CN113725584A

CN113725584A - Unmanned aerial vehicle 5G antenna structure that anti-wind reliability is high

Info

Publication number: CN113725584A
Application number: CN202111049822.5A
Authority: CN
Inventors: 盛会洁; 刘芸; 宋浩; 王生龙
Original assignee: Kunshan Rcd Electronics Co ltd
Current assignee: Kunshan Rcd Electronics Co ltd
Priority date: 2021-09-08
Filing date: 2021-09-08
Publication date: 2021-11-30

Abstract

The invention discloses an unmanned aerial vehicle 5G antenna structure with high wind resistance and reliability, and particularly relates to the technical field of unmanned aerial vehicle antennas. According to the invention, the frame plate is arranged on the outer side of the antenna body, and the rack is driven to move up and down through the meshing of the rack and the gear, so that the antenna body on the mounting plate is driven to move out of the bottom of the frame plate, and the filter bag on the outer side of the antenna body can play a role in protecting the antenna body and also can play a role in ventilating and radiating, so that the antenna body has a better wind-resistant effect and higher use strength.

Description

Unmanned aerial vehicle 5G antenna structure that anti-wind reliability is high

Technical Field

The utility model relates to an unmanned aerial vehicle antenna technology field especially relates to an unmanned aerial vehicle 5G antenna structure that wind-resistant reliability is high.

Background

At present, with the continuous perfection of living facilities, when people need to check the ground, people always hold a scanning instrument to scan and check the ground, because of large area, the manual scanning is time-consuming and labor-consuming, and some errors exist, with the continuous development of scientific technology, the existing ground scanning is checked generally in an unmanned aerial vehicle mode, an unmanned aerial vehicle is an airplane without a driver, the unmanned aerial vehicle can be large or small in size according to the use, and can be used for aerial reconnaissance, communication, pesticide spraying and the like, the unmanned aerial vehicle is controlled by using a radio remote control device and a control device, the unmanned aerial vehicle is generally provided with an antenna device to ensure that the unmanned aerial vehicle transmits information through the antenna device, and the unmanned aerial vehicle receives signals by using an antenna, in recent years, with the continuous development of unmanned aerial vehicle technology, unmanned aerial vehicle's flight ability and all kinds of functional characteristic are constantly perfect and strengthen, and correspondingly, unmanned aerial vehicle's communication system has also obtained higher development, and along with the popularization of 5G signal, unmanned aerial vehicle's remote control communication intensity is stronger, and the control scope is farther, the operation is got up more accurately.

The antenna for the existing unmanned aerial vehicle is generally directly connected with the interface thread on the unmanned aerial vehicle, and then is used, when encountering strong wind or other severe environments, the antenna can be rocked on the unmanned aerial vehicle to collide with the unmanned aerial vehicle and then be damaged, and the influence is on the signal receiving.

Disclosure of Invention

The utility model discloses an aim at provides an unmanned aerial vehicle 5G antenna structure that anti-wind reliability is high, can make the unmanned aerial vehicle antenna anti-wind more when using, and it is more reliable to use.

To achieve the purpose, the following technical scheme is adopted in the disclosure: an unmanned aerial vehicle 5G antenna structure with high wind resistance and reliability comprises an antenna body and a frame plate, wherein the antenna body is arranged in the frame plate, heat-conducting plates are embedded on two sides of an inner cavity of the frame plate, a first sliding groove and a second sliding groove are respectively formed in the inner wall surfaces of the two heat-conducting plates, the first sliding groove and the second sliding groove extend to the bottom of the frame plate, a sliding block is arranged in the first sliding groove, a rack is arranged in the second sliding groove, a mounting plate is arranged between the rack and the sliding block, a port is formed in the mounting plate, a first threaded hole is formed in the center surface of the bottom of the mounting plate, a screw rod is connected in the first threaded hole, the bottom of the screw rod is fixedly connected with the top of the antenna body, a second threaded hole is formed in the outer wall surface of the bottom of the mounting plate, a first annular plate is connected in the second threaded hole, and a second annular plate is connected in the first annular plate through threads, the antenna comprises an antenna body, a first ring plate and a second ring plate, wherein the first ring plate is fixedly arranged on the outer wall of the antenna body, the second ring plate is fixedly arranged on the outer wall of the antenna body, the filter bag is arranged on the outer side of the antenna body, a storage cavity is formed in one side of a second sliding groove, a micro motor is fixedly arranged in the storage cavity, a gear is fixedly arranged on the front side of an output shaft of the micro motor, the gear is arranged on one side of a rack and meshed with the rack, and a baffle is hinged to the bottom of the frame plate.

