CN214267957U

CN214267957U - Five pole flapping wing aircraft in space based on just gentle coupling

Info

Publication number: CN214267957U
Application number: CN202022153109.2U
Authority: CN
Inventors: 侯宇; 王强; 金子涵
Original assignee: Wuhan University of Science and Engineering WUSE
Current assignee: Wuhan University of Science and Engineering WUSE
Priority date: 2020-09-27
Filing date: 2020-09-27
Publication date: 2021-09-24
Anticipated expiration: 2030-09-27

Abstract

The utility model discloses a five pole flapping wing aircraft in space based on just gentle coupling, this flapping wing aircraft comprises fuselage, gear drive system, five pole mechanism in space, both sides wing and fin mechanism. The direct current motor drives a gear transmission system, force which is subjected to speed reduction and torque increase is input into the space five-bar mechanism to sequentially drive the first connecting rod, the second connecting rod, the third connecting rod and the fourth connecting rod, and then wings on two sides do regular 8-shaped motion under the action of a flexible ball pair in the space five-bar mechanism; a fourth connecting rod in the space five-rod mechanism is used as a rocker to drive a first wing connecting rod, so that flap motion is realized; the tail wing is driven by two stepping motors, so that the pitching and the steering of the flapping wing air vehicle are realized. The utility model has the characteristics of whole quality is light, the drive is former driving link few, can all realize the imitative nature birds flapping wing aircraft of flapping-twist reverse-wave pendulum-folding coupling, compromise flight efficiency height and practicality height simultaneously.

Description

Five pole flapping wing aircraft in space based on just gentle coupling

Technical Field

The utility model relates to an aircraft technical field specifically is a five pole flapping wing air vehicles in space based on rigid-flexible coupling.

Background

The flapping wing aircraft is a novel miniature aircraft, has extremely high flexibility and high efficiency, and has wide application prospect. The flapping wing aircraft can generate thrust and lift required by flight only by flapping in a special path, so that the aerodynamic characteristics are much higher than those of fixed wing aircraft and rotor aircraft. The flapping wing aircraft can achieve steering and lifting by adjusting the gravity center of the aircraft body through the tail or the wing, and is quicker compared with a mode of a fixed wing and a rotary wing. However, the flapping wing aircraft has been developed relatively late, and most of the time ago, birds in nature were used as a reference, but the aerodynamic characteristics of birds have not been well defined so far. Ornithopters fly in a very low-Relo-number environment, which greatly makes research difficult. In terms of structure, it is also one of the present challenges that an ornithopter is as compact and efficient as possible while meeting the design and installation requirements. The patent (CN201821642577.2) adopts belt transmission as a main torque transmission mode, and because the transmission ratio of the belt transmission is inaccurate, large vibration is easy to generate in flapping of the flapping wing aircraft, and the efficiency is not high. The gear arrangement of the patent (CN201910815338.5) results in an increase in the frontal area of the fuselage, and the wind resistance is also increased at the same time.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a space five-rod flapping wing aircraft based on rigid-flexible coupling, which realizes the four-motion coupling of flapping, swinging, twisting and folding by completely imitating the flying behavior of birds, greatly improves the thrust and lift efficiency of the flapping wing aircraft, and controls the pitching and steering of the flapping wing aircraft by a tail wing mechanism; the unmanned aerial vehicle can pass through places where environments such as dangerous areas, closed spaces, disaster relief sites and the like are complex and even the unmanned aerial vehicle with rotor wings is difficult to complete tasks; the structure has the structural characteristics of rigid-flexible coupling and light overall mass; the flapping-swinging-twisting-bending four-motion coupling improves the motion characteristics of the efficiency of the flapping wing air vehicle; the bionic characteristic is closer to the flight mode of large and medium bird wing wings.

In order to achieve the above object, the utility model provides a following technical scheme: a rigid-flexible coupled space five-rod flapping-wing aircraft comprises an aircraft body, wing mechanisms on two sides, a space five-rod mechanism, a gear transmission system and an empennage mechanism, wherein the aircraft body comprises an aircraft body rack, a front supporting circular frame and a rear supporting circular frame, and the structural strength of the aircraft body is improved.

