阅读说明：本技术 一种能自主起飞的扑旋翼飞行器 (Flapping rotor aircraft capable of taking off automatically ) 是由 侯宇 江厚清 王强 蒋怡蔚 李浩男 金子涵 于 2021-08-18 设计创作，主要内容包括：本发明涉及一种能自主起飞的扑旋翼飞行器。其技术方案是：所述扑旋翼飞行器的机身中部(11)前端通过两侧连接板(10)与头部(9)固定连接,机身中部(11)的后端与尾杆(12)固定连接；前起落架(2)固定在两侧连接板(10)的下部,驱动机构(3)安装在两侧连接板(10)的中间位置处,两个机翼(4)对称地安装在两侧连接板(10)的外侧,后起落架(5)安装在机身中部(11)的下部靠后处,涵道风扇系统(6)安装在机身中部(11)的后端,尾翼(7)安装在尾杆(12)的末端。驱动机构(3)完成机翼(4)的扑动扭转折叠运动。涵道风扇系统(6)实现飞行器的转向升降并提供动力。本发明具有驱动原动件少、能实现扑动-折叠-扭转三耦合运动、飞行速度快、升降力大和能自主起飞的特点。(The invention relates to a flapping rotor wing aircraft capable of taking off automatically. The technical scheme is as follows: the front end of the middle part (11) of the flapping rotor wing aircraft body is fixedly connected with the head part (9) through connecting plates (10) at two sides, and the rear end of the middle part (11) of the aircraft body is fixedly connected with the tail rod (12); the aircraft is characterized in that a front undercarriage (2) is fixed on the lower portions of two side connecting plates (10), a driving mechanism (3) is installed in the middle of the two side connecting plates (10), two wings (4) are symmetrically installed on the outer sides of the two side connecting plates (10), a rear undercarriage (5) is installed at the lower portion, close to the rear, of a middle portion (11) of an aircraft body, a ducted fan system (6) is installed at the rear end of the middle portion (11) of the aircraft body, and a tail wing (7) is installed at the tail end of a tail rod (12). The driving mechanism (3) completes flapping, twisting and folding movement of the wings (4). The ducted fan system (6) achieves steering lifting of the aircraft and provides power. The invention has the characteristics of few driving motive power parts, capability of realizing flapping-folding-twisting three-coupling motion, high flying speed, large lifting force and capability of taking off automatically.)

1. The utility model provides a can independently take off pounce rotor craft which characterized in that: firstly, setting the head of an aircraft to be the front, the left side facing the head of the aircraft to be the left side, and the right side facing the head of the aircraft to be the right side; the left and right directions are transverse and the front and back directions are longitudinal;

the flapping rotor wing aircraft capable of taking off automatically consists of an aircraft body (1), a nose landing gear (2), a driving mechanism (3), wings (4), a rear landing gear (5), a ducted fan system (6), an empennage (7) and a model airplane receiver (8);

the machine body (1) consists of a head (9), two connecting plates (10), a machine body middle part (11) and a tail rod (12); the head (9) is connected with the front end of the middle part (11) of the machine body through connecting plates (10) at two sides, the middle position of the rear end of the middle part (11) of the machine body is fixedly connected with the position, close to the front end, of the tail rod (12), and a rectangular plate connecting hole is formed in the front end of the tail rod (12);

the aircraft is characterized in that a front undercarriage (2) is fixed at the lower parts of two side connecting plates (10), a driving mechanism (3) is installed in the middle of the two side connecting plates (10), two wings (4) are symmetrically installed on the outer sides of the two side connecting plates (10), a rear undercarriage (5) is installed at the lower part of the middle part (11) of the aircraft body close to the rear part, a ducted fan system (6) is installed at the rear end of the middle part (11) of the aircraft body, and a tail wing (7) is installed at the tail end of a tail rod (12);

the head part (9) consists of an arc-shaped frame (13), a bevel gear fixing rod (14) and a machine head fixing rod (16); the arc-shaped frame (13) is a whole consisting of an arc-shaped rod, a vertical rod and a horizontal rod, the rear end of the arc-shaped rod is integrated with the upper end of the vertical rod, and the front end of the arc-shaped rod is integrated with the front end of the horizontal rod; the lower ends of the two vertical rods are symmetrically fixed at two sides of the handpiece fixing rod (16) close to the middle part, and the rear ends of the horizontal rods are symmetrically fixed at two ends of the bevel gear fixing rod (14) close to the two ends; bevel gear shafts (15) are symmetrically fixed on the bevel gear fixing rod (14), and the two bevel gear shafts (15) are respectively abutted against the inner walls of the corresponding horizontal rods;

in the head (9):

the vertical distance h between the handpiece fixing rod (16) and the bevel gear fixing rod (14)₁=0.8~0.9h₀，

Horizontal distance l between the handpiece fixing rod (16) and the bevel gear fixing rod (14)₁=0.3~0.4l₀，

Distance b between two arc-shaped rods₁=0.5~0.6b₀；

Wherein:

h₀indicating the height of the vertical pole, mm,

l₀indicating the length, in mm,

b₀the length, mm, of the handpiece fixed rod (16) and the bevel gear fixed rod (14);

the connecting plate (10) is a quadrilateral flat plate surrounded by a front bevel edge (17), a middle bevel edge (21), a rear bevel edge (26) and a long bevel edge (28); the included angle between the front bevel edge (17) and the middle bevel edge (21) is an obtuse angle, and the included angle between the rear bevel edge (26) and the middle bevel edge (21) is an obtuse angle;

in the quadrilateral flat plate:

a bevel gear fixing rod hole (19) is arranged at the included angle of the front bevel edge (17) and the middle bevel edge (21),

a nose landing gear mounting hole (18) is arranged at the included angle of the front bevel edge (17) and the long bevel edge (28),

a torsion bar hole (23) is arranged at the included angle of the middle bevel edge (21) and the rear bevel edge (26),

a second machine body fixing rod hole (27) is arranged at the included angle of the rear inclined edge (26) and the long inclined edge (28),

a torsion shaft hole (24) is arranged at the middle position of the torsion rod hole (23) and the second machine body fixing rod hole (27),

a first body fixing rod hole (25) is arranged at a position close to the second body fixing rod hole (27),

a transmission rotating shaft hole (20) is arranged at the middle position of the quadrilateral flat plate close to the front part,

a head fixing rod hole (22) is arranged at the middle part of the quadrilateral flat plate, the head fixing rod hole (22) is close to the middle bevel edge (21),

a bevel gear fixing rod (14) provided with a head (9) is fixed in the bevel gear fixing rod hole (19),

a head fixing rod (16) provided with a head (9) is fixed in the head fixing rod hole (22);

