CN218537132U - Unmanned aerial vehicle data acquisition device - Google Patents

Abstract

The utility model discloses an unmanned aerial vehicle data acquisition device relates to unmanned air vehicle technical field, including supporting platform, surface mounting has the block terminal on the supporting platform, and surface mounting has a power supply unit on the block terminal, the collection subassembly is installed to supporting platform one side bottom, and supporting platform lateral wall fixedly connected with support, the pivot is installed all around to the supporting platform outer wall, and pivot lateral wall swing joint has a support arm, driving motor is installed to support arm one end, and driving motor top swing joint has a drive shaft, through solar panel, rotary rod and the mutually supporting of oblique pull rod, absorbs solar light source through solar panel, converts solar light source into the leading-in block terminal inner wall of electric current, supplies power for electronic part, utilizes the rotary rod and the support angle of the solar panel of being convenient for adjust of cooperation of oblique pull rod, has solved unmanned aerial vehicle easy outage when long-time operation in the air, and the time of endurance is shorter, has reduced work efficiency's problem.

Description

Unmanned aerial vehicle data acquisition device

Technical Field

The utility model relates to an unmanned air vehicle technique field especially relates to an unmanned aerial vehicle data acquisition device.

Background

The data acquisition of unmanned aerial vehicle is an atmospheric detecting instrument used in the fields of information science and system science, earth science, surveying and mapping science technology and hydraulic engineering, and computer vision is a science for researching how to make a machine "see", and further, it means that a camera and a computer are used to replace human eyes to carry out machine vision such as identification, tracking and measurement on a target, and further image processing is carried out, so that the computer processing becomes an image more suitable for human eyes to observe or transmit to an instrument to detect. As a scientific discipline, computer vision research-related theories and techniques attempt to build artificial intelligence systems that can derive ' information ' from images or multidimensional data, where information referred to herein as Shannon's defined information that can be used to help make a "decision," and since perception can be viewed as extracting information from sensory signals, computer vision can also be viewed as the science of how to cause an artificial system to "perceive" from images or multidimensional data.

The existing data acquisition device for the unmanned aerial vehicle is easy to power off when the unmanned aerial vehicle operates in the air for a long time, the endurance time is short, the working efficiency is reduced, the shooting picture is fuzzy when light is strong, and the practicability is poor, so that the best using effect cannot be achieved.

SUMMERY OF THE UTILITY MODEL

The utility model provides an unmanned aerial vehicle data acquisition device has solved unmanned aerial vehicle and has cut off the power supply easily when long-time operation in the air, and the time of endurance is shorter, has reduced work efficiency, and shoots the picture comparatively fuzzy when light is stronger, and the practicality is relatively poor to can't reach best result of use's technical problem.

For solving the technical problem, the utility model provides a pair of unmanned aerial vehicle data acquisition device, including supporting platform, supporting platform upper surface mounting has the block terminal, and surface mounting has a power supply unit on the block terminal, the collection subassembly is installed to supporting platform one side bottom, and supporting platform lateral wall fixedly connected with support, the pivot is installed all around to the supporting platform outer wall, and pivot lateral wall swing joint has the support arm, driving motor is installed to support arm one end, and driving motor top swing joint has the drive shaft, drive shaft outer wall both sides swing joint has the flabellum.

Preferably, the power supply assembly includes solar panel, power supply assembly upper surface mounting has solar panel, and solar panel center department wears to be equipped with the rotary rod, solar panel bottom swing joint has the diagonal draw bar.

Preferably, solar panel passes through wire and block terminal electric connection, and solar panel specifically adopts monocrystalline silicon solar panel component.

Preferably, the collection subassembly includes rotatory ring, rotatory ring is installed to the collection subassembly lateral wall, and gathers the subassembly outer wall and install the camera, gather the subassembly bottom and install the singlechip, and singlechip lateral wall electric connection has the antenna, gather the subassembly top and install the light screen, and light screen one side fixedly connected with mount pad.

Preferably, the camera is electrically connected with the single chip microcomputer, and the camera specifically adopts an infrared camera component.

Preferably, the specific model of the single chip microcomputer is STC89C51.