Preferably, gear drive system includes direct current motor, straight-teeth gear one, straight-teeth gear two, bevel gear one, bevel gear two, gear shaft one and gear shaft two, direct current motor fixes in the frame of the fuselage with the direction parallel with the fuselage, direct current motor's output is connected bevel gear one, a side-mounting of bevel gear one bevel gear two, bevel gear two is fixed gear shaft one, straight-teeth gear one is fixed through interference fit on the gear shaft one, straight-teeth gear one with straight-teeth gear two meshing, straight-teeth gear two is fixed through interference fit on the gear shaft two, the gear shaft two passes shaft hole in the frame of the fuselage articulates. The transmission direction of the torque is changed through a first bevel gear and a second bevel gear, and the torque is further output to the space five-rod mechanism through a first straight gear and a second straight gear, wherein the second bevel gear and the first straight gear are in interference fit with a first gear shaft, and the second straight gear is fixed on the second gear shaft.

Preferably, the space five-bar mechanism comprises a first connecting rod, a second connecting rod, a third connecting rod, a fourth connecting rod and a flexible ball pair, one end of the first connecting rod is fixedly connected with the second gear shaft, the other end of the first connecting rod is hinged to one end of the second connecting rod in a parallel direction, the other end of the second connecting rod is hinged to one end of the third connecting rod in a vertical direction, the first connecting rod, the second connecting rod, the third connecting rod and the fourth connecting rod form a space mechanism, the other end of the third connecting rod is hinged to the middle section of the fourth connecting rod in a parallel direction, the end of the root of the fourth connecting rod is fixedly connected with one end of the flexible ball pair, and the other end of the flexible ball pair is fixed on the machine body frame.

Preferably, the wing mechanisms on the two sides comprise a first wing connecting rod, a second wing connecting rod, a third wing connecting rod and a wing surface supporting rod, one end of the first wing connecting rod is fixed on the fourth connecting rod of the space mechanism, the other end of the first wing connecting rod is hinged with the second wing connecting rod, the second wing connecting rod is hinged with one end of the third wing connecting rod, and the other end of the third wing connecting rod is hinged with the middle section of the third connecting rod of the space mechanism.

Preferably, the empennage mechanism comprises a first stepping motor, a second stepping motor, a first empennage connecting rod, a second empennage connecting rod, a bracket of the stepping motor and an empennage, the first stepping motor is fixed at the middle rear position of the machine body frame, the second stepping motor is fixed on the bracket of the stepping motor, the bracket of the stepping motor is hinged at the tail part of the machine body frame, and the second stepping motor is fixedly connected with the empennage.

Preferably, the whole body of the machine body is of a streamline structure, and the area of the front supporting circular frame is smaller than that of the rear supporting circular frame.

Preferably, the position of each gear is in the direction of the reduction gear.

Preferably, one end of the second wing connecting rod is provided with a branch, and the branch is hinged with the third wing connecting rod.

Preferably, the flight is a cladding.

Compared with the prior art, the beneficial effects of the utility model are that:

1. the utility model discloses used gear drive as power transmission mode, the drive ratio is stable, and the arrangement mode is favorable to putting in the focus and reduces the fuselage windward area.

2. The utility model discloses use five-bar mechanism in space to transmit power for wing mechanism, when can realizing 8 style of calligraphy movements, reduce former moving quantity and whole quality, other mechanisms that can realize 8 style of calligraphy movements of comparing, the utility model discloses the quantity reduces in a large number because of using space mechanism.

3. The utility model discloses use flexible spherical pair more to have the high efficiency than rigid spherical pair, at flapping wing aircraft operation in-process, the wing is repeated the high-speed rotation and is made traditional rigid spherical pair have great friction, and flexible spherical pair then does not have the friction to utilize the resilience force to make the wing return stroke rapider.

4. The utility model has the structural characteristics of rigid-flexible coupling and light overall mass; the flapping-swinging-twisting-bending four-motion coupling improves the motion characteristics of the efficiency of the flapping wing air vehicle; the bionic characteristic is closer to the flight mode of large and medium bird wing wings.

Drawings

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

fig. 2 is a schematic view of the structure of the fuselage according to the present invention;

FIG. 3 is a schematic view of a spatial five-bar mechanism according to the present invention;

fig. 4 is a schematic view of a wing mechanism of the present invention;

fig. 5 is a schematic view of the tail wing mechanism of the present invention.

