Air-ground dual-purpose six-foot robot
1. The utility model provides a land and air dual-purpose six-legged four rotor robot structure, its characterized in that combines together four rotor unmanned aerial vehicle and six-legged robot, specifically includes control cabin (1), flight mechanism (2), crawls mechanism (3).
2. The control cabin according to claim 1, characterized in that hardware circuits such as a flight controller and a crawling controller are placed inside the control cabin shell 1, an upper cover plate (13) of the unmanned aerial vehicle is an approximately circular fourteen-sided polygon, a protective cover (11) and a GPS (12) are arranged above the upper cover plate, an electronic speed governor is arranged below the upper cover plate to control the rotation speed of a rotor wing, and a pan-tilt-zoom camera (14) is arranged in front of the upper cover plate.
3. The flight mechanism according to claim 1, characterized in that in the flight mechanism (2), a horn (23) is positioned between an upper unmanned aerial vehicle cover plate (13) and a lower unmanned aerial vehicle cover plate (15) and is connected through a folding mechanism A (21) and a folding mechanism B (22), the horn (23) can be manually folded downwards through adjusting screws, and a motor pile (24) is positioned at the tail end of the horn (23) and is internally provided with a rotor motor (26) which is connected with a rotor (25) through screws.
4. The flight mechanism (2) and the crawling mechanism (3) and the crawling mechanism according to claim 1, wherein a lower unmanned aerial vehicle cover plate (15) in the flight mechanism (2) is connected with a hexapod connecting plate (39) through four M4 x 50 copper columns, and the hexapod connecting plate (33) is used for fixing a steering engine.
5. The crawling mechanism (3) according to claim 1, characterized in that said crawling mechanism (3) comprises six mechanical claws of the same structure, connected by six-foot connecting plates (39), the six-foot connecting plates are rectangular in shape, protruding from the four corners and the middle points of the long sides, and cut a circular hollow pattern around the geometric center; the hip joint steering engine (31) is connected with a hexapod connecting plate (39) through screws, the hip joint steering engine controls feet to move transversely, the hip joint steering engine (31) is connected with the knee joint steering engine (32) through U-shaped steering engine connectors (34) and (35), the knee joint steering engine (32) is connected with the ankle joint steering engine (36) through a C-shaped steering engine connector (33), the knee joint steering engine and the ankle joint steering engine control feet to move longitudinally, a leg support (37) is connected to the ankle joint steering engine (36) through 8 small screws, and the bottom of the leg support (37) is connected with a damping pad (38).
6. The crawling mechanism 3 of claim 5 drives the leg structure of the robot to turn left or right by rotating the hip joint steering engine (31) to complete the steering movement of the robot; the leg stretching motion of the robot is completed by driving the leg structure of the robot to lift up or fall down through the rotation of the knee joint steering engine (32); the robot finishes the selection of the position of the leg landing point by the rotation of the ankle joint steering engine (36); the cooperation of the hip joint steering engine (31), the knee joint steering engine (32) and the ankle joint steering engine (36) can enable the robot to move in any direction.
Background
The air-ground amphibious robot is widely applied to the fields of security protection, military and the like. The system is mainly used for performing dangerous actions such as disaster rescue and cave exploration in dangerous environments. Therefore, the insect is a six-legged robot for both land and air, and has great application prospect.
The existing mobile robot has higher requirement on the ground, can only cross obstacles in a flying mode when encountering a lot of obstacles, has a lower body chassis, cannot adapt to the environments such as low-lying water on the ground, gobi deserts and the like, and is greatly influenced by the ground conditions in the moving process.
Disclosure of Invention
The invention aims to provide a small hexapod amphibious robot which can crawl by utilizing a hexapod structure, can cope with various complex terrains, is provided with a detachable rotor wing device, is more suitable for multi-scene conversion, and has stable crawling effect, strong controllability and obvious exploration effect.