the middle part (11) of the machine body consists of two parallelogram racks (29), a second quadrilateral fixed rod (35), a first quadrilateral fixed rod (34), a first machine body fixed rod (31) and a second machine body fixed rod (32), wherein the second quadrilateral fixed rod, the first quadrilateral fixed rod and the second quadrilateral fixed rod are respectively one; the parallelogram frame (29) is an integral body consisting of two parallel diagonal members and two parallel long members, and the included angle between the front diagonal member and the lower long member of the parallelogram frame (29) is an acute angle; a second quadrilateral fixing rod (35) and a first quadrilateral fixing rod (34) are sequentially fixed at an acute angle at the rear part and an obtuse angle at the rear part of the two parallelogram racks (29), rear landing gear mounting holes (33) are symmetrically arranged in front of the first quadrilateral fixing rod (34), two motor mounting holes (30) are symmetrically arranged at the acute angle at the front parts of the two parallelogram racks (29), a second body fixing rod (32) is fixed at the obtuse angle at the front parts of the two parallelogram racks (29), and a first body fixing rod (31) is fixed at the upper part of the forward bevel edges of the two parallelogram racks (29);

a tail rod (12) is fixed at the middle position of a second quadrilateral fixing rod (35) in the middle part (11) of the machine body, and the central line of the tail rod (12) is vertical to the second quadrilateral fixing rod (35);

a first machine body fixing rod (31) is fixedly arranged in the first machine body fixing rod holes (25) of the two connecting plates (10),

a second body fixing rod (32) is fixedly arranged in the second body fixing rod holes (27) of the two connecting plates (10);

the nose landing gear (2) consists of a nose landing gear universal wheel (36) and a nose landing gear cross bar (37), and the nose landing gear universal wheels (36) are symmetrically arranged at two ends close to the nose landing gear cross bar (37); two ends of a nose landing gear cross frame rod (37) are respectively and fixedly arranged in nose landing gear mounting holes (18) of the corresponding connecting plates (10);

the driving mechanism (3) consists of a twisting mechanism (38), a driving motor (39) and a flapping folding mechanism (40); the driving motor (39) consists of a double-head motor (41) and four small belt pulleys (42); two small belt pulleys (42) are symmetrically arranged on output shafts at two ends of the double-head motor (41), and frame connecting holes (43) are symmetrically arranged at two ends of a shell of the double-head motor (41); the screws are in threaded connection with the corresponding rack connecting holes (43) through the motor mounting holes (30) of the two parallelogram racks (29);

the torsion mechanism (38) consists of two first large belt pulleys (44), two torsion shafts (45), a cylindrical sliding block (46), a guide rod (47) and a torsion rod (48);

first large belt pulleys (44) are symmetrically arranged at the positions, close to the outer ends, of the two torsion shafts (45), torsion eccentric shafts (50) are arranged on the inner end faces of the two torsion shafts (45), the two torsion eccentric shafts (50) are correspondingly connected with eccentric round holes (51) arranged at the two sides of the cylindrical sliding block (46), and the axes of the two torsion shafts (45) are the same straight line; the cylindrical sliding block (46) is movably sleeved at one end of the guide rod (47), the other end of the guide rod (47) is fixedly connected with the middle position of the torsion rod (48), and wing connecting holes (49) are formed in two ends of the torsion rod (48); the outer ends of the two torsion shafts (45) are respectively arranged in the torsion shaft holes (24) of the connecting plate (10); the torsion bar (48) is arranged in a torsion bar hole (23) of the connecting plate (10);

the flapping folding mechanism (40) consists of a second large belt pulley (52), a transmission shaft (53), a double-sided bevel gear (54), a crank bevel gear (55), a flapping folding connecting rod (56) and a track rod (57);

second large belt pulleys (52) are symmetrically arranged at the positions, close to the two ends, of the transmission shaft (53), double-sided bevel gears (54) are arranged at the middle positions of the transmission shaft (53), and the bevel teeth on the two sides of each double-sided bevel gear (54) are respectively meshed with the corresponding two crank bevel gears (55); connecting rod eccentric shafts (60) are symmetrically arranged on the same side face of the bevel gear of the crank bevel gear (55), the lower ends of the two flapping folding connecting rods (56) are movably connected with the connecting rod eccentric shafts (60), the upper ends of the two flapping folding connecting rods (56) are respectively movably connected with the lower end of a track rod (57) through track rod pin shafts (58), and the upper end of the track rod (57) is provided with a track rod connecting hole (59); the axial line of the connecting rod eccentric shaft (60) is mutually vertical to the central line of the track rod connecting hole (59) in space;

two ends of the transmission shaft (53) are movably arranged in the transmission rotating shaft holes (20) of the two connecting plates (10); the two crank bevel gears (55) are respectively and movably mounted with two bevel gear shafts (15) of the bevel gear fixing rod (14);

two small belt pulleys (42) of output shafts at two ends of the double-head motor (41) are respectively and correspondingly connected with a first large belt pulley (44) of the torsion mechanism (38) and a second large belt pulley (52) of the flapping folding mechanism (40) through respective belts;

the wing (4) consists of a plane four-bar mechanism (61), an inner wing (63) and an outer wing (67), and the inner wing (63) and the outer wing (67) are movably connected together through the plane four-bar mechanism (61);

the plane four-bar mechanism (61) consists of a transmission rod (64), a wing connecting rod (62), an inner wing rod (65) and an outer wing rod (66); the transmission rod (64) is formed by bending a straight rod into two straight rods, the included angle of the two straight rods is 150-170 degrees, and wing hinge holes (71) are formed in the included angle of the two straight rods; the wing hinge hole (71) is hinged with one end of a wing connecting rod (62) through a pin shaft, the other end of the wing connecting rod (62) is hinged with one end of an inner wing rod (65) through a pin shaft of an inner wing connecting rod pin shaft hole (70), and the other end of the inner wing rod (65) is hinged with the bend angle of an outer wing rod (66) through a pin shaft; the outer wing rod (66) is an L-shaped rod piece formed by a long rod and a short rod, the short rod end of the L-shaped rod piece is hinged with the left end of the transmission rod (64) through a pin shaft, and a track rod connecting shaft (68) is coaxially arranged on the right end face of the transmission rod (64); the track rod connecting shaft (68) is connected with the track rod connecting hole (59);

the long rod body of the outer wing rod (66) of the plane four-bar mechanism (61) is fixedly connected with the lower surface of the outer wing (67), and the long rod body of the outer wing rod (66) is close to the front side edge of the outer wing (67); the body of the inner wing rod (65) is fixedly connected with the lower surface of the inner wing (63), and the body of the inner wing rod (65) is close to the front side edge of the inner wing (63);

a C-shaped groove is arranged on the inner side surface of the inner wing (63) close to the front side, wing pin shaft holes are symmetrically formed in the opening end of the C-shaped groove, and wing pin shafts (69) are movably connected with the wing pin shaft holes; a torsion rod (48) of the torsion mechanism (38) is provided with a wing connecting hole (49) which is hinged with a wing pin shaft (69);

the rear landing gear (5) consists of a rear landing gear universal wheel (72) and a rear landing gear transverse frame (73); the axle of the universal wheel (72) of the rear landing gear is fixedly connected with the middle position of a transverse frame (73) of the rear landing gear through a connecting rod piece, and the end faces of the two ends of the transverse frame (73) of the rear landing gear are symmetrically provided with fastening screw holes (74); fastening screw holes (74) at two ends of a rear landing gear transverse frame (73) are respectively fixed at rear landing gear mounting holes (33) at the inner sides of two parallelogram racks (29) in the middle part (11) of the airplane body through screws;