Preferably, the specific model of the antenna is an LTE5G antenna.

Compared with the prior art, the utility model provides a pair of unmanned aerial vehicle data acquisition device has following beneficial effect:

the utility model provides a pair of unmanned aerial vehicle data acquisition device, through solar panel, rotary rod and the mutually supporting of oblique pull rod, absorb solar light source through solar panel, convert solar light source into the leading-in block terminal inner wall of electric current, for electronic parts supplies power, utilize the rotary rod to be convenient for adjust the support angle of solar panel with the cooperation of oblique pull rod, solved unmanned aerial vehicle and cut off the power supply easily when long-time operation aloft, the time of endurance is shorter, has reduced work efficiency's problem.

The utility model provides a pair of unmanned aerial vehicle data acquisition device, through rotatory ring, the camera, a single-chip microcomputer, the antenna, the light screen is mutually supported with the mount pad, install the collection subassembly in the supporting platform bottom through the mount pad, utilize the camera to shoot the picture, the leading-in singlechip inner wall of picture that will shoot, carry out analysis processes through the singlechip, utilize the antenna to receive radio signal, be convenient for lead-in computer inner wall of data of singlechip analysis, utilize the light screen to shelter from light to the camera, prevent the polarisation, it is comparatively fuzzy to have solved the shooting picture when light is stronger, the relatively poor problem of practicality.

Drawings

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

fig. 2 is a schematic structural diagram of the power supply assembly of the present invention;

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

fig. 4 is an enlarged view of the driving shaft and the fan blade of the present invention.

In the figure: 1. a support platform; 2. a distribution box; 3. a power supply assembly; 31. a solar panel; 32. rotating the rod; 33. a diagonal member; 4. a collection assembly; 41. a rotating ring; 42. a camera; 43. a single chip microcomputer; 44. an antenna; 45. a visor; 46. a mounting seat; 5. a support; 6. a rotating shaft; 7. a support arm; 8. a drive motor; 9. a drive shaft; 10. a fan blade.

Detailed Description

Embodiment one, given by fig. 1-4, the utility model discloses a supporting platform 1, 1 last surface mounting of supporting platform has block terminal 2, supply power for electronic parts through block terminal 2, and 2 last surface mounting of block terminal have power supply unit 3, collection subassembly 4 is installed to 1 one side bottom of supporting platform, and 1 lateral wall fixedly connected with support 5 of supporting platform, support when unmanned aerial vehicle descends through support 5, supporting platform 1 outer wall installs pivot 6 all around, be convenient for adjust the position angle of support arm 7 through pivot 6, and 6 lateral walls swing joint of pivot has support arm 7, support flabellum 10 through support arm 7, driving motor 8 is installed to 7 one end of support arm, and driving motor 8 top swing joint has drive shaft 9, 9 outer wall both sides swing joint of drive shaft has flabellum 10, it rotates to take off drive flabellum 10 through the cooperation of driving motor 8 with drive shaft 9, the work of being convenient for.

Power supply unit 3 includes solar panel 31, 3 surface mounting of power supply unit has solar panel 31, and solar panel 31 center department wears to be equipped with rotary rod 32, solar panel 31 bottom swing joint has oblique pull rod 33, absorb the solar light source through solar panel 31, convert the solar light source into the leading-in 2 inner walls of block terminal of electric current, supply power for electronic parts, utilize rotary rod 32 and the cooperation of oblique pull rod 33 to be convenient for adjust solar panel 31's support angle, solar panel 31 passes through wire and 2 electric connection of block terminal, and solar panel 31 specifically adopts monocrystalline silicon solar panel component, it is corrosion-resistant, and the maintenance cost is reduced.

