CN211844881U - Wing tip connecting structure of combined unmanned aerial vehicle - Google Patents

Abstract

The utility model discloses a modular unmanned aerial vehicle's wingtip connection structure, include: a guide rail is arranged in the chord direction of a first wingtip of each single machine in the combined unmanned aerial vehicle, and a clamping groove is arranged in the chord direction of a second wingtip of each single machine; the flexible connecting assembly is arranged in the guide rail and moves along the guide rail under the action of external force; the rotary electromagnetic damper is arranged inside the clamping groove; the rotary electromagnetic damper is connected with the flexible connecting assembly in a matched mode, and flexible connection of wingtips among different single machines is achieved; the head of the rigid pin is provided with a taper and is arranged on the first wingtip; the hole opening of the pin hole is provided with a taper and is arranged on the second wing tip; and the rigid pin and the pin hole are connected in a matched manner, so that the rigid connection of wing tips among different single machines is realized. The utility model discloses a this combination formula unmanned aerial vehicle's wingtip connection structure, can be according to wind-force size automatically regulated flexonics or rigid connection, have advantages such as the mode of connection is nimble variable, convenient operation, stability are strong.

Description

Wing tip connecting structure of combined unmanned aerial vehicle

Technical Field

The utility model relates to an aircraft technical field especially relates to a modular unmanned aerial vehicle's wingtip connection structure.

Background

The small-sized fixed wing unmanned aerial vehicle (with the wingspan between 0.5m and 2 m) has the characteristics of small size, light weight, low cost, convenience in operation, flexibility, low noise, good concealment, easiness in networking and the like, and has wide application prospects in the civil and military fields, such as urban short-distance logistics transportation, electric power inspection, disaster monitoring and investigation, swarm operation, distributed reconnaissance and the like. However, the stability and wind resistance of the airplane are relatively weak due to the light weight and small inertia of the single drone platform. In addition, the small-sized fixed wing unmanned aerial vehicle is small in aspect ratio and large in induced resistance, so that the voyage and the time of voyage are shortened, and the long-distance flight task in long voyage is not favorably executed. Based on bionics and aerodynamic principles, an effective solution is to connect the wing tips of a plurality of small-sized fixed-wing drones together to form a detachable combined fixed-wing drone.

The connection technology between two adjacent unmanned aerial vehicle wings is the key technology of the combined unmanned aerial vehicle. The existing connection mode mainly comprises magnetic rigid connection and mechanical rigid connection, the unmanned aerial vehicle combined through the rigid connection mode is equivalent to an unmanned aerial vehicle with a large aspect ratio, the advantage is that the range can be prolonged, and the most outstanding problem is poor wind resistance. Moreover, the rigid connection can make the wing tip part bear large aerodynamic load, and the fracture accident is easy to happen.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a modular unmanned aerial vehicle's wingtip connection structure, the technical problem who proposes above has been solved at least partially.

The specific technical scheme is as follows:

the utility model provides a modular unmanned aerial vehicle's wingtip connection structure mainly includes:

a guide rail is arranged in the chord direction of a first wingtip of each single machine in the combined unmanned aerial vehicle, and a clamping groove is arranged in the chord direction of a second wingtip of each single machine;

the flexible connecting assembly is arranged in the guide rail and moves left and right along the guide rail under the action of external force;

the rotary electromagnetic damper is arranged inside the clamping groove;

the rotary electromagnetic damper is in adaptive connection with the flexible connecting assembly, so that the flexible connection of wingtips among different single machines is realized; and

the head of the rigid pin is provided with a taper and is arranged on the first wing tip;

the hole opening of the pin hole is provided with a taper and is arranged on the second wing tip;

and the rigid pin and the pin hole are connected in a matched manner, so that the rigid connection of wing tips among different single machines is realized.

In some embodiments, the rail further comprises, inside:

the stepping motor is fixed at the bottom of the guide rail;

the screw pair comprises a screw rod and a screw nut, the screw rod is connected with the stepping motor through a coupler, and the screw nut is fixedly connected with the flexible connecting assembly.

