CN215753000U - Unmanned aerial vehicle for surveying and mapping geographic landforms - Google Patents

Abstract

The utility model discloses a geographic geomorphic surveying and mapping unmanned aerial vehicle, which comprises a host and a tripod head, wherein the bottom end of the host is provided with the tripod head, the unmanned aerial vehicle is placed on the ground, four driving machines of the aircraft are started to drive blades to operate, the ground is effectively surveyed and mapped through a monitoring probe at the bottom end of the tripod head after the unmanned aerial vehicle takes off, simultaneously, four warning lamps on the surface of a sleeve continuously flicker in the process of high-altitude flight to guard surrounding flying objects, then, a signal module of a control panel at the top end of the host is used for returning data monitored by the unmanned aerial vehicle in real time, the unmanned aerial vehicle lands after surveying and mapping, when the unmanned aerial vehicle lands on uneven ground, a compression spring in the sleeve is compressed and deformed to enable a foot support to lift the unmanned aerial vehicle off the ground all the time, and the blades of the unmanned aerial vehicle cannot be directly contacted with the ground due to unevenness of the field ground in the landing process to cause damage to the unmanned aerial vehicle, compare traditional unmanned aerial vehicle equipment flight adaptability at the in-process of using stronger, more be fit for field flight survey and drawing work.

Description

Unmanned aerial vehicle for surveying and mapping geographic landforms

Technical Field

The utility model belongs to the technical field of geographic landform surveying and relates to a geographic landform surveying and mapping unmanned aerial vehicle.

Background

The geography mapping is mainly to map the geography point location determined on the spot to the measurement work on the topographic map by a certain measurement method, the section alignment measurement, the section control measurement, the geography section measurement, the section point measurement, the section calculation and the drawing of the section map, and a geography geomorphology mapping unmanned aerial vehicle is needed in the measurement process.

The prior art has the following problems:

unmanned aerial vehicle that the in-process of current geographical landform survey and drawing needs to use is as the main equipment of measurement, and spacing unmanned aerial vehicle is mostly many rotor unmanned aerial vehicle usually, and the screw through the top is regarded as driving power at the in-process that uses, need level and smooth ground at the in-process of taking off and descending usually, otherwise appear descending easily and take off the impaired state of in-process paddle and take place, cause the unable normal operating of unmanned aerial vehicle.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a geographic landform surveying and mapping unmanned aerial vehicle, which aims to solve the problem that the unmanned aerial vehicle which is required to be used in the existing geographic landform surveying and mapping process in the background technology is taken as a main measurement device, most of limiting unmanned aerial vehicles are multi-rotor unmanned aerial vehicles, a propeller at the top end is taken as a driving force in the using process, the unmanned aerial vehicle generally needs to be leveled on the ground in the taking-off and landing processes, and otherwise, the unmanned aerial vehicle cannot normally run due to the fact that blades are damaged in the landing and taking-off processes easily occur.

In order to achieve the purpose, the utility model provides the following technical scheme: the utility model provides a geography geomorphy survey and drawing unmanned aerial vehicle, includes host computer and cloud platform, the bottom of host computer is provided with the cloud platform, the bottom of cloud platform is provided with monitor, one side of monitor is provided with the battery jar, the inside of battery jar is provided with the fixed block, a side surface of host computer is provided with the connecting rod, the top of connecting rod is provided with the sleeve, telescopic top is provided with the driving machine, the top of driving machine is provided with the paddle, telescopic surface is provided with the warning light, the inside compression spring that is provided with of sleeve, the bottom of compression spring is provided with the heel brace, the top of host computer is provided with the control panel, the surface of control panel is provided with signal module, the inside of battery jar is provided with the battery.

Preferably, the number of the fixing blocks is two, and the two fixing blocks correspond to the fixing grooves at the bottom end of the storage battery.

Preferably, the number of the connecting rods is four, and the four connecting rods are respectively installed and fixed on the surfaces of the two sides of the host.

Preferably, the monitoring probe is installed at the bottom of host computer through the cloud platform, and the monitoring probe passes through the cloud platform and can freely angle regulation.

Preferably, the number of the warning lamps is four, and the four warning lamps are respectively arranged on the front end surfaces of the four sleeves.

Preferably, the foot support is installed inside the sleeve by a compression spring, and the foot support is free to float up and down inside the sleeve.