Gather subassembly 4 including rotatory ring 41, gather subassembly 4 lateral wall and install rotatory ring 41, and gather subassembly 4 outer wall and install camera 42, gather subassembly 4 bottom and install singlechip 43, and singlechip 43 lateral wall electric connection has antenna 44, gather subassembly 4 top and install light screen 45, and light screen 45 one side fixedly connected with mount pad 46, will gather subassembly 4 and install in supporting platform 1 bottom through mount pad 46, utilize camera 42 to shoot the picture, the leading-in singlechip 43 inner wall of the picture that will shoot, carry out analysis processes through singlechip 43, utilize antenna 44 to receive radio signal, be convenient for guide-in computer inner wall with the data of singlechip 43 analysis, utilize light screen 45 to shelter from light to camera 42, prevent the polarisation, camera 42 and singlechip 43 electric connection, and camera 42 specifically adopts the infrared camera component, it is clearer to shoot the picture, the work efficiency is improved, the specific model of singlechip 43 is STC89C51, voltage output is stable, therefore, the clothes hanger is strong in practicability, the specific model of antenna 44 is LTE5G antenna, signal reception is more stable, and durable.

The working principle is as follows: during the use, absorb the solar light source through solar panel 31, convert the solar light source into the leading-in 2 inner walls of block terminal of electric current, supply power for electronic parts, utilize rotary rod 32 and oblique pull rod 33's cooperation to be convenient for adjust solar panel 31's support angle, install collection component 4 in supporting platform 1 bottom through mount pad 46, utilize camera 42 to shoot the picture, the leading-in singlechip 43 inner wall of picture that will shoot, carry out analysis processes through singlechip 43, utilize antenna 44 to receive radio signal, be convenient for the leading-in computer inner wall of data of singlechip 43 analysis, utilize light screen 45 to shelter from light to camera 42, prevent the polarisation, support when unmanned aerial vehicle descends through support 5, be convenient for adjust the position angle of support arm 7 through pivot 6, support flabellum 10 through support arm 7, drive flabellum 10 through the cooperation of driving motor 8 with drive shaft 9 and rotate, the work of taking off is convenient for.

It should be noted that the distribution box 2, the solar panel 31, the camera 42, the single chip 43, the antenna 44, the driving motor 8, and the fan blades 10 are devices or apparatuses existing in the prior art, or devices or apparatuses that can be realized in the prior art, and the composition and the principle thereof will be clear to those skilled in the art, and therefore will not be described in detail.

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 invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides an unmanned aerial vehicle data acquisition device, includes supporting platform (1), its characterized in that: support platform (1) upper surface mounting has block terminal (2), and block terminal (2) upper surface mounting has power supply unit (3), collection subassembly (4) are installed to support platform (1) one side bottom, and support platform (1) lateral wall fixedly connected with support (5), pivot (6) are installed all around to support platform (1) outer wall, and pivot (6) lateral wall swing joint has support arm (7), driving motor (8) are installed to support arm (7) one end, and driving motor (8) top swing joint has drive shaft (9), drive shaft (9) outer wall both sides swing joint has flabellum (10).

2. The unmanned aerial vehicle data acquisition device of claim 1, characterized in that, power supply unit (3) includes solar panel (31), surface mounting has solar panel (31) on power supply unit (3), and solar panel (31) center is worn to be equipped with rotary rod (32), solar panel (31) bottom swing joint has oblique pull rod (33).

3. An unmanned aerial vehicle data acquisition device according to claim 2, wherein the solar panel (31) is electrically connected with the distribution box (2) through a wire, and the solar panel (31) specifically adopts a monocrystalline silicon solar panel component.

4. The unmanned aerial vehicle data acquisition device of claim 1, wherein the collection component (4) comprises a rotating ring (41), the rotating ring (41) is installed on the outer side wall of the collection component (4), the camera (42) is installed on the outer wall of the collection component (4), the single chip microcomputer (43) is installed at the bottom end of the collection component (4), the antenna (44) is electrically connected to the outer side wall of the single chip microcomputer (43), the light screen (45) is installed at the top end of the collection component (4), and the mounting seat (46) is fixedly connected to one side of the light screen (45).

5. An unmanned aerial vehicle data acquisition device of claim 4, characterized in that, camera (42) and singlechip (43) electric connection, and camera (42) specifically adopts infrared camera component.

6. A unmanned aerial vehicle data collection device according to claim 4, wherein the specific model of the single chip microcomputer (43) is STC89C51.

7. A drone data collection device according to claim 4, characterised in that the specific model of the antenna (44) is an LTE5G antenna.

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