In a preferred embodiment, the inside of both sides of the frame plate is provided with an air cavity, the outer wall surfaces of both sides of the frame plate are provided with air inlet grooves, the air inlet grooves are internally and fixedly provided with first filter cloth, the bottom parts of the outer wall surfaces of both sides of the frame plate are provided with air outlet grooves, and the air outlet grooves are internally and fixedly provided with second filter cloth.

In a preferred embodiment, a limiting groove is formed in the surface of the top of the baffle, a roller is arranged in the limiting groove, a U-shaped frame is arranged on the outer side of the roller, the roller is connected with the U-shaped frame through a bearing, and the top of the U-shaped frame is fixedly connected with the bottom of the sliding block.

In a preferred embodiment, two grooves which are symmetrical front and back are formed in the surface of the outer wall of the bottom of one side of the frame plate, elastic ropes are arranged in the grooves, one end of each elastic rope is fixedly connected with the inner wall of each groove, and the other end of each elastic rope is fixedly connected with the surface of the top of the baffle.

In a preferred embodiment, the top surface of the baffle is fixedly provided with a first magic tape, the bottom surface of the frame plate is fixedly provided with a second magic tape, and the second magic tape is adhered to the first magic tape.

In a preferred embodiment, slots are formed in the inner wall surfaces of the rack and the sliding block, and two insertion blocks are arranged in the two slots and are respectively fixedly arranged on the outer walls of the two sides of the mounting plate.

In a preferred embodiment, the outer wall surface of the first annular plate and the outer wall surface of the second annular plate are both processed with external threads, the inner wall surface of the first annular plate is processed with internal threads, the first annular plate is in threaded connection with the second threaded hole through the external threads, and the second annular plate is in threaded connection with the first annular plate through the external threads and the internal threads.

In a preferred embodiment, a fixing plate is fixedly arranged on the top of the outer wall of each of the two sides of the frame plate, and a screw is connected to the fixing plate through a thread.

The beneficial effect of this disclosure does:

1. according to the invention, the frame plate is arranged on the outer side of the antenna body, and the rack is driven to move up and down through the meshing of the rack and the gear, so that the antenna body on the mounting plate is driven to move out of the bottom of the frame plate, and the filter bag on the outer side of the antenna body can play a role in protecting the antenna body and also can play a role in ventilating and radiating, so that the antenna body has a better wind-resistant effect and higher use strength.

2. Through all having seted up the air cavity in the frame plate both sides, air inlet duct and air outlet duct have all been seted up on frame plate both sides outer wall surface, wind enters into the air cavity from the air inlet duct, then discharge through air outlet duct, the heat that antenna body work produced is transmitted to the air cavity in through the heat-conducting plate, then blow away the heat by the wind of blowing in, play the radiating effect to antenna body, and air inlet duct and air outlet duct in first filter cloth and the second filter cloth can filter the air, avoid the dust impurity in the air to cause the jam in entering into the air cavity.

3. Through be provided with the gyro wheel on the slider, the slider is when the downstream, the gyro wheel rolls at the spacing inslot, promote the downward upset of baffle and open, make antenna body and filter bag stretch out from the framework and use, the baffle is connected with the deckle board through two stretch cords, the stretch cord has elasticity, pull the baffle, after not using the antenna body, the antenna body moves again in the deckle board, pull the baffle again under the drive of stretch cord and laminate bottom the deckle board, first magic subsides on the baffle and the bonding of second magic subsides of deckle board bottom, make the baffle play sealed effect to the deckle board.

