CN217624114U - Unmanned aerial vehicle monitoring devices that gas pollution used - Google Patents

Abstract

The utility model discloses an unmanned aerial vehicle monitoring devices that gaseous pollution used belongs to the unmanned aerial vehicle field, an unmanned aerial vehicle monitoring devices that gaseous pollution used, including the unmanned aerial vehicle body, two carriages of the bottom fixedly connected with of unmanned aerial vehicle body, two sliding connection has the casing between the relative one side of carriage, shells inner wall's bottom is provided with the collection subassembly, the inside drive assembly that is provided with of casing, drive assembly's drive end is connected with the output of collection subassembly, the back of casing is provided with storage assembly, and through the setting of collection subassembly, the gaseous collection of pollution of being convenient for, through the setting of drive assembly, be convenient for drive collection subassembly and storage assembly and be connected, and then form gas collection work, and through storage assembly's setting, not only be convenient for gaseous pollution deposit, satisfied depositing of different kinds of gaseous pollutants moreover, improve the functional that gaseous pollution collected.

Description

Unmanned aerial vehicle monitoring devices that gas pollution used

Technical Field

The utility model relates to an unmanned aerial vehicle field, more specifically say, relate to an unmanned aerial vehicle monitoring devices that gas pollution used.

Background

The unmanned plane is called unmanned plane for short, and is an unmanned plane operated by radio remote control equipment and a self-contained program control device. The airplane has no cockpit, but is provided with an automatic pilot, a program control device and other equipment, and during recovery, the airplane can automatically land in the same way as the landing process of a common airplane, and can also be recovered by a parachute or a barrier net for remote control.

Through patent search, the application number: CN202020348025.1 covers in gas collection device top through left guard plate and right guard plate, can protect gas collection device under the condition that can not cause the influence to gas collection device's work, improves the safety in utilization, however at the in-process of in-service use, can't classify to the polluted gas of different positions and collect and store to the pollution degree that the staff can't accurate monitoring is gaseous.

SUMMERY OF THE UTILITY MODEL

1. Technical problem to be solved

To the problem that exists among the prior art, the utility model aims to provide an unmanned aerial vehicle monitoring devices that gas pollution used, through the setting of gathering the subassembly, the gaseous collection of being convenient for to and through the setting of storage subassembly, not only be convenient for deposit of gaseous pollutants, satisfied depositing of different kinds of gaseous pollutants moreover, avoided can not carrying out classified collection and storage to the gaseous pollutants of different positions to as for the problem of the unable accurate monitoring gas body pollution degree of staff.

2. Technical scheme

In order to solve the above problems, the utility model adopts the following technical proposal.

An unmanned aerial vehicle monitoring device for gas pollution comprises an unmanned aerial vehicle body, wherein two sliding frames are fixedly connected to the bottom of the unmanned aerial vehicle body, a shell is connected between two opposite sides of the sliding frames in a sliding manner, an acquisition assembly is arranged at the bottom of the inner wall of the shell, a driving assembly is arranged in the shell, the driving end of the driving assembly is connected with the output end of the acquisition assembly, a storage assembly is arranged on the back surface of the shell and comprises an opening arranged on the back surface of the shell and a mounting plate fixed on the back surface of the shell through bolts, at least three elastic clamping sleeves are fixedly connected to the front surface of the mounting plate, vacuum collecting bottles are clamped in the three clamping sleeves, and rubber covers are arranged at ports of the three vacuum collecting bottles;

through the setting of gathering the subassembly, the gaseous collection of being convenient for, through drive assembly's setting, be convenient for drive and gather the subassembly and be connected with storage assembly, and then form gas collection work.

Further, gather the subassembly including being fixed in the gasbag of shells inner wall bottom, the inside of gasbag communicates respectively has extraction tube and discharge pipe, all be provided with the check valve on extraction tube and the discharge pipe, and the one end of extraction tube runs through the casing and extends to the outside of casing, the one end fixedly connected with needle tubing of discharge pipe.

Furthermore, the top of the inner wall of the shell is fixedly connected with a first electric telescopic rod, the telescopic end of the first electric telescopic rod is fixedly connected with an extrusion frame, and the extrusion frame is connected with the inner wall of the shell in a sliding mode.

Furthermore, the driving assembly is installed on an electric sliding rail between two sides of the inner wall of the shell, an L-shaped frame is arranged on the electric sliding rail in an electric sliding mode, a moving frame is connected to the bottom of the L-shaped frame in a sliding mode, and the moving frame is fixedly connected with the needle tube.

Furthermore, a second electric telescopic rod is fixedly connected between the front face of the movable frame and the inner wall of the L-shaped frame.

Further, the equal fixedly connected with locating rack in both sides of casing, and the equal threaded connection in inside of two carriages has the lead screw, two the one end that the lead screw is relative all rotates and is connected with the chucking piece that is used for inserting the locating rack inside.