In the figure: 1-fuselage, 2-wing mechanism, 3-empennage mechanism, 101-fuselage frame, 102-front supporting round frame, 103-rear supporting round frame, 104-direct current motor, 105-bevel gear I, 106-bevel gear II, 107-gear shaft I, 108-spur gear I, 109-spur gear II, 110-gear shaft II, 111-link I, 112-pin shaft I, 113-link II, 114-pin shaft II, 115-link III, 116-pin shaft III, 117-link IV, 118-flexible spherical pair, 201-wing link I, 202-pin shaft IV, 203-wing link II, 204-pin shaft V, 205-wing link III, 206-pin shaft VI, 207-wing supporting rod, 301-stepping motor I, 302-stepping motor II, 303-empennage connecting rod I, 304-pin shaft seven, 305-empennage connecting rod II, 306-pin shaft eight, 307-stepping motor support, 308-pin shaft nine and 309-empennage.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that 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 work belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides an embodiment: a rigid-flexible coupled space five-rod flapping wing aircraft comprises an aircraft body 1, wing mechanisms 2 on two sides, a space five-rod mechanism, a gear transmission system and a tail wing mechanism 3, wherein the aircraft body 1 comprises an aircraft body rack 101, a front supporting circular frame 102 and a rear supporting circular frame 103, and the structural strength of the aircraft body 1 is improved.

In this embodiment: the power transmission system comprises a direct current motor 104 and a bevel gear I105, wherein the model number is as follows: m is 1.5, z is 15, and the model of a bevel gear II 106 is as follows: m is 1.5, z is 25, and the model of a spur gear I108 is as follows: m is 2, z is 10, and the model of a second straight gear 109 is as follows: m is 2, z is 31, the first gear shaft 107 and the second gear shaft 110, and the direct current motor 104 adopts an adjustable speed direct current motor model as follows: 3.7V,800MA,6000r/min, a direct current motor 104 is fixedly connected with a first bevel gear 105, the first bevel gear 105 is meshed with a second bevel gear 106, the taper angle is 90 degrees, the direction of a transmission torque is changed, the second bevel gear 106 is fixedly connected with one end of a first gear shaft 107, the first gear shaft 107 is hinged with the machine body 1 through a hole of the machine body rack 101, a first straight gear 108 is fixedly connected with the other end of the first gear shaft 107 and is meshed with a second straight gear 109, the speed and the torque are further reduced and increased, the second straight gear 109 is fixedly connected with one end of a second gear shaft 110, the second gear shaft 110 is hinged with the machine body 1 through a hole in the machine body rack 101, and the second straight gear 110 serves as a driving part of the space five-rod mechanism.

In this embodiment: as shown in fig. 2, the frame of the fuselage frame 101 is streamlined, which is beneficial to reducing air resistance after the outer packaging layer is paved, and the frame is provided with three shaft holes for hinging other parts, the direct current motor 104 is fixed at the middle rear part of the fuselage frame 101 and is fixed by using a set screw mode, the motor is an object with larger mass in the whole flapping wing aircraft, the flapping wing aircraft is placed at the middle rear part to have a pitch angle, and the bevel gear 105 is fixed with the direct current motor 104 and uses an interference fit mode. The second bevel gear 106 is fixed on the first gear shaft 107 in an interference fit mode, in order to change the power of the first bevel gear 105, the large end face of the second bevel gear 106 faces the outer direction of the machine body frame 101 and is meshed with the first bevel gear 105 in a taper angle of 90 degrees, the first straight gear 108 is fixed on the first gear shaft 107 in an interference fit mode and is meshed with the second straight gear 109, the second straight gear 109 is fixed on the second gear shaft 110 in an interference fit mode, and the second gear shaft 110 is hinged through a shaft hole in the machine body frame 101.