4. Insert the mounting panel between slider and rack through using the inserted block, after using for a long time, can open the baffle, dismantle slider and rack from the framed panel, then detach mounting panel and slider, rack, unscrew first crown plate from the second screw hole on the mounting panel again, unscrew the second crown plate from first crown plate at last again, just can inspect the change to the antenna body, ensure the normal operating of antenna body.

Drawings

Fig. 1 is the structural schematic diagram when this disclosure provides is connected with unmanned aerial vehicle.

Fig. 2 is a front cross-sectional view of a bezel of the present disclosure.

Fig. 3 is a top cross-sectional view of a frame plate of the present disclosure.

Fig. 4 is a cross-sectional view of a groove of the present disclosure.

FIG. 5 is a cross-sectional view of a mounting plate of the present disclosure.

FIG. 6 is a front view of a filter bag of the present disclosure.

Fig. 7 is a front view of the bezel of the present disclosure with the bezel open.

In the figure: 1. an antenna body; 2. a frame plate; 3. a heat conducting plate; 4. a first chute; 5. a second chute; 6. a slider; 7. a rack; 8. mounting a plate; 9. an interface; 10. a first threaded hole; 11. a screw; 12. a second threaded hole; 13. a first ring plate; 14. a second ring plate; 15. a filter bag; 16. a storage chamber; 17. a micro motor; 18. a gear; 19. a baffle plate; 20. an air cavity; 21. an air inlet groove; 22. a first filter cloth; 23. an air outlet groove; 24. a second filter cloth; 25. a limiting groove; 26. a roller; 27. a U-shaped frame; 28. a groove; 29. an elastic cord; 30. a first magic tape; 31. a second magic tape; 32. a slot; 33. inserting a block; 34. a fixing plate; 35. and (4) screws.

Detailed Description

Referring to the attached drawings 1-7 of the specification, the unmanned aerial vehicle 5G antenna structure with high wind resistance and high reliability in the embodiment comprises an antenna body 1 and a frame plate 2, wherein the antenna body 1 is arranged in the frame plate 2, the frame plate 2 is used for protecting the antenna body 1 to prevent the antenna body 1 from being damaged by collision of an external object, heat conducting plates 3 are embedded at two sides of an inner cavity of the frame plate 2 to play a role in conducting heat, a first sliding chute 4 and a second sliding chute 5 are respectively arranged on the inner wall surfaces of the two heat conducting plates 3, the first sliding chute 4 and the second sliding chute 5 extend to the bottom of the frame plate 2, a sliding block 6 is arranged in the first sliding chute 4, a rack 7 is arranged in the second sliding chute 5, a mounting plate 8 is arranged between the rack 7 and the sliding block 6 and used for mounting the antenna body 1 and a filter bag 15, an interface 9 is arranged in the mounting plate 8, a first threaded hole 10 is arranged on the surface of the center of the bottom of the mounting plate 8, a screw 11 is connected with the first threaded hole 10 through an internal thread, the bottom of the screw 11 is fixedly connected with the top of the antenna body 1, a second threaded hole 12 is formed in the outer wall surface of the bottom of the mounting plate 8, a first ring plate 13 is connected with the second threaded hole 12 through an internal thread, a second ring plate 14 is connected with the first ring plate 13 through an internal thread, a filter bag 15 is fixedly arranged on the outer wall of the second ring plate 14, the filter bag 15 is conveniently detached from the mounting plate 8 for cleaning, the filter bag 15 is arranged on the outer side of the antenna body 1, a storage cavity 16 is formed in one side of the second chute 5, a micro motor 17 is fixedly arranged in the storage cavity 16 and driven by the micro motor 17 to realize automatic operation, a gear 18 is fixedly arranged on the front side of an output shaft of the micro motor 17, the gear 18 is arranged on one side of the rack 7 and meshed with the rack 7, and a baffle 19 is hinged to the bottom of the frame plate 2, the sealing function is achieved.