Further, the flexible connection assembly includes:

the left connecting sheet is connected to the screw nut;

the flexible hollow column is sleeved on the lead screw, and in some embodiments, the flexible hollow column is made of an elastic rubber material;

and the right connecting piece is connected with a boss, in some embodiments, the boss is an outer hexagonal boss, and the outer hexagonal boss is made of a magnetic conductive material.

In some embodiments, the above-described rotary electromagnetic damper comprises:

the rotating part is matched and connected with the boss of the flexible connecting component, further, the rear end of the rotating part is also connected with a plane spiral spring, and the plane spiral spring and the rotary electromagnetic damper are installed in the clamping groove after being connected;

the fixing part is used for fixing the rotary electromagnetic damper in the clamping groove;

and the limiting pin controls the maximum pitch angle of the combined unmanned aerial vehicle during flexible connection between the single units.

In some embodiments, the wingtip connection between the single units of the combined unmanned aerial vehicle is automatically adjusted to be flexible connection or rigid connection according to the wind speed, and the strength of the flexible connection is automatically adjusted according to the grade of wind power.

In some embodiments, when the rotary electromagnetic damper is electrified, the rotary part generates electromagnetic force, and the attraction connection between the rotary part and the boss of the flexible connecting component is realized through the action of the electromagnetic force; when the rotary electromagnetic damper is powered off, the electromagnetic force disappears, and the connection between the rotating part and the boss is disconnected.

The utility model provides a wing tip connection structure of this combination formula unmanned aerial vehicle compares with other techniques, has following beneficial effect:

(1) the utility model adds the flexible connection mode of the wing tip, and the flexible connection eliminates the defect of easy fracture in the prior rigid connection;

(2) the utility model realizes a novel wingtip connection mode by combining flexible connection and rigid connection, gives play to the best flight performance of the unmanned aerial vehicle assembly through the conversion of rigid connection and flexible connection, can realize automatic adjustment of connection flexibility according to different wind power grades, and realizes vibration reduction and self-stabilization by adopting a rotary electromagnetic damper and a plane volute spiral spring;

(3) the utility model is provided with the rotary electromagnetic damper, which can absorb the energy generated by gust in the rotating process and play the role of buffering and damping, thereby inhibiting the maximum overshoot of the pitching angle of the unmanned aerial vehicle and preventing the unmanned aerial vehicle from stalling; the utility model is also provided with a plane volute spiral spring, and the pitch angle difference between two adjacent unmanned aerial vehicles can be offset by means of the restoring moment of the spring;

(4) the utility model discloses a wingtip connection structure has rigid connection and flexonics's advantage concurrently. During the taking-off and cruising stages, the wings of a plurality of unmanned aerial vehicles are connected together, and when no wind exists or the wind power is small, the wings of two adjacent unmanned aerial vehicles are rigidly connected through positioning pins and electromagnets, so that the voyage and the voyage are prolonged; when a large gust of wind occurs, the flexible connection between the two wings is realized through the flexible connection assembly, so that the wind resistance of the unmanned aerial vehicle assembly is improved;

(5) the utility model discloses a wing tip connection structure, at the task execution stage, with rotatory electromagnetic damper outage, realize disassembling between the unmanned aerial vehicle, every unmanned aerial vehicle carries out the task alone, has advantages such as connected mode is variable, easy operation, the function is complete, stability height.