Preferably, the bottom of heel brace is provided with fixed cushion, and fixed cushion adopts flexible rubber to make inside hollow structure that adopts.

Compared with the prior art, the utility model provides a geographic and geomorphic surveying and mapping unmanned aerial vehicle which has the following beneficial effects:

the utility model relates to a geotopographic surveying and mapping unmanned aerial vehicle, which is characterized in that a holder is arranged at the bottom end of a host, monitoring probes are arranged at the bottom end of the holder, four connecting rods are arranged at two sides of the host, a sleeve is arranged at the top end of each connecting rod, a driving machine is arranged at the top end of each sleeve, blades are arranged at the top end of each driving machine, and a foot support is arranged at the bottom end of each sleeve, the unmanned aerial vehicle is placed on the ground in the process of using the unmanned aerial vehicle, the unmanned aerial vehicle keeps a certain distance from the ground through the more slender foot supports, then the four driving machines of the aircraft are started to drive the blades to run, the unmanned aerial vehicle is carried to the high altitude, the monitoring probes at the bottom end of the holder are used for effectively surveying and mapping the ground after the unmanned aerial vehicle takes off, meanwhile, four warning lamps on the surface of each sleeve continuously flash in the process of flying at the high altitude, surrounding flying objects are warned, and then the data monitored by the unmanned aerial vehicle are returned in real time through a signal module of a control panel at the top end of the host, accomplish unmanned aerial vehicle descending after the survey and drawing, unmanned aerial vehicle descends when uneven ground, the inside compression spring compression deformation of sleeve makes the heel brace lift unmanned aerial vehicle off the ground at all times, guarantee that unmanned aerial vehicle's paddle can not the unevenness on open-air ground cause paddle direct and ground contact at the descending in-process, cause unmanned aerial vehicle's damage, compare traditional unmanned aerial vehicle equipment, novel geographical landform survey and drawing unmanned aerial vehicle is stronger at the flight adaptability of the in-process that uses, more be fit for open-air flight survey and drawing work.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the principles of the utility model without limiting the utility model in which:

fig. 1 is a schematic structural view of a geo-geomorphic mapping unmanned aerial vehicle according to the present invention;

fig. 2 is a schematic structural view of a mounting foot brace of the unmanned aerial vehicle for mapping geographical features, which is provided by the utility model;

FIG. 3 is a schematic structural view of a landing state of the unmanned aerial vehicle for mapping geographical features, which is provided by the utility model;

in the figure: 1. a host; 2. a holder; 3. monitoring the probe; 4. a connecting rod; 5. a driver; 6. a paddle; 7. a control panel; 8. a signal module; 9. a battery case; 10. a fixed block; 11. a warning light; 12. a sleeve; 13. a compression spring; 14. a foot support; 15. and (4) a storage battery.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-3, the present invention provides a technical solution:

the utility model provides a geography geomorphic survey and drawing unmanned aerial vehicle, including host computer 1 and cloud platform 2, the bottom of host computer 1 is provided with cloud platform 2, the bottom of cloud platform 2 is provided with monitoring probe 3, one side of monitoring probe 3 is provided with battery jar 9, the inside of battery jar 9 is provided with fixed block 10, a side surface of host computer 1 is provided with connecting rod 4, the top of connecting rod 4 is provided with sleeve 12, the top of sleeve 12 is provided with driving machine 5, the top of driving machine 5 is provided with paddle 6, sleeve 12's surface is provided with warning light 11, sleeve 12 is inside to be provided with compression spring 13, compression spring 13's bottom is provided with heel brace 14, the top of host computer 1 is provided with control panel 7, the surface of control panel 7 is provided with signal module 8, the inside of battery jar 9 is provided with battery 15.

The utility model provides a geography landform survey and drawing unmanned aerial vehicle, fixed block 10 is provided with two altogether, and the fixed slot of two fixed blocks 10 and battery 15 bottom corresponds, connecting rod 4 is provided with four altogether, and four connecting rods 4 install respectively and fix the both sides surface at host computer 1, monitor 3 passes through cloud platform 2 and installs the bottom at host computer 1, and monitor 3 can free angle of adjustment through cloud platform 2, warning light 11 is provided with four altogether, and four warning lights 11 set up respectively at four sleeve 12's front end surface, the inside at sleeve 12 is installed through compression spring 13 to heel brace 14, and heel brace 14 is in sleeve 12's inside free fluctuation, the bottom of heel brace 14 is provided with fixed cushion, and fixed cushion adopts flexible rubber to make inside hollow structure that adopts.