2 both sides outer wall tops of deckle board are all fixed and are equipped with fixed

plate

34, 34 threaded connection of fixed plate has screw 35 for be connected whole equipment and unmanned aerial vehicle and use.

The implementation scenario is specifically as follows: when the unmanned aerial vehicle is used, the frame plate 2 is installed on the unmanned aerial vehicle through the screw 35 on the fixing plate 34, and then the unmanned aerial vehicle can be used, a worker controls the micro motor 17 in the storage cavity 16 through the remote control device to drive the gear 18 to rotate, the gear 18 rotates to be meshed with the rack 7 to drive the rack 7 to move downwards, so as to drive the installation plate 8 and the slider 6 to move downwards together, the roller 26 at the bottom of the slider 6 pushes the baffle 19 to turn over and open when the slider 6 moves, the filter bag 15 and the antenna body 1 extend out of the frame plate 2, and then the unmanned aerial vehicle is controlled to take off to be used, the filter bag 15 plays a role in protecting the outer side of the antenna body 1, the filter bag 15 can ventilate, the heat on the antenna body 1 is taken away by wind, the antenna body 1 plays a role in heat dissipation, and the extending height of the antenna body 1 can be adjusted through the engagement of the micro motor 17, the gear 18 and the rack 7 as required, the use is more convenient.

Referring to the accompanying

drawings

1, 2, 3 and 7 in the specification, the 5G antenna structure of the unmanned aerial vehicle with high wind resistance and reliability in the embodiment has the advantages that the air cavities 20 are formed in the two sides of the frame plate 2, the air inlet grooves 21 are formed in the outer wall surfaces of the two sides of the frame plate 2, the first filter cloth 22 is fixedly arranged in the air inlet grooves 21, the air outlet grooves 23 are formed in the bottoms of the outer wall surfaces of the two sides of the frame plate 2, the second filter cloth 24 is fixedly arranged in the air outlet grooves 23, and the first filter cloth 22 and the second filter cloth 24 are used for filtering air to prevent dust and impurities from entering the air cavities 20 to affect the heat dissipation effect.

The implementation scenario is specifically as follows: when using unmanned aerial vehicle, because unmanned aerial vehicle flies at a high speed, external wind flows to air cavity 20 from air inlet duct 21 on framed panel 2 in, the heat that antenna body 1 work produced transmits to air cavity 20 in through heat-conducting plate 3 in framed panel 2, blow off through wind and discharge heat from air outlet duct 23, play the effect of heat dissipation cooling, through being equipped with first filter cloth 22 in air inlet duct 21, be equipped with second filter cloth 24 in air outlet duct 23, can filter gas, avoid dust impurity in the air to enter into air cavity 20 and cause the jam, give off to cause the influence thermal, utilize wind to dispel the heat to antenna body 1, other electronic equipment that need not reuse dispels the heat, the radiating effect is better, the consumption of electric energy has significantly reduced.

Referring to the accompanying

drawings

2, 4 and 7 in the specification, in the unmanned aerial vehicle 5G antenna structure with high wind resistance and reliability, the top surface of the baffle plate 19 is provided with a limiting groove 25, a roller 26 is arranged in the limiting groove 25, a U-shaped frame 27 is arranged on the outer side of the roller 26, the roller 26 is connected with the U-shaped frame 27 through a bearing, the top of the U-shaped frame 27 is fixedly connected with the bottom of the slider 6, when the roller 26 contacts with the baffle plate 19, the baffle plate 19 is pushed to turn downwards to be opened, friction between the roller 26 and the baffle plate 19 is rolling friction, and resistance between the roller 26 and the baffle plate 19 can be greatly reduced.

