front end of the gas sampling pump 3 is provided with an exhaust pipe 10;

the gas sampling device comprises a protective box 7, a gas sampling pump 3, four electromagnetic valves 11, four sampling bags 12 and a gas sampling pump, wherein the protective box 7 is arranged above the gas sampling pump 3, the electromagnetic valves 11 are arranged at the front end of the protective box 7, and the sampling bags 12 are arranged at the rear ends of the four electromagnetic valves 11;

and a contaminant detection module 6 installed at one side of the gas sampling pump 3.

Referring to fig. 2, the exhaust pipe 10 is connected to four electromagnetic valves 11 through shunt pipes 101, and during sampling, the single chip microcomputer 16 can control different electromagnetic valves 11 to open through the electromagnetic valve control module 18, and guide the pollution sources at different positions into different sampling bags 12 in cooperation with the gas sampling pump 3 to perform classified sampling.

Referring to fig. 2, the front end of the sampling bag 12 is connected to the electromagnetic valve 11 through the flexible rubber pipe joint 13, the flexible rubber pipe joint 13 is provided with the manual air inlet valve 14, the front end of the sampling bag 12 is provided with the manual air outlet valve 15, and when the sampling bag 12 is dismounted, the manual air inlet valve 14 and the manual air outlet valve 15 need to be ensured to be in a closed state to avoid air leakage when the sampling bag is dismounted.

Referring to fig. 1, a filter screen 5 is installed inside the air inlet 4, and the filter screen 5 can prevent the occurrence of pipeline blockage caused by the entering of extra-large particle dirt into the gas sampling pump 3.

Referring to fig. 1, a box cover 8 is mounted on the upper surface of a protective box 7, the periphery of the box cover 8 is connected with the protective box 7 through hasps 9, the protective box 7 can protect an internal sampling bag 12, and the box cover 8 can ensure the sealing performance of a protective net.

Please refer to fig. 1 and fig. 3, the internally mounted of rotor unmanned aerial vehicle main part 1 has single chip microcomputer chip 16, wireless data transmission module 17, solenoid valve control module 18, GPS positioning module 19 and power module 20, the internally mounted of the junction of exhaust pipe 10 and gas sampling pump 3 has pressure sensor 21, pollutant detection module 6, GPS positioning module 19, the output of pan tilt camera 2 and power module 20 all with single chip microcomputer chip 16's input electric connection, single chip microcomputer chip 16 passes through wireless data transmission module 17 and remote control terminal electric connection, single chip microcomputer chip 16's output passes through solenoid valve control module 18 and solenoid valve 11 electric connection, power module 20 provides the electric energy for the internal component, single chip microcomputer chip 16 has realized the data transmission interaction, GPS positioning module 19 can acquire unmanned aerial vehicle current position, conveniently monitor and gather to the pollution source position.

The working principle is as follows: during the use, send the signal by remote control terminal to the wireless data transmission module 17 in rotor unmanned aerial vehicle main part 1, through the operation of chip on chip 16 controlling means, device built-in GPS orientation module 19, can acquire the current position in real time, conveniently monitor and gather to the pollution source position, when unmanned aerial vehicle reachs the pollution source position, at first carry out the detection record to pollutant composition and concentration by pollutant detection module 6, later by chip on chip 16 through one of them solenoid valve 11 on the solenoid valve controlling means 18 controlling means, and drive gas sampling pump 3 operation, lead into the sampling bag 12 with this pollution source, when baroceptor 21 detected pressure reached the threshold value, then feedback signal to chip on chip 16, close solenoid valve 11, solenoid valve 11 and sampling bag 12 respectively are equipped with four, can be in a monitoring process, detect the sample to the source pollutant of moving everywhere, high efficiency, after the sample, the staff can open protective housing 7, under the condition of guaranteeing that manual admission valve 14 and manual discharge valve 15 of sampling bag 12 are in the closed state, the hose nipple 13 and the solenoid valve 11 separation of sampling bag 12.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (6)

1. A device for monitoring and collecting moving source pollutants comprises a rotor wing unmanned aerial vehicle main body (1), wherein a pan-tilt camera (2) is installed at the lower end of the rotor wing unmanned aerial vehicle main body (1);

the method is characterized in that: further comprising:

the rotor unmanned aerial vehicle comprises a rotor unmanned aerial vehicle body (1), a gas sampling pump (3) embedded into the upper end of the rotor unmanned aerial vehicle body (1), wherein a gas inlet (4) is formed in one side of the front end of the gas sampling pump (3), and a gas exhaust pipe (10) is installed on the other side of the front end of the gas sampling pump (3);

the gas sampling device comprises a protective box (7) which is arranged above the gas sampling pump (3), wherein the front end of the protective box (7) is provided with four electromagnetic valves (11), and the rear ends of the four electromagnetic valves (11) are provided with sampling bags (12);

a contaminant detection module (6) mounted on one side of the gas sampling pump (3).

2. The apparatus of claim 1 for mobile source contaminant monitoring and collection, wherein: the exhaust pipe (10) is communicated with the four electromagnetic valves (11) through the shunt pipes (101).

3. The apparatus for mobile source contaminant monitoring and collection according to claim 1, wherein: the front end of the sampling bag (12) is connected with the electromagnetic valve (11) through a soft rubber pipe joint (13), a manual air inlet valve (14) is installed on the soft rubber pipe joint (13), and a manual air outlet valve (15) is installed at the front end of the sampling bag (12).

4. The apparatus for mobile source contaminant monitoring and collection according to claim 1, wherein: and a filter screen (5) is arranged in the air inlet (4).

5. The apparatus of claim 1 for mobile source contaminant monitoring and collection, wherein: the upper surface mounting of protective housing (7) has case lid (8), be connected with protective housing (7) through hasp (9) around case lid (8).

6. The apparatus of claim 1 for mobile source contaminant monitoring and collection, wherein: the utility model discloses a rotor unmanned aerial vehicle, including rotor unmanned aerial vehicle main part (1), the internally mounted of blast pipe (10) has single chip microcomputer chip (16), wireless data transmission module (17), solenoid valve control module (18), GPS orientation module (19) and power module (20), the internally mounted of blast pipe (10) and gas sampling pump (3) junction has baroceptor (21), pollutant detection module (6), GPS orientation module (19), cloud platform camera (2) and power module (20) the output all with the input electric connection of single chip microcomputer chip (16), single chip microcomputer chip (16) are through wireless data transmission module (17) and remote control terminal electric connection, the output of single chip microcomputer chip (16) passes through solenoid valve control module (18) and solenoid valve (11) electric connection.

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