the ducted fan system (6) consists of a rectangular plate (76), a transverse steering engine (78), a U-shaped frame (79), a longitudinal steering engine (80), a first ducted fan (81), a double-rod transverse frame (82) and a second ducted fan (83);

a transverse steering engine (78) is fixed on the lower plane of the rectangular plate (76), a steering engine shaft of the transverse steering engine (78) is fixedly connected with the middle position of the closed end of the U-shaped frame (79), the open end of the U-shaped frame (79) is fixedly connected with two sides of the lower part of the longitudinal steering engine (80), and the steering engine shafts on two sides of the longitudinal steering engine (80) are respectively fixedly connected with the tail ends of longitudinal rods (86) of corresponding double-rod transverse frames (82);

the double-rod transverse frame (82) is formed by integrating a transverse rod (84) and two longitudinal rods (86); ducted fan fixing plates (85) are symmetrically arranged at two ends of the transverse rods (84), and longitudinal rods (86) are symmetrically fixed close to the inner sides of the ducted fan fixing plates (85);

a machine body connecting through hole (75) is arranged near the front end of the rectangular plate (76), and a tail rod connecting hole (77) is arranged on the upper plane of the rectangular plate (76); the first quadrilateral fixing rod (34) penetrates through the machine body connecting through hole (75) and is fixed in the middle part (11) of the machine body; a rectangular plate connecting hole at the front end of the tail rod (12) is fixed with a tail rod connecting hole (77) of the rectangular plate (76) through a screw; the first ducted fan (81) and the second ducted fan (83) are respectively and fixedly connected with the corresponding ducted fan fixing plate (85);

the connection relation of the model airplane receiver (8) is as follows: the model airplane receiver (8) is wirelessly connected with the remote controller (87), and the anode and the cathode of the lithium battery (88) are correspondingly connected with the anode and the cathode of the power interface of the model airplane receiver (8); an electric regulation interface 1, an electric regulation interface 2 and an electric regulation interface 3 of a model airplane receiver (8) are sequentially and correspondingly connected with an electric regulation 1, an electric regulation 2 and an electric regulation 3, and the electric regulation 1, the electric regulation 2 and the electric regulation 3 are sequentially and correspondingly connected with a double-end motor (41), a first ducted fan (81) and a second ducted fan (83); a steering engine interface 1 and a steering engine interface 2 of the model airplane receiver (8) are sequentially and correspondingly connected with a transverse steering engine (78) and a longitudinal steering engine (80);

the lithium battery (88) and the model airplane receiver (8) are respectively arranged in the two parallelogram frames (29) of the middle part (11) of the airplane body.

2. A flapping-rotor aircraft capable of autonomous takeoff according to claim 1, wherein: the cylindrical sliding block (46) is a hollow cube, and eccentric round holes (51) are symmetrically formed in the left side face and the right side face of the hollow cube; the hollow cube is provided with a square hole or a round hole, and the nominal size of the cross section of the square hole or the round hole is the same as that of the cross section of the guide rod (45).

3. A flapping-rotor aircraft capable of autonomous takeoff according to claim 1, wherein: the output shaft of the transverse steering engine (78) is mutually perpendicular to the output shaft of the longitudinal steering engine (80) in space.

Technical Field

The invention belongs to the technical field of flapping wing aircrafts, and particularly relates to a flapping rotor wing aircraft capable of taking off automatically.

Background

The flapping wing flight has good maneuverability and flexibility. Compared with fixed wing flight, the high-lift aircraft can obtain high lift force by fully utilizing unsteady aerodynamic characteristics under the condition of low Reynolds number, and has very high flight stability. Compared with single-degree-of-freedom flapping-wing motion, the multi-degree-of-freedom flapping-wing motion can better realize the attitude of flying creatures, is flexible to fly, and can better control the flying mode in the motion process.

At present, most of the studied flapping-wing aircraft are single-degree-of-freedom mechanisms, the operation form is simple, the flight flexibility and the flight stability cannot be compared with those of flying creatures, for example, a pigeon-like flapping-wing aircraft (CN 112693606A), although the pigeon-like flapping-wing aircraft can fly at high speed, can carry more effective loads, has smaller flapping-wing size, still suffers larger resistance to a single wing surface in the flight process, has poor flexibility, needs to be thrown by hand during takeoff, and cannot take off autonomously like autonomous birds;

in the existing multi-degree-of-freedom flapping wing aircraft, such as a bird-like multi-degree-of-freedom flapping wing aircraft (CN 107021223A), although the flapping amplitude of the wing can be changed according to different flight conditions, the angle of attack of the wing in the motion direction can also be changed, and the wing motion has the characteristic of high bionic performance; however, the wings are used as single-wing surfaces, only have two postures of torsion and flapping, are not folded, do not have three motions of flapping, folding and torsion, and need other modes such as manual lifting during taking off and landing;

for example, in a two-section three-degree-of-freedom flapping wing aircraft patent (CN 112478155 a), although flapping, folding and twisting can be effectively realized by only one driving motor, the power for flight advancing is still insufficient, and the aircraft also needs to be thrown by hand, and the lift force required by flight cannot be sufficiently ensured;

as another flapping wing aircraft (CN 113086187 a) with two degrees of freedom capable of realizing flapping and twisting, although the flapping wing can realize both flapping and twisting motions only under the driving of one driving motor, so as to improve the aerodynamic performance of the flapping wing aircraft, and the whole mechanism operates stably, so as to improve the maneuverability and stability of the flapping wing aircraft, only two motions of flapping and twisting can be realized, and no three-coupling motion of flapping, folding and twisting can be realized.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and aims to provide a flapping rotor wing aircraft which has few driving power parts, can realize flapping-folding-twisting three-coupling motion, has high flying speed and large lifting force and can take off autonomously.

In order to achieve the purpose, the invention adopts the technical scheme that: for convenience of description, the aircraft head is set to be the front, the left side facing the aircraft head is the left side, and the right side facing the aircraft head is the right side; the left-right direction is transverse, and the front-back direction is longitudinal.

The flapping rotor wing aircraft capable of taking off automatically comprises an aircraft body, a front undercarriage, a driving mechanism, wings, a rear undercarriage, a ducted fan system, an empennage and an aeromodelling receiver.

The machine body consists of a head part, two connecting plates, a middle part of the machine body and a tail rod; the head is connected with the front end of the middle part of the machine body through the connecting plates on the two sides, the middle position of the rear end of the middle part of the machine body is fixedly connected with the tail rod close to the front end, and the front end of the tail rod is provided with a rectangular plate connecting hole.

The nose landing gear is fixed on the lower portions of the two side connecting plates, the driving mechanism is installed in the middle of the two side connecting plates, the two wings are symmetrically installed on the outer sides of the two side connecting plates, the rear landing gear is installed on the lower portion, close to the rear, of the middle of the fuselage, the ducted fan system is installed at the rear end of the middle of the fuselage, and the tail wing is installed at the tail end of the tail rod.

