CN216434141U - Last wind vane support of ozone detection unmanned aerial vehicle - Google Patents

Abstract

The utility model provides a last wind vane support of ozone detection unmanned aerial vehicle, this last wind vane support of ozone detection unmanned aerial vehicle, including unmanned aerial vehicle, atmosphere ozone detector, deformation subassembly and support. The support pin joint is in unmanned aerial vehicle's bottom, atmosphere ozone detector sets up on the support. The deformation assembly is arranged at the bottom of the support, and the wind indicating end of the deformation assembly is arranged at the same side of the air inlet of the atmospheric ozone detector. This last wind vane support of ozone detection unmanned aerial vehicle rotates motor, connecting seat, two preceding deflectors and back deflector through two that set up and mutually supports, can become the wind vane and then guide atmosphere ozone detector to rotate the windward direction when needs, makes things convenient for its detection. Also can let simultaneously the utility model discloses the wind direction this moment is judged to the clarity, and then lets it can the quick travel to wind gap department down. The detection is convenient. Simultaneously can act as unmanned aerial vehicle's undercarriage after warping. The utility model is multipurpose.

Description

Last wind vane support of ozone detection unmanned aerial vehicle

Technical Field

The utility model relates to an ozone check out test set technical field specifically is a last wind vane support of ozone detection unmanned aerial vehicle.

Background

In the process of using unmanned aerial vehicle to aerial ozone detection, because ozone detection device fixes on unmanned aerial vehicle, personnel often just to the wind gap with the ozone detection import in order to improve the efficiency that detects the sampling, let a large amount of air currents get into detection device as far as, make things convenient for it to detect.

However, the natural wind direction is constantly changing, so personnel have to frequently adjust the position of the unmanned aerial vehicle, and the operation difficulty of the personnel is greatly increased. Is inconvenient for the use of personnel.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

Not enough to prior art, the utility model provides a last wind vane support of ozone detection unmanned aerial vehicle.

(II) technical scheme

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: the utility model provides a wind vane support on ozone detection unmanned aerial vehicle, includes unmanned aerial vehicle, atmosphere ozone detector, deformation subassembly and support. The support pin joint is in unmanned aerial vehicle's bottom, atmosphere ozone detector sets up on the support. The deformation assembly is arranged at the bottom of the support, and the wind indicating end of the deformation assembly is arranged at the same side of the air inlet of the atmospheric ozone detector.

Preferably, the deformation assembly includes two rotating motors, a connecting seat, two front guide plates and a rear guide plate. The connecting seat is arranged at the bottom of the support, and the two rotating motors are symmetrically arranged on two sides of the connecting seat by taking the connecting seat as a center. The two front guide plates and the rear guide plate are respectively hinged with the two rotating motors. The heights of the front guide plate and the rear guide plate are consistent. The front guide plate is arranged at the same side of an air inlet of the atmospheric ozone detector.

Preferably, the deformation assembly further comprises a front sleeve and a rear sleeve. The front sleeve and the rear sleeve are respectively hinged to the front side and the rear side of the connecting seat.

Preferably, the two front guide plates and the two rear guide plates are provided with magnets with different magnetism at the sides close to each other.

Preferably, the wind speed measuring device further comprises a wind speed measuring device and a rotating rod. Dwang one end links to each other with the deformation subassembly, and the other end passes support, unmanned aerial vehicle respectively and extends to unmanned aerial vehicle's top. The wind speed measurer is arranged on a rotating rod positioned at the top of the unmanned aerial vehicle.

Preferably, the front sleeve and the rear sleeve are fitted with the front guide plate and the rear guide plate.

(III) advantageous effects

The utility model provides a last wind vane support of ozone detection unmanned aerial vehicle. The method has the following beneficial effects:

1. this last wind vane support of ozone detection unmanned aerial vehicle rotates motor, connecting seat, two preceding deflectors and back deflector through two that set up and mutually supports, can become the wind vane and then guide atmosphere ozone detector to rotate the windward direction when needs, makes things convenient for its detection. Also can let simultaneously the utility model discloses the wind direction this moment is judged to the clarity, and then lets it can the quick travel to wind gap department down. The detection is convenient. Simultaneously can act as unmanned aerial vehicle's undercarriage after warping. The utility model is multipurpose.

Drawings

Fig. 1 is a first perspective view of the present invention;

fig. 2 is a second perspective view of the present invention;

fig. 3 is a perspective view of a part of the present invention.

In the figure: 1 unmanned aerial vehicle, 2 atmosphere ozone detector, 3 supports, 4 deformation subassembly, 5 wind speed measurement wares, 6 dwang, 7 preceding deflector, 8 preceding sleeves, 9 rotation motor, 10 back sleeves, 11 back deflector, 12 connecting seats.

Detailed Description

The embodiment of the utility model provides a wind vane support on ozone detection unmanned aerial vehicle, as shown in fig. 1-3, including unmanned aerial vehicle 1, atmosphere ozone detector 2, deformation subassembly 4 and support 3. Support 3 pin joint is in unmanned aerial vehicle 1's bottom, and atmosphere ozone detector 2 sets up on support 3. The deformation assembly 4 is arranged at the bottom of the bracket 3, and the wind-directing end of the deformation assembly 4 is arranged at the same side of the air inlet of the atmospheric ozone detector 2.