In this embodiment: the space five-bar mechanism comprises a first connecting rod 111, a second connecting rod 113, a third connecting rod 115, a fourth connecting rod 117 and a flexible ball pair 118, wherein one end of the first connecting rod 111 is fixedly connected with a second gear shaft 110 to be used as a crank of the space five-bar mechanism, so that power is transmitted into the space five-bar mechanism, the other end of the first connecting rod 111 is hinged with one end of the second connecting rod 113 in a parallel direction, the other end of the second connecting rod 113 is hinged with one end of the third connecting rod 115 in a vertical direction, the first connecting rod 111, the second connecting rod 113, the third connecting rod 115 and the fourth connecting rod 117 form the space mechanism, the other end of the third connecting rod 115 is hinged with the middle section of the fourth connecting rod 117 in a parallel direction, wherein the fourth connecting rod 117 is a key part and is fixed on the flexible ball pair 118 and fixedly connected with the root of the wing mechanism 2, the flexible ball pair 118 is fixed on the machine frame 101 and fixedly connected with the fourth connecting rod 117, and the flexible ball pair 118 is a rigid ball pair, the kinematic pair has no friction, the aircraft efficiency is higher due to the elastic return force, the space five-bar mechanism on the other side is consistent with the above, the space five-bar mechanism is an RRRRRRS mechanism, and the formula of the degree of freedom is as follows:

F＝6n-5p₅-4p₄-3p₃-2p₂-p₁

substituting the spatial mechanism number value:

F＝6×4-5×4-3×1＝1

therefore, the degree of freedom is one, and the number of the whole prime movers is reduced.

In this embodiment: one end of the first wing connecting rod 201 is fixed with the fourth connecting rod 117 through interference fit, the other end of the first wing connecting rod 201 is hinged with the second wing connecting rod 203 through a fourth pin shaft 202, the second wing connecting rod 203 is provided with a forking connecting rod part, the forking connecting rod part is hinged with one end of the third wing connecting rod 205 through a fifth pin shaft 204, the other end of the third wing connecting rod 205 is hinged with a position hole in the third connecting rod 115 through a sixth pin shaft 206 so as to realize a double-rocker mechanism, and the wing supporting rods 207 are uniformly fixed on the three fixed first wing connecting rods 201 and the five fixed second wing connecting rods 203 through screw and nut modes, so that the soft wing covering layer is conveniently and finally fixed.

In this embodiment, the first step motor 301 is fixed to the frame via a set screw, an output shaft of the first step motor 301 is fixedly connected to one end of a first tail connecting rod 303 via an interference fit, the other end of the first tail connecting rod 303 is hinged to one end of a second tail connecting rod 305 via a seventh pin 304, the other end of the second tail connecting rod 305 is hinged to a frame 307 of the step motor via an eighth pin 306, the frame 307 of the step motor is hinged to the frame via a ninth pin 308, the second step motor 302 is fixed to the frame 307 of the step motor via a set screw, and the output shaft of the second step motor 302 is fixed to the tail 309 via an interference fit.

In this embodiment: the tail fin 309 is a cladding layer instead of a solid material, thereby reducing the mass of the tail fin.

The working principle is as follows: the utility model provides a direct current motor 104 passes through gear drive system, with power transmission to connecting rod 111 on. Further, the first connecting rod 111 drives the second connecting rod 113, the third connecting rod 115 and the fourth connecting rod 117 in the space five-rod mechanism, and the machine body frame 101 in the space five-rod mechanism is a fifth rod and plays a role in fixing; the rotation of a first connecting rod 111 in the space five-rod mechanism enables the flapping wing aircraft to generate flapping motion, and when the first connecting rod 111 rotates, a second connecting rod 113 and a flexible ball pair 118 exist as keys for realizing the torsion and the swing of the flapping wing aircraft; further, a first wing connecting rod 201 is fixed on a fourth connecting rod 117 and serves as a relative frame of the wing double-rocking mechanism, a third connecting rod 115 is provided with a hole which is hinged with a third wing connecting rod 205, the hole is away from the axis of a third pin shaft 116 by a certain distance which serves as the length of an active rocker of the wing double-rocking mechanism, and a second wing connecting rod 203 serves as a passive rocker to realize the folding of the flapping wing; furthermore, a first stepping motor 301 of the tail wing mechanism controls the pitching of the tail wing through a double-rocking mechanism, and a second stepping motor 302 directly controls the rotation of the tail wing 309, so that the turning of the flapping wing aircraft is realized.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. The utility model provides a five pole flapping wing aircraft in space of rigid-flexible coupling which characterized in that: the airplane wing mechanism comprises an airplane body (1), wing mechanisms (2) on two sides, a space five-rod mechanism, a gear transmission system and an empennage mechanism (3), wherein the airplane body (1) comprises an airplane body rack (101), a front supporting circular frame (102) and a rear supporting circular frame (103) which are used for increasing the structural strength of the airplane body (1).