The working principle and the using process of the utility model are as follows: after the unmanned aerial vehicle is installed, the storage battery 15 is charged with electricity through a charging interface at the front end, then a fixing groove at the bottom end of the storage battery 15 is aligned with two fixing blocksinside a battery tank (9) at the bottom end of a host 1 to charge the storage battery 15 with electricity, then the unmanned aerial vehicle is started by using control equipment, a driving machine 5 arranged on a sleeve 12 of a connecting rod 4 at two sides of the unmanned aerial vehicle is started to drive a paddle 6 to run at a high speed to generate airflow to take off the unmanned aerial vehicle, the unmanned aerial vehicle flies to the high altitude of a place to be measured, the ground is effectively surveyed and drawn through a monitoring probe 3 at the bottom end of a holder 2 after the unmanned aerial vehicle takes off, meanwhile, four warning lamps 11 on the surface of the sleeve 12 continuously twinkle in the process of flying at the high altitude to guard surrounding flying objects, then, the data monitored by the unmanned aerial vehicle is transmitted back in real time through a signal module 8 of a control panel 7 at the top end of the host 1, and the unmanned aerial vehicle lands after surveying and drawing, unmanned aerial vehicle descends when uneven ground, the inside compression spring 13 compression deformation of sleeve 12 makes heel brace 14 lift unmanned aerial vehicle off the ground all the time, four independent heel brace 14's deformation, make 1 whole assurance of host computer steady, guarantee that unmanned aerial vehicle's paddle 6 can not cause paddle 6 directly and ground contact at the unevenness of descending in-process field ground, cause unmanned aerial vehicle's damage, compare traditional unmanned aerial vehicle equipment, novel flight adaptability of geographical landform survey and drawing unmanned aerial vehicle at the in-process that uses is stronger, more be fit for field flight survey and drawing work, reduce the damage rate of unmanned aerial vehicle at outdoor flight.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a geographic and geomorphic survey and drawing unmanned aerial vehicle, includes host computer (1) and cloud platform (2), its characterized in that: the device is characterized in that a cradle head (2) is arranged at the bottom end of a host (1), a monitoring probe (3) is arranged at the bottom end of the cradle head (2), a battery groove (9) is arranged on one side of the monitoring probe (3), a fixed block (10) is arranged inside the battery groove (9), a connecting rod (4) is arranged on one side surface of the host (1), a sleeve (12) is arranged at the top end of the connecting rod (4), a driving machine (5) is arranged at the top end of the sleeve (12), a paddle (6) is arranged at the top end of the driving machine (5), a warning lamp (11) is arranged on the surface of the sleeve (12), a compression spring (13) is arranged inside the sleeve (12), a foot support (14) is arranged at the bottom end of the compression spring (13), a control panel (7) is arranged at the top end of the host (1), and a signal module (8) is arranged on the surface of the control panel (7), and a storage battery (15) is arranged in the battery tank (9).

2. A geo-topographic mapping drone according to claim 1, characterized in that: the two fixing blocks (10) are arranged, and the two fixing blocks (10) correspond to the fixing grooves at the bottom end of the storage battery (15).

3. A geo-topographic mapping drone according to claim 1, characterized in that: the four connecting rods (4) are arranged, and the four connecting rods (4) are respectively installed and fixed on the surfaces of the two sides of the host (1).

4. A geo-topographic mapping drone according to claim 1, characterized in that: monitor probe (3) are installed in the bottom of host computer (1) through cloud platform (2), and monitor probe (3) can freely angle regulation through cloud platform (2).

5. A geo-topographic mapping drone according to claim 1, characterized in that: the warning lamps (11) are four in number, and the four warning lamps (11) are arranged on the surfaces of the front ends of the four sleeves (12) respectively.

6. A geo-topographic mapping drone according to claim 1, characterized in that: the foot support (14) is installed inside the sleeve (12) through a compression spring (13), and the foot support (14) freely floats up and down inside the sleeve (12).

7. A geo-topographic mapping drone according to claim 1, characterized in that: the bottom of heel brace (14) is provided with fixed cushion, and fixed cushion adopts flexible rubber to make inside hollow structure that adopts.

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