Drawings

Fig. 1 is an exploded view of an assembly of a wing tip attachment structure according to an embodiment of the present invention;

fig. 2 is a schematic view of a connection end surface of a left wing in the wing tip connection structure according to an embodiment of the present invention;

fig. 3 is a schematic connection end surface view of a right wing in a wing tip connection structure according to an embodiment of the present invention;

fig. 4 is a schematic view of a flexible connection assembly according to an embodiment of the present invention;

FIGS. 5A-5B are schematic views of a rotary electromagnetic damper according to an embodiment of the present invention;

fig. 6 is a schematic combination diagram of a rigid connection between two wings of the combined type unmanned aerial vehicle according to an embodiment of the present invention;

fig. 7 is a schematic diagram of a rigid combination applied to a plurality of small unmanned aerial vehicles according to an embodiment of the present invention;

fig. 8 is a schematic combination diagram of a flexible connection between two wings of the combined type unmanned aerial vehicle according to an embodiment of the present invention;

fig. 9 is a schematic view of a flexible assembly applied to a plurality of small unmanned aerial vehicles according to an embodiment of the present invention;

fig. 10 is a schematic view of the combined unmanned aerial vehicle after the wing tip is disassembled in the power-off state.

In the figure:

left wing 1 stepping motor 2 coupling 3

Lead screw 4, lead screw nut 5 and flexible connecting assembly 6

Rotary electromagnetic damper 7 plane scroll spring 8 right wing 9

Rigid pin 11, 13 guide rail 12 pin hole 91, 93

Flexible hollow column 62 of left connecting sheet 61 of clamping groove 92

Rotating part 71 of outer hexagonal boss 64 of right connecting piece 63

The rotation limit pins 72, 73 fix the fixing portions 75 of the limit pins 74

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the present invention will be described in further detail with reference to the accompanying drawings, and the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

The device technology designed by the utility model enables the combined unmanned aerial vehicle to be combined and disassembled as required, rigid connection is adopted when no wind exists or the wind power is low, two wings of adjacent unmanned aerial vehicles are tightly connected together through the positioning pin and the electromagnet, and the voyage can be improved to the maximum extent; when a large gust of wind occurs, the two wings are in flexible connection, and the influence of the gust of wind on the stability of the unmanned aerial vehicle can be well eliminated through the flexible combination body, the rotary electromagnetic damper and the planar spiral spring; when the unmanned aerial vehicle reaches a task area to execute a task, the two unmanned aerial vehicles are disassembled in the air through electromagnetic force control, and each unmanned aerial vehicle independently executes a set task.

In view of this, an embodiment of the utility model provides a wing tip connection structure of this combination formula unmanned aerial vehicle, include:

a guide rail is arranged in the chord direction of a first wingtip of each single machine in the combined unmanned aerial vehicle, and a clamping groove is arranged in the chord direction of a second wingtip of each single machine;

the flexible connecting assembly is arranged in the guide rail and moves left and right along the guide rail under the action of external force;

the rotary electromagnetic damper is arranged inside the clamping groove;

and the rotary electromagnetic damper is in adaptive connection with the flexible connecting component, so that the flexible connection of wingtips among different units is realized.

It should be noted that, in this embodiment, the first wingtip and the second wingtip respectively represent wingtips of wings on two sides of one single machine, and in a specific implementation process, a guide rail or a clamping groove is arranged on the first wingtip, or a clamping groove or a guide rail is arranged on the second wingtip, which is not particularly limited.

Based on above embodiment, this combination formula unmanned aerial vehicle's wingtip connection structure in this embodiment can still include:

the head of the rigid pin is provided with a taper and is arranged on the first wing tip;

the hole opening of the pin hole is provided with a taper and is arranged on the second wing tip;

and the rigid pin and the pin hole are connected in a matched manner, so that the rigid connection of wing tips among different single machines is realized.

It should be noted that, in this embodiment, a rigid pin or a rigid pin hole is provided on the first wing tip, or a rigid pin hole or a rigid pin is provided on the second wing tip, which is also not limited, and the purpose of this embodiment is the same as that of the above embodiment, and is to implement rigid connection between the single units in the combined unmanned aerial vehicle through connection between the rigid pin and the rigid pin hole. Further, when the flexible connecting assembly is completely located inside the guide rail (i.e. the length of the flexible connecting assembly exposed to the guide rail is 0), the connection between the flexible connecting assembly in the guide rail and the rotating electromagnetic damper in the slot can also be used as a rigid connection mode. In some embodiments, the two rigid connections described herein may be combined or may be independent.