2. A rigid-flexible coupled space five-stick ornithopter according to claim 1, wherein: the gear transmission system comprises a direct current motor (104), a first straight gear (108), a second straight gear (109), a first bevel gear (105), a second bevel gear (106), a first gear shaft (107) and a second gear shaft (110), wherein the direct current motor (104) is fixed on a machine body rack (101) in a direction parallel to a machine body (1), an output end of the direct current motor (104) is connected with the first bevel gear (105), one side of the first bevel gear (105) is provided with the second bevel gear (106), the second bevel gear (106) is fixed on the first gear shaft (107), the first straight gear (108) is fixed on the first gear shaft (107) through interference fit, the first straight gear (108) is meshed with the second straight gear (109), the second straight gear (109) is fixed on the second gear shaft (110) through interference fit, the second gear shaft (110) is hinged through a shaft hole in the machine body rack (101), the transmission direction of the torque is changed through a first bevel gear and a second bevel gear, and the torque is further output to the space five-rod mechanism through a first straight gear and a second straight gear, wherein the second bevel gear and the first straight gear are in interference fit with a first gear shaft, and the second straight gear is fixed on the second gear shaft.

3. A rigid-flexible coupled space five-stick ornithopter according to claim 1, wherein: the space five-bar mechanism comprises a first connecting rod (111), a second connecting rod (113), a third connecting rod (115), a fourth connecting rod (117) and a flexible ball pair (118), one end of the first connecting rod (111) is fixedly connected with the second gear shaft (110), the other end of the first connecting rod (111) is hinged with one end of the second connecting rod (113) in a parallel direction, the other end of the second connecting rod (113) is hinged with one end of the third connecting rod (115) in a vertical direction, the first connecting rod (111), the second connecting rod (113), the third connecting rod (115) and the fourth connecting rod (117) form a space mechanism, the other end of the third connecting rod (115) is hinged with the middle section of the fourth connecting rod (117) in a parallel direction, the root end of the four connecting rods (117) is fixedly connected with one end of a flexible ball pair (118), the other end of the flexible ball pair (118) is fixed on the machine body frame (101).

4. A rigid-flexible coupled space five-stick ornithopter according to claim 3, wherein: the two-side wing mechanism (2) comprises a first wing connecting rod (201), a second wing connecting rod (203), a third wing connecting rod (205) and a wing surface supporting rod (207), one end of the first wing connecting rod (201) is fixed on the fourth connecting rod (117) of the space mechanism, the other end of the first wing connecting rod (201) is hinged to the second wing connecting rod (203), the second wing connecting rod (203) is hinged to one end of the third wing connecting rod (205), and the other end of the third wing connecting rod (205) is hinged to the middle section of the third connecting rod (115) of the space mechanism.

5. A rigid-flexible coupled space five-stick ornithopter according to claim 1, wherein: the empennage mechanism (3) comprises a first stepping motor (301), a second stepping motor (302), a first empennage connecting rod (303), a second empennage connecting rod (305), a bracket of the stepping motor (307) and an empennage (309), the first stepping motor (301) is fixed at the middle rear position of the machine body rack (101), the second stepping motor (302) is fixed on the bracket of the stepping motor (307), the bracket of the stepping motor (307) is hinged at the tail part of the machine body rack (101), and the second stepping motor (302) is fixedly connected with the empennage (309).

6. A rigid-flexible coupled space five-stick ornithopter according to claim 1, wherein: the whole body (1) is of a streamline structure, and the area of the front supporting circular frame (102) is smaller than that of the rear supporting circular frame (103).

7. A rigid-flexible coupled space five-stick ornithopter according to claim 2, wherein: the position of each gear should be in the direction of the reduction drive to mount.

8. A rigid-flexible coupled space five-stick ornithopter according to claim 4, wherein: one end of the second wing connecting rod (203) is provided with a branch, and the branch is hinged with the third wing connecting rod (205).

9. A rigid-flexible coupled space five-stick ornithopter according to claim 5, wherein: the tail fin (309) is a cladding.