3. Advantageous effects

Compared with the prior art, the utility model has the advantages of:

this technical scheme is through the setting of two carriages, and the part that is convenient for detect the collection carries out slidable mounting, improves the convenience of installation, and through the setting of gathering the subassembly, the gaseous collection of being convenient for through the setting of drive assembly, is convenient for drive collection subassembly and storage assembly and is connected, and then forms gas collection work, and through the setting of storage assembly, not only be convenient for deposit of gaseous pollutants, satisfied depositing of different kinds of gaseous pollutants moreover, improve the functional of gaseous pollutants collection.

Drawings

Fig. 1 is a front view of the present invention;

fig. 2 is a schematic structural view of the unmanned aerial vehicle body of the present invention;

fig. 3 is a schematic structural view of the housing of the present invention;

fig. 4 is a side sectional view of the middle case of the present invention.

The numbering in the figures illustrates:

1. an unmanned aerial vehicle body; 2. a carriage; 3. a housing; 4. a collection assembly; 41. an air bag; 42. an extraction pipe; 43. a discharge pipe; 44. a needle tube; 45. a first electric telescopic rod; 46. an extrusion frame; 5. a drive assembly; 51. an electric slide rail; 52. an L-shaped frame; 53. a movable frame; 54. a second electric telescopic rod; 6. a storage component; 61. mounting a plate; 62. a clamping sleeve; 63. a vacuum collection bottle; 7. a positioning frame; 8. a screw rod; 9. and a clamping block.

Detailed Description

The technical solution in the embodiment of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiment of the present invention; obviously, the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by those skilled in the art without any inventive work are within the scope of the present invention based on the embodiments of the present invention.

Example 1:

referring to fig. 1-4, an unmanned aerial vehicle monitoring device for gas pollution comprises an unmanned aerial vehicle body 1, wherein two sliding frames 2 are fixedly connected to the bottom of the unmanned aerial vehicle body 1, a housing 3 is slidably connected between opposite sides of the two sliding frames 2, an acquisition assembly 4 is arranged at the bottom of the inner wall of the housing 3, a driving assembly 5 is arranged inside the housing 3, the driving end of the driving assembly 5 is connected with the output end of the acquisition assembly 4, a storage assembly 6 is arranged on the back surface of the housing 3, the storage assembly 6 comprises an opening arranged on the back surface of the housing 3 and an installation plate 61 fixed on the back surface of the housing 3 through bolts, at least three elastic clamping sleeves 62 are fixedly connected to the front surface of the installation plate 61, vacuum collection bottles 63 are clamped inside the three clamping sleeves 62, and rubber covers are arranged at ports of the three vacuum collection bottles 63;

through the arrangement of the two sliding frames 2, the components for detection and collection can be conveniently installed in a sliding manner, and the installation convenience is improved;

the collection of the polluted gas is facilitated by the arrangement of the collection assembly 4;

the driving assembly 5 is arranged, so that the collection assembly 4 is conveniently driven to be connected with the storage assembly 6, and further gas collection work is formed;

through the arrangement of the storage assembly 6, the storage of the polluted gas is facilitated, the storage of different types of polluted gases is met, and the collection functionality of the polluted gas is improved;

the vacuum collecting bottle 63 is in a vacuum state, so that gas can enter the vacuum collecting bottle more smoothly, and the rubber cover is arranged, so that the needle tube 44 can be conveniently inserted, and the gas cannot leak after the needle tube 44 is pulled out.

Referring to fig. 4, the collecting assembly 4 includes an air bag 41 fixed at the bottom of the inner wall of the housing 3, the air bag 41 is respectively communicated with an extracting tube 42 and a discharging tube 43, the extracting tube 42 and the discharging tube 43 are both provided with a one-way valve, one end of the extracting tube 42 penetrates through the housing 3 and extends to the outside of the housing 3, and one end of the discharging tube 43 is fixedly connected with a needle tube 44;

two one-way valves are provided for one-way control of the suction tube 42 and the discharge tube 43 to prevent the gas inside the air bag 41 from being discharged through the suction tube 42 and to prevent the external gas from entering the air bag 41 through the discharge tube 43, and the needle tube 44 is at the same height as the row of vacuum collection bottles 63.

Referring to fig. 4, a first electric telescopic rod 45 is fixedly connected to the top of the inner wall of the housing 3, an extrusion frame 46 is fixedly connected to the telescopic end of the first electric telescopic rod 45, and the extrusion frame 46 is slidably connected to the inner wall of the housing 3;

first electric telescopic handle 45 is connected with external power and control switch for drive extrusion frame 46 up-and-down motion, through the downward motion of extrusion frame 46, can extrude gasbag 41, make the inside formation negative pressure of gasbag 41 breathe in.

Referring to fig. 4, the driving assembly 5 is mounted on an electric sliding rail 51 between two sides of the inner wall of the housing 3, an L-shaped frame 52 is electrically slid on the electric sliding rail 51, a moving frame 53 is slidably connected to the bottom of the L-shaped frame 52, and the moving frame 53 is fixedly connected to the needle tube 44;

the electric slide rail 51 adopts an electric slide rail component in the prior art, is used for electrically controlling the L-shaped frame 52 to move left and right, and can indirectly drive the moving frame 53 and the needle tube 44 to move left and right through the left and right movement of the L-shaped frame 52, so that the needle tube 44 can be aligned to the vacuum collection bottles 63 at different positions to collect different gases.