Two symmetrical recesses 28 around are seted up to panel 2 one side bottom outer wall surface, be equipped with stretch cord 29 in the recess 28, stretch cord 29 one end and recess 28 inner wall fixed connection, stretch cord 29 other end and baffle 19 top fixed surface are connected, and stretch cord 29 has elasticity, and when moving antenna body 1 in the panel 2, stretch cord 29 pulling baffle 19 is automatic to be shifted up and is laminated with panel 2, realizes automated operation.

19 top fixed surface of baffle is equipped with first magic subsides 30, 2 bottom fixed surface of framed panel are equipped with second magic subsides 31, second magic subsides 31 and first magic subsides 30 bond, make more firm of being connected between baffle 19 and the framed panel 2 to the convenience is opened baffle 19 from framed panel 2 bottom and is used.

The implementation scenario is specifically as follows: when needs stretch out antenna body 1, it is rotatory to start micro motor 17 and drive gear 18, gear 18 is rotatory to drive rack 7 and moves down, thereby it moves down together with slider 6 to drive antenna body 1 on the mounting panel 8, stretch out from the bottom of framework 2, when needs move antenna body 1 to in the framework 2 again, only need to drive micro motor 17 reverse rotation, it just can to drive rack 7 rebound, gyro wheel 26 follows slider 6 and also shifts up together, the pressure that baffle 19 received reduces, be close to towards the bottom of framework 2 under the drive of stretch cord 29, first magic subsides 30 on the baffle 19 bond with the second magic subsides 31 of framework 2 bottom, make fixing of baffle 19 play at framework 2 firmly, play the effect of sealed protection.

Referring to the attached drawings 2-6 of the specification, the unmanned aerial vehicle 5G antenna structure with high wind resistance and reliability of the embodiment has the advantages that the inner wall surfaces of the rack 7 and the slider 6 are provided with the slots 32, the two slots 32 are provided with the insertion blocks 33, the two insertion blocks 33 are respectively fixedly arranged on the outer walls of the two sides of the mounting plate 8, the mounting plate 8 is conveniently detached from the position between the slider 6 and the rack 7, and the antenna body 1 and the filter bag 15 on the mounting plate 8 are detached.

The outer wall surface of the first annular plate 13 and the outer wall surface of the second annular plate 14 are both provided with external threads, the inner wall surface of the first annular plate 13 is provided with internal threads, the first annular plate 13 is in threaded connection with the second threaded hole 12 through the external threads, the second annular plate 14 is in threaded connection with the first annular plate 13 through the external threads and the internal threads, and therefore a worker can conveniently detach the filter bag 15 from the mounting plate 8 to clean and replace the filter bag.

The implementation scenario is specifically as follows: when not using unmanned aerial vehicle, can dismantle screw 35 on the fixed plate 34 with unmanned aerial vehicle separately, then it is rotatory to start micro motor 17 and drive gear 18, make rack 7 shift out from the bottom of framed panel 2, with slider 6, rack 7, mounting panel 8 is whole to be torn down from framed panel 2, then it is separately with mounting panel 8 and slider 6 and rack 7, rotatory first crown plate 13 is twisted out from second screw hole 12, twist out from first crown plate 13 again rotatory second crown plate 14, just can take filter bag 15 from mounting panel 8, clear up the change to filter bag 15, screw rod 11 on the rotatory antenna body 1 of staff at last is twisted out from first screw hole 10, just can inspect antenna body 1 and change, moreover, the steam generator is simple in structure, conveniently clear up a device of dress.