Based on the above embodiment, further, wherein, the guide rail further includes inside the guide rail:

the stepping motor is fixed at the bottom of the guide rail;

the screw pair comprises a screw rod and a screw nut, the screw rod is connected with the stepping motor through a coupler, and the screw nut is fixedly connected with the flexible connecting assembly.

It should be noted that the stepping motor and the screw pair are only one embodiment, and any embodiment that can realize the left-right movement of the flexible connecting assembly along the guide rail can be replaced.

In some embodiments, the rotary electromagnetic damper is further connected to a flat spiral spring, and the flat spiral spring and the rotary electromagnetic damper are both installed in the slot after being connected.

The present embodiment and the application scenario thereof will be further explained with reference to fig. 1 to 10.

Referring to fig. 1, the present embodiment is composed of a left wing 1, a micro stepping motor 2, a coupling 3, a lead screw 4, a lead screw nut 5, a flexible connection assembly 6, a rotary electromagnetic damper 7, a flat spiral spring 8, a right wing 9, and the like. It should be noted that the left wing 1 and the right wing 9 are the first wingtip and the second wingtip, the guide rail 12 is disposed on the left wing 1, and the slot 92 is disposed on the right wing 9.

Referring to fig. 1 and 2 again, the specific implementation manner of the flexible connecting assembly 6 moving left and right along the guide rail 12 is as follows: the micro stepping motor 2 is fixed in the guide rail 12 of the left wing 1, and drives the screw rod 4 to rotate through the coupler 3. The screw pair formed by the screw 4 and the screw nut 5 can change the rotation of the screw 4 into the movement of the screw nut 5 in the guide rail 12. One end of the flexible connecting assembly 6 is fixedly connected with the screw nut 5, and the movement of the screw nut 5 is controlled along with the rotation of the screw 4 so as to control the flexible connecting assembly 6 to move left and right in the wing guide rail. The parts (including the micro stepping motor 2, the coupler 3, the lead screw 4, the lead screw nut 5 and the flexible connecting assembly 6) described herein all belong to the mounting assembly on the left wing 1.

Referring to fig. 1 and 3 again, the rotary electromagnetic damper 7 and the flat spiral spring 8 are connected and then installed in the installation slot 92 of the right wing 9.

In some embodiments, the flexible connection assembly further comprises:

the left connecting sheet is connected to the screw nut;

the flexible hollow column is sleeved on the lead screw, and in some embodiments, the flexible hollow column is made of an elastic rubber material;

and the right connecting piece is connected with a boss, in some embodiments, the boss is an outer hexagonal boss, and the outer hexagonal boss is made of a magnetic conductive material.

In this embodiment, referring to fig. 4, the flexible connecting assembly 6 is formed by connecting a left connecting piece 61, a flexible hollow column 62, a right connecting piece 63 and an outer hexagonal boss 64. The left connecting sheet 61 and the right connecting sheet 63 are made of engineering plastics, so that the weight can be effectively reduced; the flexible hollow column 62 is made of hollow elastic rubber, and the material can transmit force and moment in three directions of pitching, rolling and yawing between two adjacent unmanned aerial vehicles and has good rebound and buffering vibration reduction effects; the outer hexagonal boss 64 is made of a magnetically permeable material. It should be noted that, the boss is preferably an outer hexagonal boss, but in the specific implementation, the shape and structure of the boss are not limited, and other polygonal bosses may be used.

In some embodiments, the above-described rotary electromagnetic damper comprises:

the rotating part is matched and connected with the boss of the flexible connecting assembly;

the fixing part is used for fixing the rotary electromagnetic damper in the clamping groove;

and the limiting pin controls the maximum pitch angle of the combined unmanned aerial vehicle during flexible connection between the single units.