The head part consists of an arc-shaped frame, a bevel gear fixing rod and a machine head fixing rod; the arc-shaped frame is an integral body consisting of an arc-shaped rod, a vertical rod and a horizontal rod, the rear end of the arc-shaped rod is integrated with the upper end of the vertical rod, and the front end of the arc-shaped rod is integrated with the front end of the horizontal rod; the lower ends of the two vertical rods are symmetrically fixed at two sides of the machine head fixing rod close to the middle part, and the rear ends of the horizontal rods are symmetrically fixed at two ends of the bevel gear fixing rod close to the two ends; bevel gear shafts are symmetrically fixed on the bevel gear fixing rod, and the two bevel gear shafts are respectively abutted against the inner walls of the corresponding horizontal rods.

In the head portion:

vertical distance h between machine head fixing rod and bevel gear fixing rod₁=0.8~0.9h₀；

Horizontal distance l between machine head fixing rod and bevel gear fixing rod₁=0.3~0.4l₀；

Distance b between two arc-shaped rods₁=0.5~0.6b₀。

Wherein:

h₀represents the height of the vertical pole, mm;

l₀represents the length, mm, of the horizontal bar;

b₀the length and mm of the handpiece fixed rod and the bevel gear fixed rod are shown.

The connecting plate is a quadrilateral flat plate surrounded by a front bevel edge, a middle bevel edge, a rear bevel edge and a long bevel edge; the included angle between the front bevel edge and the middle bevel edge is an obtuse angle, and the included angle between the rear bevel edge and the middle bevel edge is an obtuse angle.

In the quadrilateral flat plate:

a bevel gear fixing rod hole is formed at the included angle of the front bevel edge and the middle bevel edge;

a front landing gear mounting hole is formed at the included angle between the front bevel edge and the long bevel edge;

a torsion bar hole is arranged at the included angle of the middle bevel edge and the rear bevel edge;

a second machine body fixing rod hole is formed at the included angle of the rear bevel edge and the long bevel edge;

a torsion shaft hole is formed in the middle of the torsion rod hole and the second machine body fixing rod hole;

a first machine body fixing rod hole is formed at a position close to the second machine body fixing rod hole;

a transmission rotating shaft hole is arranged at the middle position of the quadrilateral flat plate close to the front part;

a machine head fixing rod hole is arranged at the position close to the rear part of the middle part of the quadrangular flat plate and is close to the middle bevel edge;

a bevel gear fixing rod with a head is fixed in the bevel gear fixing rod hole;

the head fixing rod with the head is fixed in the head fixing rod hole.

The middle part of the machine body consists of two parallelogram racks, a second quadrilateral fixed rod, a first machine body fixed rod and a second machine body fixed rod which are all one; the parallelogram frame is an integral body consisting of two parallel diagonal members and two parallel long members, and the included angle between the front diagonal member and the lower long member of the parallelogram frame is an acute angle; the two parallelogram racks are respectively and symmetrically provided with two motor mounting holes at acute angles at the front parts of the two parallelogram racks, the obtuse angles at the front parts of the two parallelogram racks are respectively and symmetrically provided with a second machine body fixing rod, and the forward inclined edges of the two parallelogram racks are respectively and upwards provided with a first machine body fixing rod.

A tail rod is fixed at the middle position of the second quadrilateral fixing rod in the middle of the machine body, and the central line of the tail rod is vertical to the second quadrilateral fixing rod;

a first machine body fixing rod is fixedly arranged in the first machine body fixing rod holes of the two connecting plates;

and a second machine body fixing rod is fixedly arranged in the second machine body fixing rod holes of the two connecting plates.

The nose landing gear consists of a nose landing gear universal wheel and a nose landing gear cross bar, and the nose landing gear universal wheels are symmetrically arranged at two ends close to the nose landing gear cross bar; two ends of the nose landing gear cross frame rod are respectively and fixedly arranged in the nose landing gear mounting holes of the corresponding connecting plates.

The driving mechanism consists of a torsion mechanism, a driving motor and a flapping folding mechanism; the driving motor consists of a double-head motor and four small belt pulleys; two small belt pulleys are symmetrically arranged on output shafts at two ends of the double-end motor, and frame connecting holes are symmetrically arranged at two ends of the double-end motor shell; the screws are in threaded connection with the corresponding frame connecting holes through the motor mounting holes of the two parallelogram frames.

The torsion mechanism consists of two first large belt pulleys, two torsion shafts, a cylindrical sliding block, a guide rod and a torsion rod; first large belt pulleys are symmetrically arranged at the positions, close to the outer ends, of the two torsion shafts, torsion eccentric shafts are arranged on the inner end faces of the two torsion shafts, the two torsion eccentric shafts are correspondingly connected with eccentric round holes formed in the two sides of the cylindrical sliding block respectively, and the axes of the two torsion shafts are the same straight line. The cylindrical sliding block is movably sleeved at one end of the guide rod, the other end of the guide rod is fixedly connected with the middle position of the torsion rod, and wing connecting holes are formed in the two ends of the torsion rod. The outer ends of the two torsion shafts are respectively arranged in torsion shaft holes of the connecting plate; the torsion bar is installed in the torsion bar hole of the connecting plate.

The flapping folding mechanism consists of a second large belt pulley, a transmission shaft, a double-sided bevel gear, a crank bevel gear, a flapping folding connecting rod and a track rod; second large belt pulleys are symmetrically arranged at the positions, close to the two ends, of the transmission shaft, double-sided bevel gears are arranged in the middle of the transmission shaft, and the bevel teeth on the two sides of each double-sided bevel gear are meshed with the corresponding two crank bevel gears respectively; connecting rod eccentric shafts are symmetrically arranged on the same side face of bevel teeth of the crank bevel gear, the lower ends of the two flapping folding connecting rods are movably connected with the connecting rod eccentric shafts, the upper ends of the two flapping folding connecting rods are respectively movably connected with the lower ends of the track rods through track rod pin shafts, and track rod connecting holes are formed in the upper ends of the track rods; the axis of the connecting rod eccentric shaft is mutually vertical to the central line of the connecting hole of the track rod in space.

Two ends of the transmission shaft are movably arranged in the transmission shaft holes of the two connecting plates; the two crank bevel gears are respectively and movably installed with two bevel gear shafts of the bevel gear fixing rod.

Two small belt pulleys of output shafts at two ends of the double-end motor are correspondingly connected with a first large belt pulley of the torsion mechanism and a second large belt pulley of the flapping folding mechanism respectively through respective belts.

The wing consists of a plane four-bar mechanism, an inner wing and an outer wing, and the inner wing and the outer wing are movably connected together through the plane four-bar mechanism; the plane four-bar mechanism consists of a transmission rod, a wing connecting rod, an inner wing rod and an outer wing rod; the transmission rod is formed by bending a straight rod into two straight rods, the included angle of the two straight rods is 150-170 degrees, and wing hinge holes are formed in the included angle of the two straight rods; the wing hinge hole is hinged with one end of a wing connecting rod through a pin shaft, the other end of the wing connecting rod is hinged with one end of an inner wing rod through a pin shaft in a pin shaft hole of the inner wing connecting rod, and the other end of the inner wing rod is hinged with a bent angle of an outer wing rod through a pin shaft; the outer wing rod is an L-shaped rod piece formed by a long rod and a short rod, the short rod end of the L-shaped rod piece is hinged with the left end of the transmission rod through a pin shaft, and a track rod connecting shaft is coaxially arranged at the right end face of the transmission rod; the track rod connecting shaft is connected with the track rod connecting hole.