Claims

1. The utility model provides an unmanned aerial vehicle 5G antenna structure that anti-wind reliability is high, includes antenna body (1) and deckle board (2), establish in deckle board (2) antenna body (1), its characterized in that: the heat-conducting plates (3) are embedded on two sides of the inner cavity of the frame plate (2), the inner wall surfaces of the two heat-conducting plates (3) are respectively provided with a first sliding groove (4) and a second sliding groove (5), the first sliding groove (4) and the second sliding groove (5) both extend to the bottom of the frame plate (2), a sliding block (6) is arranged in the first sliding groove (4), a rack (7) is arranged in the second sliding groove (5), a mounting plate (8) is arranged between the rack (7) and the sliding block (6), an interface (9) is arranged inside the mounting plate (8), a first threaded hole (10) is formed in the surface of the center of the bottom of the mounting plate (8), a threaded rod (11) is connected with the inner thread of the first threaded hole (10), the bottom of the threaded rod (11) is fixedly connected with the top of the antenna body (1), and a second threaded hole (12) is formed in the outer wall surface of the bottom of the mounting plate (8), second screw hole (12) female connection has first crown plate (13), first crown plate (13) internal thread is connected with second crown plate (14), second crown plate (14) outer wall is fixed and is equipped with filter bag (15), establish in the antenna body (1) outside filter bag (15), storing chamber (16) have been seted up to second spout (5) one side, storing chamber (16) internal fixation is equipped with micro motor (17), micro motor (17) output shaft front side is fixed and is equipped with gear (18), gear (18) are established in rack (7) one side and are engaged with rack (7) mutually, frame (2) bottom articulates there is baffle (19).

2. The unmanned aerial vehicle 5G antenna structure of claim 1, wherein the structure is characterized in that: air cavities (20) are formed in the two sides of the frame plate (2), air inlet grooves (21) are formed in the outer wall surfaces of the two sides of the frame plate (2), first filter cloth (22) is fixedly arranged in the air inlet grooves (21), air outlet grooves (23) are formed in the bottoms of the outer wall surfaces of the two sides of the frame plate (2), and second filter cloth (24) is fixedly arranged in the air outlet grooves (23).

3. The unmanned aerial vehicle 5G antenna structure of claim 1, wherein the structure is characterized in that: limiting groove (25) have been seted up on baffle (19) top surface, be equipped with gyro wheel (26) in limiting groove (25), the gyro wheel (26) outside is equipped with U-shaped frame (27), gyro wheel (26) are connected with U-shaped frame (27) through the bearing, U-shaped frame (27) top and slider (6) bottom fixed connection.

4. The unmanned aerial vehicle 5G antenna structure of claim 1, wherein the structure is characterized in that: two symmetrical front and back grooves (28) are formed in the surface of the outer wall of the bottom of one side of the frame plate (2), an elastic rope (29) is arranged in each groove (28), one end of each elastic rope (29) is fixedly connected with the inner wall of each groove (28), and the other end of each elastic rope (29) is fixedly connected with the surface of the top of the baffle plate (19).

5. The unmanned aerial vehicle 5G antenna structure of claim 1, wherein the structure is characterized in that: baffle (19) top fixed surface is equipped with first magic subsides (30), framed board (2) bottom fixed surface is equipped with second magic subsides (31), second magic subsides (31) bond with first magic subsides (30).

6. The unmanned aerial vehicle 5G antenna structure of claim 1, wherein the structure is characterized in that: slots (32) are formed in the inner wall surfaces of the rack (7) and the sliding block (6), inserting blocks (33) are arranged in the two slots (32), and the two inserting blocks (33) are fixedly arranged on the outer walls of the two sides of the mounting plate (8) respectively.

7. The unmanned aerial vehicle 5G antenna structure of claim 1, wherein the structure is characterized in that: the outer wall surface of the first annular plate (13) and the outer wall surface of the second annular plate (14) are both provided with external threads, the inner wall surface of the first annular plate (13) is provided with internal threads, the first annular plate (13) is in threaded connection with the second threaded hole (12) through the external threads, and the second annular plate (14) is in threaded connection with the first annular plate (13) through the external threads and the internal threads.

8. The unmanned aerial vehicle 5G antenna structure of claim 1, wherein the structure is characterized in that: the frame plate is characterized in that fixing plates (34) are fixedly arranged at the tops of the outer walls of the two sides of the frame plate (2), and screws (35) are connected to the inner threads of the fixing plates (34).