The purpose of the invention is realized by the following technical scheme:
the air-ground dual-purpose hexapod robot comprises a leg support, a control cabin protective cover, a GPS, a pan-tilt camera, an unmanned aerial vehicle upper cover plate, an unmanned aerial vehicle lower cover plate, a folding mechanism A, a folding mechanism B, a boom, a motor pile, a rotor wing motor, a hip joint steering engine, a knee joint steering engine, a C-shaped steering engine connector, a U-shaped steering engine connector A, a U-shaped steering engine connector B, an ankle joint steering engine, a leg support, a shock pad and a crawling structure connecting plate, wherein the leg support is made of steel; the main body of the flight mechanism is positioned at the upper part of the robot, the unmanned aerial vehicle cover plate is of an approximate-circle fourteen-edge shape, a GPS and a protective cover are arranged on the unmanned aerial vehicle cover plate, an electronic governor is arranged below the unmanned aerial vehicle cover plate to control the rotating speed of a rotor wing, a pan-tilt camera is arranged in front of the unmanned aerial vehicle cover plate, a machine arm is positioned between an unmanned aerial vehicle upper cover plate and an unmanned aerial vehicle lower cover plate and connected through a folding mechanism, a motor pile is positioned in the tail end of the machine arm and is provided with a rotor wing motor, and the rotor wing motor is connected with the motor pile through screws; the whole upper portion of robot is the mechanism of crawling, realizes sufficient structure through the steering wheel and removes, and the steering wheel passes through the steering wheel connector and connects, through the screw fixation between the steering wheel connector, sufficient structure bottom is by the screw fixation shock pad.
As shown in figure 2, the flight mechanism unmanned aerial vehicle cover plate is provided with a long strip-shaped hole and a threaded hole which can be connected with the tail end of the arm through a folding mechanism, the folding mechanism is divided into an A part and a B part which are fixed through screws, the size of the robot body can be reduced in a non-working state, and the robot is easy to transport and carry; the protective cover comprises a flight control mechanism, a crawling control mechanism and a power supply control circuit; the cloud platform camera is fixed at unmanned aerial vehicle upper cover plate, and the wing comprises horn, rotor motor and the motor stake of four looks isostructures, controls the high-speed rotatory robot that drives of screw and moves in the air by control mechanism.
As shown in fig. 3, the crawling mechanism comprises six mechanical claws with the same structure, the mechanical claws are connected through a six-foot connecting plate, the main body of the six-foot connecting plate is rectangular, the four corners and the middle points of the long sides of the six-foot connecting plate protrude out, and circular hollow patterns are cut around the geometric center of the six-foot connecting plate; the hip joint steering engine is connected with the hexapod connecting plate through screws, the hip joint steering engine is connected with the knee joint steering engine through a U-shaped steering engine connector, the knee joint steering engine is connected with the ankle joint steering engine through a C-shaped steering engine connector, the leg support is connected to the ankle joint steering engine through 8 small screws, and the bottom of the leg support is connected with a damping pad.
The invention has the advantages and effects that:
1. the invention has flexible application scene, strong stability and driving force and obvious exploration and rescue effect. The whole mechanical structure adopts an insect type, so that the mechanical structure not only has the capability of crawling on uneven ground, but also can be changed into claws to grab articles in a flying state;
2. in the invention, the connecting plate and the bracket are mostly in hollow structures, so that the weight of the robot is reduced to the greatest extent under the condition of ensuring the stability of the whole framework, and the size of the robot body is reduced due to the characteristic of detachable wings, so that the robot is easy to transport and carry, has the advantages of stable structure and high strength, and increases the transportability of the robot;
3. according to the invention, the control system is arranged in the robot, and the protective cover is attached on the control system, so that the operation of the control system can be ensured to the greatest extent, and the debugging performance of the robot is improved by disassembling the protective cover.
Drawings
FIG. 1 is a front view of a robot;
FIG. 2 is a rear view of the robot;
FIG. 3 is a view of a robot flight configuration;
fig. 4 is a view showing a construction of the robot crawling.
Reference numerals: 1. control cabin, 2 flight mechanism, 3 crawling mechanism. 11. The unmanned aerial vehicle comprises a protective cover, 12, a GPS, 13, an upper cover plate of the unmanned aerial vehicle, 14, a pan-tilt camera, 15, a lower cover plate of the unmanned aerial vehicle, 21, a folding mechanism A, 22, a folding mechanism B, 23, a horn, 24, a motor pile, 25, a rotor, 26, a rotor motor, 31, a hip joint steering engine, 32, a knee joint steering engine, 33, a C-type steering engine connector, 34, a U-type steering engine connector A, 35, a U-type steering engine connector B, 36, an ankle joint steering engine, 37, a leg support, 38, a shock pad and 39, and a six-foot connecting plate.
Detailed Description
The present invention will be described in detail with reference to the embodiments shown in the drawings.
As shown in figure 1, the land-air integrated hexapod robot comprises a control cabin (1), a flying mechanism (2) and a crawling mechanism (3).