The long rod body of the outer wing rod of the plane four-bar mechanism is fixedly connected with the lower surface of the outer wing, and the long rod body of the outer wing rod is close to the front side edge of the outer wing; the rod body of the inner wing rod is fixedly connected with the lower surface of the inner wing, and the rod body of the inner wing rod is close to the front side edge of the inner wing.

A C-shaped groove is arranged at the position, close to the front side, of the inner side surface of the inner wing, the opening end of the C-shaped groove is symmetrically provided with wing pin shaft holes, and wing pin shafts are movably connected with the wing pin shaft holes; the torsion rod of the torsion mechanism is provided with a wing connecting hole which is hinged with a wing pin shaft.

The rear landing gear consists of a rear landing gear universal wheel and a rear landing gear cross frame; the axle of the universal wheel of the rear landing gear is fixedly connected with the middle position of the cross frame of the rear landing gear through a connecting rod piece, and the end surfaces of the two ends of the cross frame of the rear landing gear are symmetrically provided with fastening screw holes; the fastening screw holes at the two ends of the rear landing gear cross frame are respectively fixed at the mounting holes of the rear landing gear at the inner sides of the two parallelogram racks at the middle part of the body through screws.

The ducted fan system is composed of a rectangular plate, a transverse steering engine, a U-shaped frame, a longitudinal steering engine, a first ducted fan, a double-rod cross frame and a second ducted fan.

The lower plane of the rectangular plate is fixedly provided with a transverse steering engine, a steering engine shaft of the transverse steering engine is fixedly connected with the middle position of the closed end of the U-shaped frame, the open end of the U-shaped frame is fixedly connected with the two sides of the lower part of the longitudinal steering engine, and the steering engine shafts on the two sides of the longitudinal steering engine are respectively fixedly connected with the tail ends of the longitudinal rods of the corresponding double-rod transverse frame.

The double-rod transverse frame is formed by integrating a transverse rod and two longitudinal rods; both ends of the transverse rod are symmetrically provided with ducted fan fixing plates, and the longitudinal rods are symmetrically fixed close to the inner sides of the ducted fan fixing plates.

A machine body connecting through hole is arranged near the front end of the rectangular plate, and a tail rod connecting hole is arranged on the upper plane of the rectangular plate; the first quadrilateral fixing rod penetrates through the machine body connecting through hole and is fixed in the middle of the machine body; a rectangular plate connecting hole at the front end of the tail rod is fixed with a tail rod connecting hole of the rectangular plate through a screw; the first ducted fan and the second ducted fan are fixedly connected with the corresponding ducted fan fixing plates respectively.

The connection relation of the model airplane receiver is as follows: the model airplane receiver is wirelessly connected with the remote controller, and the anode and the cathode of the lithium battery are correspondingly connected with the anode and the cathode of a power interface of the model airplane receiver; an electric regulation interface 1, an electric regulation interface 2 and an electric regulation interface 3 of the model airplane receiver are sequentially and correspondingly connected with an electric regulation 1, an electric regulation 2 and an electric regulation 3, and the electric regulation 1, the electric regulation 2 and the electric regulation 3 are sequentially and correspondingly connected with a double-end motor, a first ducted fan and a second ducted fan; a steering engine interface 1 and a steering engine interface 2 of the model airplane receiver are sequentially and correspondingly connected with a transverse steering engine and a longitudinal steering engine.

The lithium battery and the model airplane receiver are respectively arranged in the two parallelogram frames in the middle of the airplane body.

The cylindrical sliding block is a hollow cube, and eccentric round holes are symmetrically formed in the left side surface and the right side surface of the hollow cube; the hollow cube is provided with a square hole or a round hole, and the nominal size of the section of the square hole or the round hole is the same as that of the section of the guide rod.

The output shaft of the transverse steering engine is mutually perpendicular to the output shaft of the longitudinal steering engine in space.

Due to the adoption of the technical scheme, compared with the prior art, the invention has the following positive effects:

1. the invention uses small belt pulleys arranged at two ends of a double-head motor in the driving mechanism to be respectively connected with the torsion mechanism and the flapping folding mechanism through respective belts, and respectively transmits power to corresponding wing shaft pins and transmission rods in wings at two sides, so that driving members are few.

2. The driving mechanism is a space SSR mechanism as a whole, a torsion mechanism in the driving mechanism is a crank slider guide rod mechanism, and is connected with a cylindrical slider through a torsion eccentric shaft on a torsion shaft, so that the cylindrical slider and the guide rod do reciprocating motion and the guide rod rotates for a certain angle in a reciprocating way by taking the axis of the torsion rod as a central line, and wings connected with two sides of the torsion rod are twisted for a certain angle; the flapping folding mechanism of the driving mechanism transmits power to a crank bevel gear through a double-sided bevel gear, and a track rod connected with a flapping folding connecting rod is driven by a connecting rod eccentric shaft to rotate at a certain angle, so that wings connected with the track rod do flapping folding movement at a certain angle; therefore, the invention can realize three-coupling motion of flapping, folding and twisting.

3. In the ducted fan system, a first ducted fan and a second ducted fan are connected with a longitudinal steering engine through a double-rod cross frame, the longitudinal steering engine is connected with a transverse steering engine through a U-shaped frame, and the transverse steering engine is fixed on a rectangular plate connected with a machine body; the force generated by the counterclockwise or clockwise rotation of the two ducted fans can increase or decrease the forward speed of the flapping-rotor aircraft; therefore, the invention has high flying speed.

4. The transverse steering engine provided by the invention can provide steering force for the aircraft during left-right steering by adjusting the left-right direction and angle of force generated by the rotation of the two ducted fans, so that the ducted steering of the aircraft is realized; the longitudinal steering engine controls the vertical direction and the angle of force generated when the two ducted fans rotate, and provides the aircraft with lift force required during takeoff and resistance required during descent; therefore, the lifting force of the invention is large.

5. The wings of the flapping-rotor aircraft have torsional postures in the flying process, so that the attack angle of the wings is regularly changed, the airflow velocity on the wing surfaces of the wings is greater than that under the wing surfaces during flying, and a larger lift force is generated; therefore, the lifting force is large.

6. The nose landing gear and the rear landing gear are universal wheel landing gears with light weight, and the height of the nose landing gear is slightly larger than that of the rear landing gear, so that the flapping rotor aircraft can autonomously stand like a bird; the flapping rotor aircraft can provide certain takeoff angle and speed sprint when taking off, can provide certain speed buffer when landing, and does not need personnel to throw the aircraft to take off by hands or catch the aircraft to land by hands; therefore, the invention can realize autonomous takeoff.

Therefore, the invention has the characteristics of few driving motive power pieces, capability of realizing flapping-folding-twisting three-coupling motion, high flying speed, large lifting force and capability of taking off automatically.

