CN212099378U - Remote sensing monitoring unmanned aerial vehicle for natural resources, anticollision institution and heat dissipation mechanism - Google Patents

Abstract

The utility model discloses a remote sensing monitoring unmanned aerial vehicle, anticollision institution and heat dissipation mechanism for natural resources, unmanned aerial vehicle includes the casing, the bottom of casing is close to outside fixed mounting and has the undercarriage, the inboard fixed mounting that the bottom of casing is located the undercarriage has the camera, one side fixedly connected with wing of casing, the upper portion fixed mounting of wing has the rotor, the one end of wing is equipped with anticollision institution, anticollision institution is including crashproof seat, crash bar, elasticity arc pole, anticollision spring, buffer pad, reset spring and damping hole, the front portion of casing is equipped with heat dissipation mechanism, heat dissipation mechanism is including first dust screen, fixing base, fixed screw, inlet port and second dust screen. A remote sensing monitoring unmanned aerial vehicle for natural resources, can play excellent crashproof effect, to the damage that unmanned aerial vehicle brought when reducing the striking, secondly also can improve the radiating effect, reduced the windage to possess better dustproof efficiency.

Description

Remote sensing monitoring unmanned aerial vehicle for natural resources, anticollision institution and heat dissipation mechanism

Technical Field

The utility model relates to an unmanned aerial vehicle field, in particular to remote sensing monitoring unmanned aerial vehicle, anticollision institution and heat dissipation mechanism for natural resources.

Background

The remote sensing monitoring unmanned aerial vehicle for natural resources is a remote control plane for remote sensing monitoring of natural resources, a camera is usually arranged on the plane, the camera can fly above gardens and forests, and the remote sensing monitoring unmanned aerial vehicle is used for monitoring whether the gardens and the forests have potential safety hazards or not and belongs to a monitoring tool commonly used for natural resources; but current remote sensing for natural resources monitors unmanned aerial vehicle anticollision effect relatively poor, traditional remote sensing for natural resources monitors unmanned aerial vehicle and only is at the anticollision frame of house type of outside fixed mounting of rotor, but anticollision frame itself does not possess the function of the anti striking of buffering, when the striking produces, still can bring great damage for unmanned aerial vehicle, secondly traditional unmanned aerial vehicle casing is the sealed, the heat dissipation is slow, and the windage is big, long-time flight causes the phenomenon that unmanned aerial vehicle high temperature easily, and unmanned aerial vehicle flight resistance has also been increased, the power consumption has been improved, the result of use is relatively poor.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a main aim at provides a remote sensing monitoring unmanned aerial vehicle, anticollision institution and heat dissipation mechanism for natural resources can effectively solve the problem in the background art.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides a remote sensing monitoring unmanned aerial vehicle for natural resources, includes the casing, the bottom of casing is close to outside fixed mounting and has the undercarriage, the inboard fixed mounting that the bottom of casing is located the undercarriage has the camera, one side fixedly connected with wing of casing, the upper portion fixed mounting of wing has the rotor, the one end of wing is equipped with anticollision institution, anticollision institution is including crashproof seat, crash bar, elasticity arc pole, anticollision spring, buffer block, reset spring and damping hole, the front portion of casing is equipped with heat dissipation mechanism, heat dissipation mechanism is including first dirt screen, fixing base, fixed screw, inlet port and second dirt screen.

Preferably, anticollision seat fixed mounting is in the one end of wing, crash bar swing joint is in the one end of anticollision seat, elasticity arc pole fixed connection is in the one end of crash bar, buffer plate fixed connection is at the other end of crash bar, reset spring places the inside at the anticollision seat, the damping hole is seted up on a side surface of buffer plate.

Preferably, the number of the wings is six, one ends of the six wings are provided with anti-collision mechanisms, and damping oil is filled in the anti-collision seats.

Preferably, the fixing seat is fixedly installed on one side of the first dust filter screen, the fixing screw penetrates through the fixing seat and is in threaded connection with the shell, the air inlet hole is formed in the front surface of the shell, and the second dust filter screen is in threaded connection with the rear portion of the shell.

Preferably, the rear surface of the housing is provided with an exhaust hole, and the second dust filter screen covers the outside of the exhaust hole.