In this embodiment, referring to fig. 5, the rotary electromagnetic damper 7 is mainly composed of a rotating portion 71, a fixed portion 75, rotary limit pins 72 and 73, and a fixed limit pin 74. The damping torque of the rotary electromagnetic damper changes with a change in the rotational speed of the rotating portion 71. The change rule is as follows: the rotating speed is increased, and the damping torque is also increased; the rotation speed is slowed down, and the damping torque is reduced. The rotary electromagnetic damper 7 can be completely embedded in the installation clamping groove 92 of the wing 9, and has no exposed part, so that the interference resistance is reduced.

Based on the above embodiment, referring to fig. 4, 5A and 5B again, the outer hexagonal boss 64 and the rotating portion 71 (here, the inner hexagonal groove forms a profile) of the rotary electromagnetic damper cooperate to transmit force and circumferential torque between two adjacent wings of the drone. When the rotary electromagnetic damper 7 is energized, the rotary portion 71 thereof generates electromagnetic force, and is tightly attracted to the outer hexagonal boss 64, so that it can transmit force in the axial direction. After the power is cut off, the outer hexagonal boss 64 and the rotating portion 71 can be separated by a weak external force. It should be noted that the structure of the rotating portion 71 of the rotating electromagnetic damper 71 changes with the structure of the boss of the flexible connecting assembly 6, and it is only necessary to ensure that the two structures can be connected in a matching manner.

It is right to combine above-mentioned embodiment below the utility model discloses combination formula unmanned aerial vehicle's wing tip connection structure's concrete compound mode does detailed description.

Generally, the specific combination mode is realized based on the following principles:

in the taking-off and cruising phases, wings of a plurality of unmanned aerial vehicles are connected together to run, fly, rotate and fly horizontally. When no wind exists or the wind power is small, adjacent unmanned aerial vehicles are in rigid connection, and a plurality of small unmanned aerial vehicles are combined into the unmanned aerial vehicle with the large aspect ratio; when meeting great unstable wind, flight controller controls step motor according to the wind speed information that airborne atmospheric data sensor surveyed and rotates, makes flexible hollow post stretch out the guide rail, and assembly unmanned aerial vehicle wing coupling mechanism turns into flexonics, according to the different connection flexibility of the automatic transform of wind-force level (in certain extent, wind-force is flexible big more greatly). There may be relative torsion within a limited angle between adjacent drones in the three rotational degrees of freedom directions.

The main advantages of this combination are:

when no wind exists or the wind power is small, gust wind has a weak influence on the stability of the unmanned aerial vehicle, and the unmanned aerial vehicles can greatly improve the aspect ratio, reduce the induced resistance and improve the lift-drag ratio through the tight rigid connection, so that the voyage and voyage are improved to the maximum extent; when a large gust of wind occurs, the influence of the gust of wind on the stability of the unmanned aerial vehicle can be well relieved through the flexible part and the damping spring mechanism at the connecting part, so that the overall wind resistance is improved;

in the task execution stage, the unmanned aerial vehicle is changed into a plurality of independent small unmanned aerial vehicles through a disassembling mechanism, and tasks are executed respectively.

Specifically, based on the above principle:

in some embodiments, the wingtip connection between the single units of the combined unmanned aerial vehicle is automatically adjusted to be flexible connection or rigid connection according to the wind speed, and the strength of the flexible connection is automatically adjusted according to the grade of wind power.

In this embodiment, for the rigid connection mode, rigid connection of the wing is realized by matching the two pins with tapered heads and the pin holes with tapered holes arranged in the chord direction of the end surface of the wing with the magnetic force of the rotating electromagnetic damper 7. Specifically, referring to fig. 2, 3 and 6, when there is no wind or the wind is small, the wing tips of two adjacent drones can be rigidly connected. Fig. 2 shows 11 and 13, which are two rigid pins on the left wing 1, and the heads of the pins are provided with certain tapers. Fig. 3 shows 91 and 93 two pin holes in right wing 9, with a taper. The purpose of the taper design is to guide the pin and the hole to fit smoothly within a certain range of non-concentricity. Fig. 6 is a schematic diagram of rigid connection between two wings, in which the rotary electromagnetic damper 7 is powered on, and the rotating portion 71 is tightly engaged with the outer hexagonal boss 64 of the flexible connecting member 6. The micro stepping motor 2 drives the screw rod 4 to rotate, further drives the screw rod nut 5, the flexible connecting component 6, the rotary electromagnetic damper 7 and the right wing 9 to move towards the left wing 1, finally the end faces of the two wings are tightly attached, and the rigid pins 11 and 13 are inserted into the pin holes 91 and 93, so that six degrees of freedom of relative movement of the two wings are limited, and rigid connection is achieved.