Description of the drawings:

FIG. 1 is a schematic diagram of an embodiment of the present invention;

fig. 2 is a schematic structural view of the fuselage 1 of fig. 1;

FIG. 3 is an enlarged schematic view of the head 9 of FIG. 2;

FIG. 4 is an enlarged schematic view of the connection plate 10 of FIG. 2;

FIG. 5 is an enlarged schematic view of the mid-fuselage 11 of FIG. 2;

figure 6 is an enlarged schematic view of the nose landing gear 2 of figure 1;

fig. 7 is an enlarged schematic view of the drive mechanism 3 in fig. 1;

fig. 8 is an enlarged schematic view of the driving motor 39 in fig. 7;

FIG. 9 is an enlarged schematic view of the torsion mechanism 38 of FIG. 7;

FIG. 10 is an exploded, enlarged, schematic view of the torsion mechanism 38 component of FIG. 9;

FIG. 11 is a schematic diagram of one configuration of the flapping folding mechanism 40 of FIG. 8;

FIG. 12 is a schematic view of the flapping folding mechanism 40 of FIG. 11 with parts connected;

FIG. 13 is an enlarged, bottom view of the airfoil 4 of FIG. 1;

FIG. 14 is a view of FIG. 13A partially enlarged schematic view of (a);

FIG. 15 is an enlarged schematic view of the rear landing gear 5 of FIG. 1;

FIG. 16 is an enlarged schematic view of the ducted fan system 6 of FIG. 1;

FIG. 17 is a schematic bottom view of FIG. 16;

FIG. 18 is a schematic structural view of the dual bar crossbar 82 of the ducted fan system 6 of FIG. 16;

fig. 19 is a schematic diagram showing a connection relationship of the model airplane receiver 8 in fig. 1.

Detailed Description

The invention is further described with reference to the following figures and detailed description, without limiting its scope.

Example 1

A flapping rotor wing aircraft capable of taking off automatically. For convenience of description, the aircraft head is set to be the front, the left side facing the aircraft head is the left side, and the right side facing the aircraft head is the right side; the left-right direction is transverse, and the front-back direction is longitudinal.

As shown in fig. 1, the flapping-rotor aircraft capable of autonomous takeoff is composed of a fuselage 1, a nose landing gear 2, a driving mechanism 3, wings 4, a rear landing gear 5, a ducted fan system 6, an empennage 7 and a model airplane receiver 8.

As shown in fig. 2, the body 1 is composed of a head 9, two connecting plates 10, a body middle part and a tail rod; the head part 9 is connected with the front end of the middle part of the machine body through the connecting plates 10 at two sides, the middle position of the rear end of the middle part of the machine body is fixedly connected with the position, close to the front end, of the tail rod, and the front end of the tail rod is provided with a rectangular plate connecting hole.

As shown in fig. 1 and 2, the nose landing gear 2 is fixed on the lower part of the two side connecting plates 10, the driving mechanism 3 is installed at the middle position of the two side connecting plates 10, the two wings 4 are symmetrically installed on the outer sides of the two side connecting plates 10, the rear landing gear 5 is installed at the lower part of the middle part of the fuselage near the rear part, the ducted fan system 6 is installed at the rear end of the middle part of the fuselage, and the tail wing 7 is installed at the tail end of the tail rod.

As shown in fig. 3, the head 9 is composed of an arc-shaped frame, a bevel gear fixing rod and a handpiece fixing rod 16; the arc-shaped frame is an integral body consisting of an arc-shaped rod, a vertical rod and a horizontal rod, the rear end of the arc-shaped rod is integrated with the upper end of the vertical rod, and the front end of the arc-shaped rod is integrated with the front end of the horizontal rod; the lower ends of the two vertical rods are symmetrically fixed at two sides of the handpiece fixed rod 16 close to the middle part, and the rear ends of the horizontal rods are symmetrically fixed at two ends of the bevel gear fixed rod close to the two ends; bevel gear shafts are symmetrically fixed on the bevel gear fixing rod, and the two bevel gear shafts are respectively abutted against the inner walls of the corresponding horizontal rods.

In the head 9:

vertical distance h between handpiece-holding lever 16 and bevel gear-holding lever₁=0.9h₀；

Horizontal distance l between handpiece-fixing lever 16 and bevel gear-fixing lever₁=0.4l₀；

Distance b between two arc-shaped rods₁=0.6b₀。

Wherein:

h₀represents the height of the vertical pole, mm;

l₀represents the length, mm, of the horizontal bar;

b₀indicating the length, mm, of the handpiece stationary rod 16 and bevel gear stationary rod.

As shown in fig. 4, the connecting plate 10 is a quadrangular flat plate surrounded by a front oblique side 17, a middle oblique side 21, a rear oblique side 26 and a long oblique side 28; the angle between the front bevel 17 and the middle bevel 21 is obtuse, and the angle between the rear bevel 26 and the middle bevel 21 is obtuse.

In the quadrilateral flat plate:

a bevel gear fixing rod hole 19 is arranged at the included angle of the front bevel edge 17 and the middle bevel edge 21;

a nose landing gear mounting hole 18 is formed at the included angle of the front bevel edge 17 and the long bevel edge 28;

a torsion bar hole 23 is arranged at the included angle of the middle bevel edge 21 and the rear bevel edge 26;

a second fuselage fixing rod hole 27 is formed at the corner between the rear inclined edge 26 and the long inclined edge 28;

a torsion shaft hole 24 is arranged at the middle position of the torsion rod hole 23 and the second body fixing rod hole 27;

a first body fixing rod hole 25 is provided at a position close to the second body fixing rod hole 27;

a transmission rotating shaft hole 20 is arranged at the middle position of the quadrilateral flat plate close to the front part;

a head fixing rod hole 22 is formed in the middle part of the quadrilateral flat plate close to the rear part, and the head fixing rod hole 22 is close to the middle bevel edge 21;

a bevel gear fixing rod with a head 9 is fixed in the bevel gear fixing rod hole 19;

the handpiece fixing lever 16 having the head 9 mounted therein is fixed in the handpiece fixing lever hole 22.

As shown in fig. 5, the middle part of the body is composed of two parallelogram frames 29, and a second quadrilateral fixing rod 35, a first quadrilateral fixing rod 34, a first body fixing rod 31 and a second body fixing rod 32 which are all one; the parallelogram frame 29 is an integral body consisting of two parallel diagonal members and two parallel long members, and the included angle between the front diagonal member and the lower long member of the parallelogram frame 29 is an acute angle; a second quadrangle fixing rod 35 and a first quadrangle fixing rod 34 are fixed at the acute angle of the rear part and the obtuse angle of the rear part of the two parallelogram racks 29 in sequence, rear landing gear mounting holes 33 are symmetrically arranged in front of the first quadrangle fixing rod 34, two motor mounting holes 30 are symmetrically arranged at the acute angle of the front parts of the two parallelogram racks 29 respectively, a second body fixing rod 32 is fixed at the obtuse angle of the front parts of the two parallelogram racks 29, and a first body fixing rod 31 is fixed at the position of the upper inclined edge of the two parallelogram racks 29 facing forwards.