A hexapod robot for both land and air is disclosed, as shown in figure 2, a control cabin (1) and a flying mechanism (2) form the upper half part of the robot, a crawling mechanism forms the lower half part of the robot, and the two are connected through four M4 x 50 copper columns. An upper cover plate (13) of the unmanned aerial vehicle is of an approximate-circle fourteen-edge shape, a protective cover (11) and a GPS (12) are arranged above the upper cover plate, an electronic governor is arranged below the upper cover plate to control the rotating speed of a rotor wing, a pan-tilt camera (14) is arranged in front of the upper cover plate, a horn (23) is positioned between the upper cover plate (13) of the unmanned aerial vehicle and a lower cover plate (15) of the unmanned aerial vehicle and connected through a folding mechanism A (21) and a folding mechanism B (22), the horn (23) can be manually folded downwards through adjusting screws, a motor pile (24) is positioned at the tail end of the horn (23) and is internally provided with a rotor wing motor (26), and the motor pile is connected with the rotor wing (25) through screws; the crawling mechanism of the lower portion of the robot achieves foot structure movement through a hip joint steering engine (31), a knee joint steering engine (32) and an ankle joint steering engine (36), the steering engines are connected through steering engine connectors (33), (34) and (35), and a shock pad (38) is fixed to the bottom of the foot structure through screws.
A ground-air dual-purpose hexapod robot is disclosed, as shown in figure 3, a cover plate of an unmanned aerial vehicle of a flight mechanism is provided with a long strip-shaped hole and a threaded hole, the long strip-shaped hole and the threaded hole can be connected with the tail end of a machine arm (23) through a folding mechanism A (22), and the folding mechanism A (21) and a folding mechanism B (22) are fixed through screws; the protective cover (11) comprises a flight control mechanism, a crawling control mechanism and a power supply control circuit; cloud platform camera (14) are fixed at unmanned aerial vehicle upper cover plate (13), and the wing comprises horn (23), rotor (25), rotor motor (26) and motor stake (24) of four looks isostructures, controls the high-speed rotation of screw and drives the robot in aerial motion by control mechanism.
A six-legged robot for both ground and air use is disclosed, as shown in fig. 4, the crawling mechanism comprises six mechanical claws with the same structure, which are uniformly distributed around the circumference and are symmetrically distributed left and right. The six-foot structure is uniformly distributed in such a way that six legs respectively occupy a fixed point of a regular hexagon and are connected through six-foot connecting plates (39), the main bodies of the six-foot connecting plates are rectangular, protrude from the centers of four corners and long sides, and round hollowed-out patterns are cut around the geometric centers of the six-foot connecting plates; the hip joint steering engine (31) is connected with a hexapod connecting plate (39) through screws, the hip joint steering engine controls feet to move transversely, the hip joint steering engine (31) is connected with the knee joint steering engine (32) through U-shaped steering engine connectors (34) and (35), the knee joint steering engine (32) is connected with the ankle joint steering engine (36) through a C-shaped steering engine connector (33), the knee joint steering engine and the ankle joint steering engine control feet to move longitudinally, a leg support (37) is connected to the ankle joint steering engine (36) through 8 small screws, and the bottom of the leg support (37) is connected with a damping pad (38).
A six-legged robot for both ground and air use is shown in figure 4, and a crawling mechanism is composed of a skeleton structure and leg structures. The six-foot structure at the leg position is uniformly distributed in such a way that six legs respectively occupy a fixed point of a regular hexagon to be arranged. The trunk of the crawling mechanism is divided into a cover plate (11) and a bottom plate (12), and 6 steering engines are arranged between the cover plate and the bottom plateAnd (4) connecting. Leg selection three-section structure with three freely-rotating 0 s。To 180。The high-torque steering engine is characterized in that a three-joint motor is a hip joint motor (31), a knee joint motor (32) and an ankle joint motor (36), the hip joint motor (31) moves in the horizontal direction, is connected with a crawling machine body and a base joint, and rotates to drive a leg structure of the robot to turn left or right to complete steering movement of the robot. The knee joint motor (32) moves in the vertical direction and is connected with the base joint and the leg joint, and the leg structure of the robot is rotated to be lifted or dropped to complete the leg stretching movement of the robot. The ankle joint motor (36) moves in the vertical direction and is connected with the leg joint and the shin joint, and the robot is rotated to select the position of the leg landing point. The device can creep when land, can convert into the claw when the rotor is connected, snatchs the object.
The foregoing description is only exemplary of the preferred embodiments of the present application and is provided for the purpose of illustrating the general principles of the technology. It will be understood by those skilled in the art that the scope of the embodiments of the present invention is not limited to the specific combinations of the above-mentioned features, and other embodiments can be made by arbitrarily combining the above-mentioned features or their equivalents without departing from the spirit of the present invention. For example, the above features may be interchanged with other features disclosed in this application, but not limited to those having similar functions.
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