Based on the rigid connection mode, please refer to fig. 7 again, which is a schematic diagram of rigid connection of multiple unmanned aerial vehicles, the wing ends of adjacent unmanned aerial vehicles are tightly attached, all wings are kept on one plane, which is equivalent to one large aspect ratio unmanned aerial vehicle, the combined mode can reduce the tip vortex loss to the maximum extent, increase the lift-drag ratio, and thus improve the voyage and the time of voyage.

In this embodiment, to rigidity commentaries on classics flexonics, when meetting the gust, miniature step motor 2 is rotatory, makes flexonics subassembly 6 stretch out left wing, realizes the flexonics between two unmanned aerial vehicles. Specifically, referring to fig. 8, when a large gust of wind is encountered, the two wings are converted into a flexible connection. The rotary electromagnetic damper 7 keeps the electrified state and is attracted with the flexible connecting component 6, so that the wing 1 and the wing 9 are connected together. The micro stepping motor 2 drives the screw rod 4 to rotate reversely, and then pushes the screw rod nut 5 to move outwards, so that the flexible connecting component 6 extends out of the wing 1. The transmission of forces and moments between the two wings is now mainly dependent on the flexible hollow column 62 of the elastic transmission assembly 6.

Specifically, when meetting great gust, the unmanned aerial vehicle of gust position department receives the interference, and pitch angle speed can grow rapidly, and at this moment the rotatory electromagnetic damper 7 on the unmanned aerial vehicle of adjacent both sides can produce the great damping torque of opposite direction and prevent that the pitch angle continues to increase to guarantee the stability of whole assembly. Meanwhile, disturbance rotation kinetic energy can be consumed through the rotary motion of the rotary electromagnetic damper 7, so that the combined body quickly tends to a stable state. The center of the flat spiral spring 8 is connected with the rear end of the rotating part 71 of the rotary electromagnetic damper 7, and a pitching restoring moment can be generated, so that the pitching angles of two adjacent unmanned aerial vehicles are kept consistent. If the damping torque of rotatory electromagnetic damper 7 itself is not enough to offset the pitching moment that the gust produced, through the biggest angle of pitch of spacing pin control, prevent that unmanned aerial vehicle stall from falling.

It should be noted that, the extension length of the flexible hollow column 62 can be controlled by controlling the rotation angle of the micro stepping motor 2, that is, the flexible size of the connection is controlled, and then the size of the transmission force and the moment between two adjacent unmanned aerial vehicles can be adjusted: the longer the extension length is, the greater the flexibility is, and the weaker the torque transmission capacity is; the shorter the extension, the weaker the flexibility and the stronger the torque transmission capability; when the protrusion amount is 0, the rigid connection is degraded.

In this embodiment, for the flexible connection mode, please refer to fig. 9, which is a schematic diagram of a flexible combination of multiple small unmanned aerial vehicles, the unmanned aerial vehicles are connected together through a flexible assembly, and adjacent unmanned aerial vehicles can rotate relatively in three directions of rolling, pitching and yawing.

In some embodiments, when the rotary electromagnetic damper is electrified, the rotary part generates electromagnetic force, and the attraction connection between the rotary part and the boss of the flexible connecting component is realized through the action of the electromagnetic force; when the rotary electromagnetic damper is powered off, the electromagnetic force disappears, and the connection between the rotating part and the boss is disconnected.