As shown in fig. 2 and 5, a tail rod is fixed at the middle position of the second quadrangular fixing rod 35 in the middle of the fuselage, and the center line of the tail rod is perpendicular to the second quadrangular fixing rod 35;

first body fixing bars 31 are fixedly installed in the first body fixing bar holes 25 of the two connection plates 10;

a second body fixing rod 32 is fixedly installed in the second body fixing rod holes 27 of the two connection plates 10.

As shown in fig. 6, the nose landing gear 2 is composed of a nose landing gear universal wheel 36 and a nose landing gear cross bar 37, and the nose landing gear universal wheels 36 are symmetrically installed at both ends near the nose landing gear cross bar 37; both ends of the nose gear cross bar 37 are fixedly mounted in the nose gear mounting holes 18 of the respective corresponding connecting plates 10.

As shown in fig. 7, the driving mechanism 3 is composed of a twisting mechanism 38, a driving motor 39, and a flapping folding mechanism 40. As shown in fig. 8, the driving motor 39 is composed of a double-head motor 41 and four small pulleys 42; two small belt pulleys 42 are symmetrically arranged on output shafts at two ends of the double-head motor 41, and frame connecting holes 43 are symmetrically arranged at two ends of a shell of the double-head motor 41; the screws are threadedly coupled to the corresponding frame coupling holes 43 through the motor mounting holes 30 of the two parallelogram frames 29.

As shown in fig. 9 and 10, the torsion mechanism 38 is composed of two first large pulleys 44, two torsion shafts 45, a cylindrical slider 46, a guide rod 47, and a torsion rod 48; the first large belt pulleys 44 are symmetrically arranged at the positions, close to the outer ends, of the two torsion shafts 45, the torsion eccentric shafts 50 are arranged on the inner end faces of the two torsion shafts 45, the eccentricity of the torsion eccentric shafts 50 is e', the two torsion eccentric shafts 50 are respectively and correspondingly connected with eccentric circular holes 51 arranged at the two sides of the cylindrical sliding block 46, and the axes of the two torsion shafts 45 are the same straight line. The cylindrical sliding block 46 is movably sleeved at one end of a guide rod 47, the other end of the guide rod 47 is fixedly connected with the middle position of a torsion rod 48, and wing connecting holes 49 are formed in two ends of the torsion rod 48. The outer ends of the two torsion shafts 45 are respectively arranged in the torsion shaft holes 24 of the connecting plate 10; the torsion bar 48 is installed in the torsion bar hole 23 of the connection plate 10.

As shown in fig. 11 and 12, the flapping folding mechanism 40 is composed of a second large belt pulley 52, a transmission shaft 53, a double-sided bevel gear 54, a crank bevel gear 55, a flapping folding connecting rod 56 and a track rod 57; second large belt pulleys 52 are symmetrically arranged at the positions, close to the two ends, of the transmission shaft 53, double-sided bevel gears 54 are arranged at the middle positions of the transmission shaft 53, and the bevel teeth on the two sides of each double-sided bevel gear 54 are respectively meshed with the corresponding two crank bevel gears 55; the connecting rod eccentric shafts 60 are symmetrically arranged on the same side face of the bevel gear 55 of the crank bevel gear, the eccentricity of the connecting rod eccentric shafts 60 is e '', the lower ends of the two flapping folding connecting rods 56 are movably connected with the connecting rod eccentric shafts 60, the upper ends of the two flapping folding connecting rods 56 are respectively movably connected with the lower ends of the track rods 57 through track rod pin shafts 58, and the upper ends of the track rods 57 are provided with track rod connecting holes 59; the axis of the connecting rod eccentric shaft 60 and the center line of the locus rod connecting hole 59 are perpendicular to each other in space.

Two ends of the transmission shaft 53 are movably arranged in the transmission shaft holes 20 of the two connecting plates 10; the two crank bevel gears 55 are movably mounted with two bevel gear shafts of the bevel gear fixing rod respectively.

Two small belt pulleys 42 of output shafts at two ends of the double-head motor 41 are respectively and correspondingly connected with a first large belt pulley 44 of the torsion mechanism 38 and a second large belt pulley 52 of the flapping folding mechanism 40 through respective belts.

As shown in fig. 13 and 14, the airfoil 4 is composed of a planar four-bar linkage 61, an inner wing 63 and an outer wing 67, the inner wing 63 and the outer wing 67 being movably connected together by the planar four-bar linkage 61; the plane four-bar mechanism 61 consists of a transmission rod 64, a wing connecting rod 62, an inner wing rod 65 and an outer wing rod 66; the transmission rod 64 is formed by bending a straight rod into two straight rods, the included angle of the two straight rods is 150-170 degrees, and wing hinge holes 71 are formed in the included angle of the two straight rods; the wing hinge hole 71 is hinged with one end of the wing connecting rod 62 through a pin shaft, the other end of the wing connecting rod 62 is hinged with one end of the inner wing rod 65 through a pin shaft of the inner wing connecting rod pin shaft hole 70, and the other end of the inner wing rod 65 is hinged with the bent angle of the outer wing rod 66 through a pin shaft; the outer wing rod 66 is an L-shaped rod member formed by a long rod and a short rod, the short rod end of the L-shaped rod member is hinged with the left end of the transmission rod 64 through a pin shaft, and the right end face of the transmission rod 64 is coaxially provided with a track rod connecting shaft 68; the track bar connecting shaft 68 is connected to the track bar connecting hole 59.

As shown in fig. 13, the stem body of the outer wing lever 66 of the planar four-bar mechanism 61 is fixedly connected with the lower surface of the outer wing 67, and the stem body of the outer wing lever 66 is adjacent to the front side of the outer wing 67; the shaft of the inner wing rod 65 is fixedly connected with the lower surface of the inner wing 63, and the shaft of the inner wing rod 65 is adjacent to the front side edge of the inner wing 63.

As shown in fig. 14, a "C" shaped groove is provided near the front side of the inner side surface of the inner wing 63, a wing pin shaft hole is symmetrically provided at the opening end of the "C" shaped groove, and the wing pin shaft 69 is movably connected with the wing pin shaft hole; the torsion bar 48 of the torsion mechanism 38 is provided with a wing connection hole 49 hinged to a wing pin 69.

As shown in fig. 15, the rear landing gear 5 is composed of a rear landing gear universal wheel 72 and a rear landing gear cross frame 73; the axle of the universal wheel 72 of the rear landing gear is fixedly connected with the middle position of a cross frame 73 of the rear landing gear through a connecting rod piece, and fastening screw holes 74 are symmetrically arranged on the end surfaces of two ends of the cross frame 73 of the rear landing gear; the fastening screw holes 74 at the two ends of the rear landing gear cross frame 73 are respectively fixed at the rear landing gear mounting holes 33 inside the two parallelogram racks 29 in the middle of the fuselage through screws.

As shown in fig. 16 and 17, the ducted fan system 6 is composed of a rectangular plate 76, a lateral steering engine 78, a "U" shaped frame 79, a longitudinal steering engine 80, a first ducted fan 81, a double-rod cross frame 82, and a second ducted fan 83.