The utility model provides a natural resources is with remote sensing monitoring unmanned aerial vehicle's anticollision institution, includes anticollision seat, crash bar, elasticity arc pole, anticollision spring, buffer plate, reset spring and damping hole, anticollision seat fixed mounting is in the one end of wing, crash bar swing joint is in the one end of anticollision seat, elasticity arc pole fixed connection is in the one end of crash bar, buffer plate fixed connection is at the other end of crash bar, reset spring places the inside at the anticollision seat, a side surface at the buffer plate is seted up to the damping hole.

The utility model provides a heat dissipation mechanism of remote sensing monitoring unmanned aerial vehicle for natural resources, includes first dust filter screen, fixing base, fixed screw, inlet port and second dust filter screen, fixing base fixed mounting is in one side of first dust filter screen, fixed screw runs through fixing base and casing threaded connection, the front surface at the casing is seted up to the inlet port, second dust filter screen screwed connection is at the rear portion of casing.

Compared with the prior art, the utility model discloses following beneficial effect has:

1. in the utility model, through the arranged anti-collision mechanism, when the impact is generated, the elastic arc rod plays a better role of buffering and anti-collision through the elasticity of the elastic arc rod, and simultaneously, the elastic arc rod can also push the anti-collision rod to move towards the inside of the anti-collision seat, thereby compressing the anti-collision spring and the reset spring, playing an excellent shock absorption and anti-collision effect through the anti-collision spring and the reset spring, improving the safety, through the arranged heat dissipation mechanism, the originally sealed shell is changed into the shell with the air inlet hole and the air exhaust hole, when flying, the external air can enter through the air inlet hole and the air exhaust hole is exhausted, the internal temperature of the shell can be effectively reduced when the air passes through the inside of the shell, playing a role of heat dissipation, simultaneously, the air circulation can also reduce the wind resistance, and the air inlet hole and the air exhaust hole are respectively provided with the first dust filter screen and the, has dustproof function.

2. The utility model provides a remote sensing monitoring unmanned aerial vehicle's anticollision institution for natural resources.

3. The utility model provides a remote sensing monitoring unmanned aerial vehicle's heat dissipation mechanism for natural resources.

Drawings

Fig. 1 is a schematic view of the overall structure of the remote sensing monitoring unmanned aerial vehicle for natural resources of the present invention;

fig. 2 is a top view of a wing of the remote sensing monitoring unmanned aerial vehicle for natural resources of the present invention;

fig. 3 is a schematic view of the internal structure of an anti-collision seat of the remote sensing monitoring unmanned aerial vehicle for natural resources of the present invention;

in the figure: 1. a housing; 2. a landing gear; 3. a camera; 4. an airfoil; 5. a rotor; 6. an anti-collision mechanism; 7. an anti-collision seat; 8. an anti-collision bar; 9. an elastic arc bar; 10. an anti-collision spring; 11. a buffer sheet; 12. a return spring; 13. a damping hole; 14. a heat dissipation mechanism; 15. a first dust filter screen; 16. a fixed seat; 17. and fixing the screw.

Detailed Description

In order to make the technical means, creation features, achievement purposes and functions of the present invention easy to understand, the present invention is further described below with reference to the following embodiments.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "front end", "rear end", "both ends", "one end", "the other end" and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element to which the reference is made must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "connected," and the like are to be construed broadly, and for example, "connected" may be either fixedly connected or detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Detailed description of the preferred embodiment

The embodiment is an embodiment of a remote sensing monitoring unmanned aerial vehicle for natural resources.

As shown in fig. 1-3, a remote sensing monitoring unmanned aerial vehicle for natural resources comprises a housing 1, wherein an undercarriage 2 is fixedly mounted at the bottom of the housing 1 close to the outer side, a camera 3 is fixedly mounted at the bottom of the housing 1 at the inner side of the undercarriage 2, a wing 4 is fixedly connected to one side of the housing 1, a rotor 5 is fixedly mounted at the upper part of the wing 4, an anti-collision mechanism 6 is arranged at one end of the wing 4, the anti-collision mechanism 6 comprises an anti-collision seat 7, an anti-collision rod 8, an elastic arc rod 9, an anti-collision spring 10, a buffer sheet 11, a return spring 12 and a damping hole 13, a heat dissipation mechanism 14 is arranged at the front part of the housing 1, and the heat dissipation mechanism 14 comprises a first dust filter 15, a fixed seat 16, a;