In this embodiment, when a task needs to be executed, please refer to fig. 10, which is a schematic view of a wing tip part of a disassembled unmanned aerial vehicle assembly, the rotary electromagnetic damper 7 is powered off, and the outer hexagonal boss 64 and the rotating part 71 can be separated under the action of weak external force, so that the combined unmanned aerial vehicle can be disassembled in the air. After disassembly, the micro stepping motor 2 rotates to drive the flexible connecting assembly 6 to retract into the guide rail groove of the left wing 1, and interference resistance of the wing is reduced.

This is so far accomplished the utility model discloses a wing tip connection structure about combination formula unmanned aerial vehicle and implementation's embodiment describes.

The above description is only the preferred embodiment of the present invention, and the protection scope of the present invention is not limited thereto, and any modification, improvement and equivalent replacement made within the spirit and principle of the present invention should be covered within the protection scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (10)

1. The utility model provides a modular unmanned aerial vehicle's wingtip connection structure which characterized in that includes:

arranging a guide rail in the chord direction of a first wingtip of each single machine in the combined unmanned aerial vehicle, and arranging a clamping groove in the chord direction of a second wingtip of each single machine;

the flexible connecting assembly is arranged in the guide rail and moves left and right along the guide rail under the action of external force;

the rotary electromagnetic damper is arranged inside the clamping groove;

and the rotary electromagnetic damper is in adaptive connection with the flexible connecting component, so that the flexible connection of wingtips between different units is realized.

2. The wingtip connection structure of the combined unmanned aerial vehicle of claim 1, further comprising:

the head of the rigid pin is provided with a taper and is arranged on the first wing tip;

the hole opening of the pin hole is provided with a taper and is arranged on the second wing tip;

and the rigid pin is in adaptive connection with the pin hole, so that rigid connection of wing tips among different single machines is realized.

3. The wingtip connection structure of the combined unmanned aerial vehicle as claimed in claim 2, wherein the guide rail further comprises:

the stepping motor is fixed at the bottom of the guide rail;

the screw pair comprises a screw rod and a screw nut, the screw rod is connected with the stepping motor through a coupler, and the screw nut is fixedly connected with the flexible connecting assembly.

4. The wingtip connection structure of the combined unmanned aerial vehicle of claim 3, wherein the flexible connection assembly comprises:

the left connecting sheet is connected to the screw nut;

the flexible hollow column is sleeved on the lead screw;

the right connecting piece is connected with a boss.

5. The wingtip connection structure of the combined unmanned aerial vehicle of claim 4, wherein the flexible hollow column is made of an elastic rubber material.

6. The wing tip connection structure of the combined unmanned aerial vehicle of claim 4, wherein the boss is an outer hexagonal boss, and the outer hexagonal boss is made of a magnetic conductive material.

7. The wingtip connection structure of the combined unmanned aerial vehicle of claim 4, wherein the rotary electromagnetic damper comprises:

the rotating part is matched and connected with the boss of the flexible connecting assembly;

the fixing part is used for fixing the rotary electromagnetic damper in the clamping groove;

and the limiting pin controls the maximum pitch angle of the combined unmanned aerial vehicle during flexible connection between the single units.

8. The wingtip connection structure of the combined unmanned aerial vehicle as claimed in claim 7, wherein a spiral spring is further connected to a rear end of the rotation portion, and the spiral spring and the rotary electromagnetic damper are installed in the slot after being connected.

9. The wingtip connection structure of the combined unmanned aerial vehicle as claimed in claim 8, wherein the wingtip connection between the units of the combined unmanned aerial vehicle is automatically adjusted to be flexible connection or rigid connection according to the wind speed, and the strength of the flexible connection is automatically adjusted according to the grade of wind power.

10. The wingtip connection structure of the combined unmanned aerial vehicle of claim 9, wherein:

when the rotary electromagnetic damper is electrified, a rotating part of the rotary electromagnetic damper generates electromagnetic force, and the rotating part is connected with the boss of the flexible connecting component in an attracting mode under the action of the electromagnetic force;

when the rotary electromagnetic damper is powered off, the electromagnetic force disappears, and the connection between the rotating part and the boss is disconnected.

Images