A transverse steering engine 78 is fixed on the lower plane of the rectangular plate 76, a steering engine shaft of the transverse steering engine 78 is fixedly connected with the middle position of the closed end of the U-shaped frame 79, the open end of the U-shaped frame 79 is fixedly connected with the two sides of the lower part of the longitudinal steering engine 80, and steering engine shafts on the two sides of the longitudinal steering engine 80 are respectively fixedly connected with the tail ends of the longitudinal rods 86 of the corresponding double-rod cross frames 82.

As shown in FIG. 18, the dual bar cross-bar 82 is a cross bar 84 integrated with two longitudinal bars 86; both ends of the transverse rod 84 are symmetrically provided with ducted fan fixing plates 85, and the inner sides of the ducted fan fixing plates 85 are symmetrically fixed with longitudinal rods 86.

As shown in fig. 16 and 17, a body attachment through hole 75 is provided near the front end of the rectangular plate 76, and a tail rod attachment hole 77 is provided on the upper plane of the rectangular plate 76; the first quadrilateral fixing rod 34 passes through the body connecting through hole 75 and is fixed in the middle of the body; the rectangular plate connecting hole at the front end of the tail rod is fixed with a tail rod connecting hole 77 of the rectangular plate 76 through a screw; the first ducted fan 81 and the second ducted fan 83 are fixedly connected to the corresponding ducted fan fixing plate 85, respectively.

As shown in fig. 19, the connection relationship of the model airplane receiver 8 is: the model airplane receiver 8 is wirelessly connected with the remote controller 87, and the anode and the cathode of the lithium battery 88 are correspondingly connected with the anode and the cathode of the power interface of the model airplane receiver 8; the electric regulation interface 1, the electric regulation interface 2 and the electric regulation interface 3 of the model airplane receiver 8 are sequentially and correspondingly connected with the electric regulation 1, the electric regulation 2 and the electric regulation 3, and the electric regulation 1, the electric regulation 2 and the electric regulation 3 are sequentially and correspondingly connected with the double-end motor 41, the first ducted fan 81 and the second ducted fan 83; and a steering engine interface 1 and a steering engine interface 2 of the model airplane receiver 8 are correspondingly connected with a transverse steering engine 78 and a longitudinal steering engine 80 in sequence.

The lithium battery 88 and the model airplane receiver 8 are respectively arranged in the two parallelogram frames 29 in the middle of the airplane body.

As shown in fig. 10, the cylindrical slider 46 is a hollow cube, the left side surface and the right side surface of the hollow cube are symmetrically provided with eccentric circular holes 51, and the centers of the eccentric circular holes 51 are equal to each other; the hollow cube is provided with a square hole having a nominal cross-sectional dimension that is the same as the nominal cross-sectional dimension of the guide rod 45.

As shown in fig. 16 and 17, the output shaft of the transverse steering engine 78 is perpendicular to the output shaft of the longitudinal steering engine 80 in space.

Example 2

A flapping rotor wing aircraft capable of taking off automatically. The procedure is as in example 1, except for the following parameters or structures:

in the head 9:

vertical distance h between handpiece-holding lever 16 and bevel gear-holding lever₁=0.8h₀；

Horizontal distance l between handpiece-fixing lever 16 and bevel gear-fixing lever₁=0.3l₀；

Distance b between two arc-shaped rods₁=0.5b₀。

The hollow cube is provided with a circular hole having a nominal cross-sectional dimension that is the same as the nominal cross-sectional dimension of the guide rod 45.

Example 3

A flapping rotor wing aircraft capable of taking off automatically. The procedure is as in example 1, except for the following parameters:

in the head 9:

vertical distance h between handpiece-holding lever 16 and bevel gear-holding lever₁=0.85h₀；

Horizontal distance l between handpiece-fixing lever 16 and bevel gear-fixing lever₁=0.35l₀；

Distance b between two arc-shaped rods₁=0.55b₀。

Compared with the prior art, the specific implementation mode has the following positive effects:

1. in the embodiment, the small belt pulleys 42 arranged at two ends of the double-end motor 41 in the driving mechanism 3 are respectively connected with the torsion mechanism 38 and the flapping folding mechanism 39 through respective belts, and power is respectively transmitted to the wing shaft pins 69 and the transmission rods 64 in the wings 4 on two sides, so that driving motive power parts are few.

2. The driving mechanism 3 of the present embodiment is a spatial SSR mechanism as a whole, the torsion mechanism 38 in the driving mechanism 3 is a crank-slider guide-bar mechanism, and is connected to the cylindrical slider 46 through the torsion eccentric shaft 50 on the torsion shaft 45, so that the cylindrical slider 46 and the guide bar 47 make reciprocating motion and the guide bar 47 makes reciprocating rotation at a certain angle with the axis of the torsion bar 48 as the center line, thereby twisting the wings 4 connected to both sides of the torsion bar 48 at a certain angle; the flapping folding mechanism 40 of the driving mechanism 3 transmits power to a crank bevel gear 55 through a double-sided bevel gear 54, and a track rod 57 connected with a flapping folding connecting rod 56 is driven by a connecting rod eccentric shaft 60 to rotate at a certain angle, so that the wing 4 connected with the track rod 57 performs flapping folding movement at a certain angle; therefore, the embodiment can realize three-coupling motion of flapping, folding and twisting.

3. In the ducted fan system 6 of the present embodiment, a first ducted fan 81 and a second ducted fan 83 are connected to a longitudinal steering engine 80 through a double-rod cross frame 82, the longitudinal steering engine 80 is connected to a transverse steering engine 78 through a U-shaped frame 79, and the transverse steering engine 78 is fixed to a rectangular plate 76 connected to a machine body; the force generated by the counterclockwise or clockwise rotation of the two ducted fans can increase or decrease the forward speed of the flapping-rotor aircraft; therefore, the flight speed of the embodiment is high.

4. The transverse steering engine 78 of the present embodiment provides the aircraft with a steering force when steering left and right by adjusting the left and right directions and angles of the force generated when the two ducted fans rotate, so as to realize the ducted steering of the aircraft; the longitudinal steering engine 80 controls the vertical direction and the angle of force generated when the two ducted fans rotate, so as to provide the aircraft with lift force required during takeoff and resistance required during descent; therefore, the lifting force of the present embodiment is large.

5. The wings 4 of the embodiment have torsional postures in the flying process, so that the flapping rotor aircraft regularly changes the attack angle of the wings 4, and the airflow velocity on the wing surfaces of the wings 4 is greater than that under the wing surfaces during flying, thereby generating larger lift force; therefore, the lifting force is large.

6. The nose landing gear 2 and the rear landing gear 5 of the embodiment are universal wheel landing gears with light weight, and the height of the nose landing gear 2 is slightly larger than that of the rear landing gear 5, so that the flapping rotor aircraft can autonomously stand like a bird; the flapping rotor aircraft can provide certain takeoff angle and speed sprint when taking off, can provide certain speed buffer when landing, and does not need personnel to throw the aircraft to take off by hands or catch the aircraft to land by hands; the present embodiment is capable of autonomous takeoff.

Therefore, the embodiment has the characteristics of few driving motive power pieces, capability of realizing flapping-folding-twisting three-coupling motion, high flying speed, large lifting force and capability of taking off automatically.