the anti-collision seat 7 is fixedly arranged at one end of the wing 4, the anti-collision rod 8 is movably connected at one end of the anti-collision seat 7, the elastic arc rod 9 is fixedly connected at one end of the anti-collision rod 8, the buffer sheet 11 is fixedly connected at the other end of the anti-collision rod 8, the reset spring 12 is placed in the anti-collision seat 7, the damping hole 13 is formed in one side surface of the buffer sheet 11, the anti-collision mechanism 6 can play an excellent anti-collision effect, the protection performance of the unmanned aerial vehicle during collision is improved, and the safety is higher; the number of the wings 4 is six, one ends of the six wings 4 are respectively provided with an anti-collision mechanism 6, damping oil is filled in an anti-collision seat 7, and the damping oil can be matched with the damping holes 13 to play a damping effect; the fixed seat 16 is fixedly arranged on one side of the first dust filter screen 15, the fixed screw 17 penetrates through the fixed seat 16 and is in threaded connection with the shell 1, the air inlet hole is formed in the front surface of the shell 1, and the second dust filter screen is in threaded connection with the rear part of the shell 1; the rear surface of the shell 1 is provided with an exhaust hole, the second dust filtering net covers the outside of the exhaust hole, and the exhaust hole can be matched with the air inlet hole to play a role in air circulation, so that heat dissipation is increased, and wind resistance is reduced.

It should be noted that, the utility model relates to a remote sensing monitoring unmanned aerial vehicle for natural resources, when using, when unmanned aerial vehicle is flying, outside air enters through first dust filter 15 and inlet port, then discharges through exhaust hole and second dust filter, or enters through second dust filter and exhaust hole, then discharges through inlet port and first dust filter 15, the air that enters passes through the inside of casing 1, can effectively reduce the temperature inside casing 1, increase the heat dissipation effect, secondly, the circulation effect of air, better wind resistance that reduces, reduce unmanned aerial vehicle's flight power consumption, play energy-conserving effect, secondly, when the air enters the inside of casing 1, receive the filtration of first dust filter 15 and second dust filter, can filter the dust in the air, can not lead to the dust entering the inside of casing 1, play excellent dustproof effect, secondly, when unmanned aerial vehicle striking produced, elasticity arc pole 9 plays the efficiency of better buffering anticollision through the elasticity of self, and elasticity arc pole 9 also can promote crash bar 8 to 7 inside removals of anticollision seat simultaneously to compression anticollision spring 10 and reset spring 12 play excellent shock attenuation anticollision effect through anticollision spring 10 and reset spring 12, improve the security.

Concretely, the second embodiment

The embodiment is an embodiment of an anticollision institution of a natural resource remote sensing monitoring unmanned aerial vehicle.

As shown in fig. 1, 2 and 3, the collision avoidance mechanism of the natural resource remote sensing monitoring unmanned aerial vehicle comprises a collision avoidance seat 7, a collision avoidance bar 8, an elastic arc bar 9, a collision avoidance spring 10, a buffer plate 11, a return spring 12 and a damping hole 13, wherein the front part of a shell 1 is provided with a heat dissipation mechanism 14, the collision avoidance seat 7 is fixedly installed at one end of a wing 4, the collision avoidance bar 8 is movably connected at one end of the collision avoidance seat 7, the elastic arc bar 9 is fixedly connected at one end of the collision avoidance bar 8, the buffer plate 11 is fixedly connected at the other end of the collision avoidance bar 8, the return spring 12 is placed inside the collision avoidance seat 7, and the damping hole 13 is arranged on one side surface of the buffer plate 11;

when unmanned aerial vehicle striking produced, elasticity arc pole 9 plays the efficiency of better buffering anticollision through the elasticity of self, and elasticity arc pole 9 also can promote crash bar 8 to 7 inside removals of anticollision seat simultaneously to compression anticollision spring 10 and reset spring 12 play excellent shock attenuation anticollision effect through anticollision spring 10 and reset spring 12, improve the security.

Detailed description of the preferred embodiment

The embodiment is an embodiment of a heat dissipation mechanism of a natural resource remote sensing monitoring unmanned aerial vehicle.