Referring to fig. 4, a second electric telescopic rod 54 is fixedly connected between the front surface of the moving frame 53 and the inner wall of the L-shaped frame 52;

the second electric telescopic rod 54 is connected to an external power source and a control switch, and is used for driving the movable frame 53 to move back and forth.

Referring to fig. 1-3, both sides of the housing 3 are fixedly connected with positioning frames 7, the insides of the two sliding frames 2 are both in threaded connection with screw rods 8, and the opposite ends of the two screw rods 8 are both rotatably connected with clamping blocks 9 for being inserted into the insides of the positioning frames 7;

the jack has all been seted up to the inside of two locating racks 7, and through two lead screws 8 of manual rotation, can drive two chucking piece 9 relative direction or the direction motion that leaves mutually, through the motion of two chucking piece 9 relative direction, can insert in the locating rack 7 of corresponding position to form the chucking, accomplish the installation of casing 3.

When in use: drive L type frame 52 and needle tubing 44 through electronic slide rail 51 and move to vacuum receiving flask 63 flush the position, through the start-up of second electric telescopic handle 54, can drive and remove the fore-and-aft movement of frame 53, through removing the motion backward of frame 53, can drive the inside that needle tubing 44 inserted vacuum receiving flask 63, through the start-up of first electric telescopic handle 45, can drive the extrusion frame 46 up-and-down motion, through the downward motion of extrusion frame 46, can extrude gasbag 41, make the inside of gasbag 41 form the negative pressure and breathe in, can form through the extraction tube 42 and breathe in, and discharge through discharge tube 43, finally discharge the inside of vacuum receiving flask 63 through needle tubing 44, form and collect.

The above description is only the preferred embodiment of the present invention; the scope of the present invention is not limited thereto. Any person skilled in the art should also be able to cover the technical scope of the present invention by replacing or changing the technical solution and the improvement concept of the present invention with equivalents and modifications within the technical scope of the present invention.

Claims (6)

1. The utility model provides an unmanned aerial vehicle monitoring devices that gas pollution used, includes unmanned aerial vehicle body (1), its characterized in that: two carriage (2) of bottom fixedly connected with of unmanned aerial vehicle body (1), two sliding connection has casing (3) between the relative one side of carriage (2), the bottom of casing (3) inner wall is provided with gathers subassembly (4), inside drive assembly (5) that is provided with of casing (3), the drive end of drive assembly (5) is connected with the output of gathering subassembly (4), the back of casing (3) is provided with storage component (6), storage component (6) are including seting up the opening at the casing (3) back to and through mounting panel (61) of bolt fastening in the casing (3) back, mounting panel (61) openly fixedly connected with at least three elastic chucking cover (62), and the equal chucking in inside of three chucking cover (62) has vacuum collection bottle (63), and the port of three vacuum collection bottle (63) all is provided with the rubber lid.

2. An unmanned aerial vehicle monitoring device for gas pollution according to claim 1, wherein: gather subassembly (4) including gasbag (41) that is fixed in casing (3) inner wall bottom, the inside of gasbag (41) communicates respectively has extraction tube (42) and discharge pipe (43), all be provided with the check valve on extraction tube (42) and discharge pipe (43), and the one end of extraction tube (42) runs through casing (3) and extends to the outside of casing (3), the one end fixedly connected with needle tubing (44) of discharge pipe (43).

3. An unmanned aerial vehicle monitoring device for gas pollution according to claim 2, wherein: the top fixedly connected with first electric telescopic handle (45) of casing (3) inner wall, the flexible end fixedly connected with extrusion frame (46) of first electric telescopic handle (45), extrusion frame (46) sliding connection in the inner wall of casing (3).

4. An unmanned aerial vehicle monitoring device for gas pollution according to claim 1, wherein: the drive assembly (5) is installed on an electric sliding rail (51) between two sides of the inner wall of the shell (3), an L-shaped frame (52) is arranged on the electric sliding rail (51) in an electric sliding mode, a moving frame (53) is connected to the bottom of the L-shaped frame (52) in a sliding mode, and the moving frame (53) is fixedly connected with the needle tube (44).

5. An unmanned aerial vehicle monitoring device for gas pollution according to claim 4, wherein: a second electric telescopic rod (54) is fixedly connected between the front surface of the moving frame (53) and the inner wall of the L-shaped frame (52).

6. An unmanned aerial vehicle monitoring device for gas pollution according to claim 1, wherein: the equal fixedly connected with locating rack (7) in both sides of casing (3), and the equal threaded connection in inside of two carriage (2) has lead screw (8), two the one end that lead screw (8) is relative all rotates and is connected with and is used for inserting inside chucking piece (9) of locating rack (7).

Images