The deformation assembly 4 comprises two rotating motors 9, a connecting seat 12, two front guide plates 7 and a rear guide plate 11. Connecting seat 12 is disposed at the bottom of bracket 3, and two rotating motors 9 are symmetrically disposed on two sides of connecting seat 12 with connecting seat 12 as the center. The two front guide plates 7 and the rear guide plate 11 are respectively hinged with the two rotating motors 9. The front guide plate 7 and the rear guide plate 11 are uniform in height. The front guide plate 7 is arranged at the same side of the air inlet of the atmospheric ozone detector 2.

Deformation assembly 4 further comprises a front sleeve 8 and a rear sleeve 10. The front sleeve 8 and the rear sleeve 10 are respectively hinged on the front side and the rear side of the connecting seat 12.

And magnets with different magnetism are arranged on the sides, close to each other, of the two front guide plates 7 and the rear guide plate 11.

Also comprises an anemometer 5 and a rotating rod 6. 6 one end of dwang links to each other with out of shape subassembly 4, and the other end passes support 3, unmanned aerial vehicle 1 respectively and extends to unmanned aerial vehicle 1's top. The wind speed measurement ware 5 sets up on the dwang 6 that is located 1 top of unmanned aerial vehicle.

The front sleeve 8 and the rear sleeve 10 are fitted with the front guide plate 7 and the rear guide plate 11. Through the dwang 6, preceding sleeve 8 and the back sleeve 10 of setting mutually supporting, can effectively solve the gap that appears after two this kind of preceding deflector 7 and the mutual lock of back deflector 11, blow the problem of opening under the great condition of wind-force.

The working principle is as follows: during the use, control rotation motor 9 makes two preceding deflectors 7 and back deflector 11 be close to each other and link to each other through magnetism, lets deformation component 4 become to form the wind vane through preceding sleeve 8 and back sleeve 10 after that, according to deformation component 4's directional this sky wind direction of judgement to remove the leeward department of waiting to detect the mill through unmanned aerial vehicle 1, atmosphere ozone detector 2 detects.

When the utility model discloses when needing to descend, through rotating 9 work of motor, rotate front guide 7 and back deflector 11 for back sleeve 10, front sleeve 8, two front guide 7 and back deflector 11 become the hexagonal support, are warp into the undercarriage by the wind vane. The utility model is multipurpose.

To sum up, this last wind vane support of ozone detection unmanned aerial vehicle, two through setting up rotate motor 9, connecting seat 12, two preceding deflectors 7 and back deflector 11 and mutually support, can become the wind vane when needs and then guide atmosphere ozone detector 2 to rotate to the windward direction, make things convenient for it to detect. Also can let simultaneously the utility model discloses the wind direction this moment is judged to the clarity, and then lets it can the quick travel to wind gap department down. The detection is convenient. And at the same time may act as landing gear for the drone 1 after deformation. The utility model is multipurpose.

Claims (6)

1. The utility model provides an ozone detects wind vane support on unmanned aerial vehicle which characterized in that: including unmanned aerial vehicle (1), atmosphere ozone detector (2), deformation subassembly (4) and support (3), support (3) pin joint is in the bottom of unmanned aerial vehicle (1), atmosphere ozone detector (2) set up on support (3), deformation subassembly (4) set up the bottom in support (3), the wind end that indicates of deformation subassembly (4) is with the air intake homonymy of atmosphere ozone detector (2).

2. The wind vane support of claim 1, wherein the wind vane support comprises: deformation subassembly (4) include two rotation motor (9), connecting seat (12), two preceding deflectors (7) and back deflector (11), connecting seat (12) set up in the bottom of support (3), and two rotation motor (9) use connecting seat (12) to set up in connecting seat (12) both sides as central symmetry, and two preceding deflectors (7) and back deflector (11) are articulated with two rotation motor (9) respectively, the highly uniform of preceding deflector (7) and back deflector (11), preceding deflector (7) and the air intake homonymy of atmosphere ozone detector (2).

3. The wind vane support of claim 1, wherein the wind vane support comprises: the deformation assembly (4) further comprises a front sleeve (8) and a rear sleeve (10), and the front sleeve (8) and the rear sleeve (10) are hinged to the front side and the rear side of the connecting seat (12) respectively.

4. The wind vane support of claim 3, wherein the wind vane support comprises: the two front guide plates (7) and the rear guide plate (11) are provided with magnets with different magnetism at the sides close to each other.

5. The wind vane support of claim 4, wherein the wind vane support comprises: still include wind speed measurement ware (5) and dwang (6), dwang (6) one end links to each other with out-of-shape component (4), and the other end passes support (3), unmanned aerial vehicle (1) respectively and extends to the top of unmanned aerial vehicle (1), wind speed measurement ware (5) set up on dwang (6) that are located unmanned aerial vehicle (1) top.

6. The wind vane support of claim 5, wherein the wind vane support comprises: the front sleeve (8) and the rear sleeve (10) are matched with the front guide plate (7) and the rear guide plate (11).

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