A heat dissipation mechanism of an unmanned aerial vehicle for remote sensing monitoring of natural resources comprises a first dust filter screen 15, a fixed seat 16, a fixed screw 17, an air inlet and a second dust filter screen, wherein the fixed seat 16 is fixedly arranged on one side of the first dust filter screen 15, the fixed screw 17 penetrates through the fixed seat 16 and is in threaded connection with a shell 1, the air inlet is formed in the front surface of the shell 1, and the second dust filter screen is in threaded connection with the rear part of the shell 1;

when unmanned aerial vehicle is in the flight, outside air passes through first dust filter screen 15 and the inlet port gets into, then discharge through exhaust hole and second dust filter screen, or get into through second dust filter screen and exhaust hole, then discharge through inlet port and first dust filter screen 15, the air of entering passes through the inside of casing 1, can the inside temperature of 1 effectual reduction casing, increase the radiating effect, secondly, the circulation effect of air, the windage of better reduction, reduce unmanned aerial vehicle's flight consumption, play energy-conserving effect, secondly, the air is when entering casing 1 inside, receive the filtration of first dust filter screen 15 and second dust filter screen, can filter the dust in the air, can not lead to the dust to enter into casing 1's inside, play excellent dustproof effect.

The basic principles and the main features of the invention and the advantages of the invention have been shown and described above. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (7)

1. The utility model provides a remote sensing monitoring unmanned aerial vehicle for natural resources which characterized in that: including casing (1), the bottom of casing (1) is close to outside fixed mounting and has undercarriage (2), the inboard fixed mounting that the bottom of casing (1) is located undercarriage (2) has camera (3), one side fixedly connected with wing (4) of casing (1), the upper portion fixed mounting of wing (4) has rotor (5), the tip of wing (4) is equipped with anticollision institution (6), anticollision institution (6) include: anticollision seat (7), crash bar (8), elasticity arc pole (9), anticollision spring (10), buffer chip (11), reset spring (12) and damping hole (13), the front portion of casing (1) is equipped with heat dissipation mechanism (14), heat dissipation mechanism (14) include: the dust filter comprises a first dust filter screen (15), a fixed seat (16), a fixed screw (17), an air inlet and a second dust filter screen.

2. The remote sensing monitoring unmanned aerial vehicle for natural resources of claim 1, characterized in that: anticollision seat (7) fixed mounting is at the tip of wing (4), crash bar (8) swing joint is in the one end of anticollision seat (7), elasticity arc pole (9) fixed connection is in the one end of crash bar (8), buffer chip (11) fixed connection is at the other end of crash bar (8), reset spring (12) are placed in the inside of anticollision seat (7), a side surface at buffer chip (11) is seted up in damping hole (13).

3. The remote sensing monitoring unmanned aerial vehicle for natural resources of claim 1, characterized in that: the number of the wings (4) is six, the one end of each wing (4) is provided with an anti-collision mechanism (6), and damping oil is filled in the anti-collision seat (7).

4. The remote sensing monitoring unmanned aerial vehicle for natural resources of claim 1, characterized in that: the fixed seat (16) is fixedly arranged on one side of the first dust filtering net (15), the fixing screw (17) penetrates through the fixed seat (16) and is in threaded connection with the shell (1), the air inlet hole is formed in the front surface of the shell (1), and the second dust filtering net is in threaded connection with the rear portion of the shell (1).

5. The remote sensing monitoring unmanned aerial vehicle for natural resources of claim 1, characterized in that: the rear surface of the shell (1) is provided with an exhaust hole, and the second dust filtering net covers the outside of the exhaust hole.

6. The utility model provides a natural resources is with remote sensing monitoring unmanned aerial vehicle's anticollision institution which characterized in that: including anticollision seat (7), crash bar (8), elasticity arc pole (9), anticollision spring (10), buffer chip (11), reset spring (12) and damping hole (13), anticollision seat (7) fixed mounting is in the one end of wing (4), crash bar (8) swing joint is in the one end of anticollision seat (7), elasticity arc pole (9) fixed connection is in the one end of crash bar (8), buffer chip (11) fixed connection is at the other end of crash bar (8), reset spring (12) are placed in the inside of anticollision seat (7), a side surface at buffer chip (11) is seted up in damping hole (13).

7. The utility model provides a heat dissipation mechanism of remote sensing monitoring unmanned aerial vehicle for natural resources which characterized in that: including first dust filter screen (15), fixing base (16), fixed screw (17), inlet port and second dust filter screen, fixing base (16) fixed mounting is in one side of first dust filter screen (15), fixed screw (17) run through fixing base (16) and casing (1) threaded connection, the inlet port is seted up at the front surface of casing (1), second dust filter screen screwed connection is at the rear portion of casing (1).

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